US3714898A - Fuze actuating system - Google Patents

Fuze actuating system Download PDF

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US3714898A
US3714898A US00843478A US3714898DA US3714898A US 3714898 A US3714898 A US 3714898A US 00843478 A US00843478 A US 00843478A US 3714898D A US3714898D A US 3714898DA US 3714898 A US3714898 A US 3714898A
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projectile
fuze
target
counter
range
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R Ziemba
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General Electric Co
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General Electric Co
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    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F41WEAPONS
    • F41GWEAPON SIGHTS; AIMING
    • F41G7/00Direction control systems for self-propelled missiles
    • F41G7/20Direction control systems for self-propelled missiles based on continuous observation of target position
    • F41G7/30Command link guidance systems
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F42AMMUNITION; BLASTING
    • F42CAMMUNITION FUZES; ARMING OR SAFETY MEANS THEREFOR
    • F42C13/00Proximity fuzes; Fuzes for remote detonation
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F42AMMUNITION; BLASTING
    • F42CAMMUNITION FUZES; ARMING OR SAFETY MEANS THEREFOR
    • F42C13/00Proximity fuzes; Fuzes for remote detonation
    • F42C13/04Proximity fuzes; Fuzes for remote detonation operated by radio waves
    • F42C13/047Remotely actuated projectile fuzes operated by radio transmission links
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F42AMMUNITION; BLASTING
    • F42CAMMUNITION FUZES; ARMING OR SAFETY MEANS THEREFOR
    • F42C17/00Fuze-setting apparatus
    • F42C17/04Fuze-setting apparatus for electric fuzes

Definitions

  • An electronic, digital, time fuze has a time base which s introduced over a radar command link at a rate which is inversely proportional to the desired projectile flight tlme.
  • a target following ranging device such as a ranging laser, provides target range information to a pulsed radar transmitter.
  • the range signal from the ranging device controls a variable pulse rate control unit which in turn ad usts the transmitter pulse rate to a value inversely proportional to the target range.
  • the transmitter is fixed to the weapon system and radiates in the direction of the projectile flight path.
  • Each projectile includes a fuze actuatmg circuit consisting of an antenna, an RF. detector, a fixed-set counter and a firing circuit.
  • the fuze actuating circuit within each projectile becomes actuated a short distance after departure from the gun muzzle.
  • the counter within the fuze counts the pulses received during its flight to target.
  • the firing circuit detonates the payload.
  • This invention relates generally to fuze actuating systems, and especially to systems wherein the range adjustment may be varied in flight.
  • a feature of this invention is an electronic, digital, time fuze, whose time base is introduced over a radar command link at a rate which is inversely proportional to the desired projectile flight time.
  • a target following ranging device such as a ranging laser, provides target range information to a pulsed radar transmitter.
  • the range signal from the ranging device controls a variable pulse rate control unit which in turn adjusts the transmitter pulse rate to a value inversely proportional to the target range.
  • the transmitter is fixed to the weapon system and radiates in the direction of the projectile flight path.
  • Each projectile includes a fuze actuating circuit consisting of an antenna, an RF. detector, a fixed-set counter and a firing circuit.
  • the fuze actuating circuit within each projectile becomes activated a short distance after departure from the gun muzzle.
  • the projectile travels towards its target it receives a series of RF. pulses at a rate which will just fill the counter when the projectile is at the proper range.
  • the counter within the fuze counts the pulses received during its flight to target.
  • the firing circuit detonates the payload.
  • PRF pulse rate frequency
  • the detonation range can be automatically adjusted if automatic range information is available.
  • the detonation range can be intentionally varied while the projectile is in flight to the target.
  • Jamming is diflicult since a special transmitter is required to communicate with the projectile and the projectile receiving antenna is directional afterwards.
  • a similar system may be utilized to initiate a rocket motor in a boosted projectile at a range most appropriate for its programmed trajectory.
  • Projectile muzzle velocity, weapon elevation and target range information are processed to provide time-to-ignitionpoint data which is subsequently translated into a transmitter pulse repetition frequency.
  • FIG. 1 is a diagram of a controlled range air burst fuze system for a shell incorporating this invention
  • FIG. 2 is a side view, partially in cross-section, of a fuze package according to this invention particularly adapted for insertion in the forward end of a small caliber projectile;
  • FIG. 3 is a block diagram of the electronic circuitry of the fuze of FIG. 2;
  • FIG. 4 is an electronic circuit diagram of the fuze of FIG. 2;
  • FIG. 5 is a block diagram of the electronic circuitry of the reset flip-flop
  • FIG. 6 is a plot of projectile range vs. radar pulse repetition frequency
  • FIG. 7 is a perspective view, partially in cross-section, of a fuze package according to this invention, particularly adapted for insertion in the aft end of a rocket boosted projectile.
  • the preferred embodiment of the system includes a source of range data, such as a ranging lasar 10, a variable pulse rate control 12, a pulse transmitter such as an X-band radar 14, a transmitter antenna 16, a weapon 18, and one or more projectiles 20.
  • Each projectile 20 has a fuze 22 which, as seen in FIG. 2, includes a housing 24 containing an antenna such as a slot antenna 26, electronic circuitry 28, a battery 30, which may be a thermal battery, a rotordetonator assembly 32 and a booster charge 34.
  • the rotor-detonator assembly 32 may be of the type shown in U.S. patent application Ser. No. 804,443, filed Mar. 5, 1969 by R. T. Ziemba. Briefly, the assembly 32 comprises an out of line ball rotor 36 having a detonator charge 38 with a filament 40 and a contact brush 42, and a C-shaped spring retainer 44.
  • the rotor is held in the out of line, safe disposition until the projectile, in flight, has developed adequate spin to centrifugally enlarge and enable the spring retainer 44 to pass into an annular recess 46 in the housing to release the rotor.
  • the rotor then rotates to axially align its center of gravity and the detonator charge with the longitudinal axis of the projectile.
  • the rotor is journalled on a transverse axis at 48 to constrain the rotor to rotation within a predetermined longitudinal plane so that the contact 42 wipes through this plane.
  • the thermal battery 30 may be of the type shown in U.S. patent application Ser. No. 695,144, filed Jan. 2, 1968 by R. T. Ziemba. Briefly, the battery includes two electrodes spaced apart by a normally solid and nonconductive thermally fusible electrolyte. Thermitic material is mounted in thermally conductive relation with the electrolyte and is ignitable by a percussion cap which is disposed between two rigid surfaces, one of which is a relatively displaceable striker element. The battery is normally inactive, until the projectile is subjected to a setback force on firing, which causes the striker element to percuss the cap, which explodes and actuates the thermitic material, which melts the electrolyte to activate the battery.
  • the battery 30 is supported in a cavity in the housing by a forward dielectric ring 50 and an aft dielectric ring 52 and is retained forward by a spring clip 54.
  • the outer case 56 of the battery serves as the negative contact, and is adapted to be wiped by the detonator contact 42.
  • the electronic circuitry 28 includes the antenna 26, and a diode detector 60, a two stage video amplifier 62, a counter 64, a firing circuit 66, and a reset circuit 68.
  • the antenna consists of a double four-port slot antenna, whose dimensions and probe phasing are designed to increase antenna gain to the rear of the projectile.
  • the slot configuration using two diametrically opposed double pairs of adjacent slots, quarterwave spaced, gives an antenna gain in the aft direction of +5 decibels over a standard dipole.
  • Antenna power is peak-detected with the hot carrier diode 60, whose output signal is the transmitted PRF envelope.
  • the signal voltage level at this point is approximately 0.05 volt, from a 40 kilowatt (peak) transmitter at a 3,000-meter range.
  • the detected pulses are amplified by the two-stage amplifier 62 to a level adequate to drive the counter 64.
  • the counter consists of twelve flip-flop stages in a cascade configuration which provide an input to output count ratio of 2 or 2048. Switchover of the last stage is detected to actuate the output circuit so only a count of 1024 is realized from the counter.
  • the output terminal of the gate 66A will be high, drawing current via the output amplifiers 66B and 66C through the filament 40 of detonator charge 38 to actuate the detonator after a finite interval which is a function of time and current.
  • each of these flip-flops may assume either of its one terminal high and zero terminal low, or one terminal low and Zero terminal high states. Absent the automatic reset circuit, should the eleventh flip-flop one output terminal be low and the twelfth flip-flop zero terminal be low the detonator filament 40 will start drawing current. Detonation would otherwise occur after a period of time. Less catastrophic, but not desirable, should any of the flip-flop assume its one-output high state, the counter will give a short count.
  • the automatic reset circuit 68 forces each of the counter flip-flop one output terminals to its low state upon the initial provision of power to the fuze from the battery 30. This reset occurs in less than one microsecond, which precludes premature actuation of the detonator.
  • the reset flip-flop 70, the reset NOR gate 72 and the reset pnp common emitter driver 74 are used to implement the reset circuit as a race loop.
  • the reset flip-flop 70, as seen in FIG. 5 may be structured as two NOR gates and 82.
  • the one output terminal 84 of the gate 82 is coupled to one of the input terminals 86 of the gate 80, whose other input terminal 88 serves as the pulse input terminal.
  • the zero output terminal 90 of the gate 80 is coupled to one of the input terminals 92 of the gate 82, Whose other input terminal 94 serves as the reset input terminal.
  • the zero-output terminal 90 of the flip-flop 70 is coupled to one input terminal 95 of the NOR gate 72, whose other input terminal 96 is coupled to ground.
  • the output terminal 98 of the gate is coupled to the base of the driver 74.
  • the emitter of the driver is coupled to the supply voltage and the collector is coupled to the reset bus 100.
  • the NOR gate 72 provides the longest delay in the loop, i.e., the slowest input to output transfer; and the driver provides the least delay.
  • the operation of the reset circuit may be broken into three phases, vis: Phase I, the interval during power coming up; Phase II, the interval after reset and before receipt of the first transmitter pulse; and Phase HI, the action on receipt of the first transmitter pulse.
  • the reset flip-flop zero output terminal 90 may initially assume either a high or low state. Assume the zero output terminal 90 is high, then the NOR gate output terminal 98 is initially and steady state low, the base electrode is initially and steady state 10W, and the driver initially and steady state conducts so that the reset bus 100 is initially and steady state high. The high signal on the reset bus resets all of the counter flipflops. The high reset signal at input terminal 94 also provides a low signal at output terminal 84 and thence a low signal at input terminal 86 and thus maintains output terminal 90 high.
  • the NOR gate output terminal 98 is initially low, and, because of the long transfer delay, the base electrode is initially low and the driver initially conducts so that the reset but 100 is initially high.
  • the initial high signal on the reset bus 100 resets all of the counter flip-flops, and also resets the reset flip.
  • the NOR gate output terminal 98 becomes high, making the base electrode high and turning off the driver so that the reset bus becomes low.
  • the reset flip-flop has already been reset, so that its zero output terminal is now high, and as described previously the driver conducts and the reset bus again becomes high.
  • the reset flip-flop zero output terminal is high
  • the NOR gate output terminal 98 is low
  • the driver conducts
  • the reset bus 100 is high.
  • the reset flip-flop one output terminal 84 is low.
  • the first transmitter pulse When, in Phase III, the first transmitter pulse is received, it is coupled to the input terminal 94 so that the zero output terminal 90 goes low.
  • the transmitter pulse is shaped to have a width greater than the NOR gate 72 transfer delay, so that when the NOR gate output terminal 98 goes high the driver stops conducting, making the reset bus 100 low, while the zero output terminal remains low.
  • the reset bus remains low, and the counter is free to count subsequent transmitter pulses without reset.
  • the variable pulse rate features of the transmitting radar is illustrated in FIG. 6 which shows the variation in pulse rate required to detonate a fuze payload as a function of target range with a counter capacity of 1024 i.e., 2 counts.
  • the pulse rate varies from about 10,000 p.p.s. at 100 meters to 200 p.p.s. at 2,000 meters.
  • fuze detonation resolution is $0.01 meter.
  • PRF which is the manner in which the radar would normally be operated in a burst fire mode.
  • the PRP may be programmed to increase in rate as the projectile travels down range, thereby providing higher resolution at maximum projectile range.
  • a SECOND EMBODIMENT As shown in FIG. 7, a fuze embodying this invention may be incorporated in a rocket-boosted projectile as an in-flight igniter assembly.
  • the assembly 200 includes a nozzle plug 202, an inner plug 204 supporting a threeturn helical antenna 206 wound on a dielectric core 208, a detector assembly 210, and a cannister 212.
  • the cannister includes a thermal battery 214, the counter and reset circuitry 216, the detonation initiator 218, and the rocket igniter 220.
  • the circuitry is substantially identical to that shown in FIG. 4, with the substitution of the helical antenna for the slotted antenna.
  • the counter and reset flip-flops may be 913 elements and the NOR gates may be 910 elements as shown in the May 1964 catalogue of Fairchild Semiconductor Division of Fairchild Camera and Instrument Corporation.
  • a weapon system comprising:
  • an RF. pulse transmitter having a transmitting antenna for transmitting pulses
  • said fuze including a receiving antenna for receiving pulses transmitted from said transmitter;
  • an RF. detector having an input terminal coupled to said receiving antenna and an output terminal
  • a fixed-set counter having an input terminal coupled to said detector output terminal for accommodating pulses therefrom and an output terminal for presenting a full-count signal when a preset count of pulses has been accumulated;
  • a firing circuit having an input terminal coupled to said counter output terminal for detonating said fuze when said full-count signal is presented by said counter;
  • variable pulse rate control means coupled to said transmitter for varying the pulse rate of said transmitter; a gun for discharging said projectile at a target; and
  • a target ranging means for determining the range of the target from said gun, and coupled to said pulse rate control means for causing said pulse rate control means to vary the pulse rate of said transmitter in inverse proportion to the range of the target from said gun.
  • a weapon system according to claim 1 further including arming means for maintaining said firing circuit in a safe condition until said projectile is in flight.
  • a weapon system according to claim 1 wherein said counter includes a plurality of multi-state stages;
  • reset means for automatically forcing each of said stages to a predetermined one of said states.
  • said receiving antenna is disposed in the ogive of said projectile and has a maximum gain to the rear of said projectile.
  • said receiving antenna is disposed within a central core of the aft end of said projectile and has a maximum gain to the rear of said projectile.
  • said fuze having an antenna
  • a pulse accumulator coupled to said antenna for receiving pulses therefrom and for providing an output signal on having accumulated a predetermined count of pulses
  • a detonator coupled to said accumulator for receiving said output signal to provide detonation
  • said method comprising:
  • said fuze having an antenna
  • a pulse accumulator coupled to said antenna for receiving pulses therefrom for providing an output signal on having accumulated a predetermined count of pulses
  • a firing circuit coupled to said accumulator for receiving said output signal and coupled to said detonator for enabling detonation subsequent to receipt of said output signal
  • said method comprising:

Abstract

AN ELECTRONIC, DIGITAL, TIME FUZE, HAS A TIME BASE WHICH IS INTRODUCED OVER A RADAR COMMAND LINK AT A RATE WHICH IS INVERSELY PROPORTIONAL TO THE DESIRED PROJECTILE FLIGHT TIME. A TARGET FOLLOWING RANGING DEVICE, SUCH AS A RANGING LASER, PROVIDES TARGET RANGE INFORMATION TO A PULSED RADAR TRANSMITTER. THE RANGE SIGNAL FROM THE RANGING DEVICE CONTROLS A VARIABLE PULSE RATE CONTROL UNIT WHICH IN TURN ADJUSTS THE TRANSMITTER PULSE RATE TO A VALUE INVERSELY PROPORTIONAL TO THE TARGET RANGE. THE TRANSMITTER IS FIXED TO THE WEAPON SYSTEM AND RADIATES IN THE DIRECTION OF THE PROJECTILE FLIGHT PATH. EACH PROJECTILE INCLUDES A FUZE ACTUATING CIRCUIT CONSISTING OF AN ANTENNA, AN R.F. DETECTOR, A FIXED-SET COUNTER AND A FIRING CIRCUIT. AT LAUNCH, THE FUZE ACTUATING CIRCUIT WITHIN EACH PROJECTILE BECOMES ACTUATED A SHORT DISTANCE AFTER DEPARTURE FROM THE GUN MUZZLE. AS THE PROJECTILE TRAVELS TOWARDS ITS TARGET IT RECEIVES A SERIES OF R.F. PULSES AT A RATE WHICH WILL JUST FILL THE COUNTER WHEN THE PROJECTILE IS AT THE PROPER RANGE. THE COUNTER WITHIN THE FUZE COUNTS THE PULSES RECEIVED DURING ITS FLIGHT TO TARGET. WHEN THE FIXED-SET NUMBER HAS BEEN ACCUMULATED, THE FIRING CIRCUIT DETONATES THE PAYLOAD.

Description

Feb; 6, 1913 R. T, ZEMBA 3,714,898
FUZE ACTUATING SYSTEM Filed July 22, 1 969 3 Sheets-Sheet'l RANGING A LASAR RANGE DATA 20%....PROJECTILE TRANSMITTER ANTENNA VARIABLE PULSE RATE RANSMITTER CONTROL v WEAPON macswme ANTENNA 68 6 1 T RESET F|G.3
6O\ 64\ 65) DET. I
AME CLOUINTIER HRE A 30 I v INVENTOR RICHARD T. ZIEMBA S ATTORNEY.
Feb. 6, 1973 R. T. ZIEMBA FUZE ACTUATI-NG SYSTEM 3 Sheets-Sheet 2 Filed Jul 22, 1969 INVENTOR RICHARD T. Zl/EMBA, BY HIS ATTORNEY.
Feb. 6, 1973 R.T. ZIEMBA FUZE ACTUATING SYSTEM 25 Sheets-Sneet 3 Filed July 22, 1969 FIG.6
609 xv 2.4m mmJDa mmhtimzqmh INVENTORZ RICHARD T. ZIEMBA,
BY HIS ATTORNEY.
United States Patent O 3,714,898 FUZE ACTUATING SYSTEM Richard T. Ziemba, Burlington, Vt., assignor to General Electric Company Filed July 22, B69, Ser. No. 843,478 Int. Cl. F42c 11/04 US. Cl. 102-70.2 R 7 Claims ABSTRACT OF THE DISCLOSURE An electronic, digital, time fuze, has a time base which s introduced over a radar command link at a rate which is inversely proportional to the desired projectile flight tlme. A target following ranging device, such as a ranging laser, provides target range information to a pulsed radar transmitter. The range signal from the ranging device controls a variable pulse rate control unit which in turn ad usts the transmitter pulse rate to a value inversely proportional to the target range. The transmitter is fixed to the weapon system and radiates in the direction of the projectile flight path. Each projectile includes a fuze actuatmg circuit consisting of an antenna, an RF. detector, a fixed-set counter and a firing circuit. At launch, the fuze actuating circuit within each projectile becomes actuated a short distance after departure from the gun muzzle. As the projectile travels towards its target it receives a series of RF. pulses at a rate which will just fill the counter when the projectile is at the proper range. The counter within the fuze counts the pulses received during its flight to target. When the fixed-set number has been accumulated, the firing circuit detonates the payload.
BACKGROUND OF THE INVENTION (1) Field of art This invention relates generally to fuze actuating systems, and especially to systems wherein the range adjustment may be varied in flight.
(2) Prior art Conventional fuzes may be grouped according to different actuating characteristics: Briefly,
(1) Timing out preset interval required to travel to target,
(a) Mechanical timing,
(b) Chemical timing,
(c) Electronic timing,
(i) Analogue timing, (ii) Digital timing;
(2) Detecting proximity of target; and
(3) Impacting on target.
Once a conventional timing fuze has been preset and sent into flight, control by the gunner is lost, and accuracy is subject to unaccounted-for movement of the target and the accuracy of the timing system. Once a conventional proximity detecting fuze has been sent into flight, control by the gunner is lost, and the fuze may be subject to premature detonation by other proximate objects. Once a conventional target impacting fuze is sent into flight, control by the gunner is lost.
BRIEF SUMMARY OF THE INVENTION It is an object of this invention to provide a system having the inherent accuracy of an electronic, digital timing actuator plus the ability of the gunner to adjust the interval in flight to actuation, thereby attaining the best characteristics of a digital timer and a proximity fuze.
A feature of this invention (as shown in FIG. 1) is an electronic, digital, time fuze, whose time base is introduced over a radar command link at a rate which is inversely proportional to the desired projectile flight time. A target following ranging device, such as a ranging laser, provides target range information to a pulsed radar transmitter. The range signal from the ranging device controls a variable pulse rate control unit which in turn adjusts the transmitter pulse rate to a value inversely proportional to the target range. The transmitter is fixed to the weapon system and radiates in the direction of the projectile flight path. Each projectile includes a fuze actuating circuit consisting of an antenna, an RF. detector, a fixed-set counter and a firing circuit.
At launch, the fuze actuating circuit within each projectile becomes activated a short distance after departure from the gun muzzle. As the projectile travels towards its target it receives a series of RF. pulses at a rate which will just fill the counter when the projectile is at the proper range. The counter within the fuze counts the pulses received during its flight to target. When the fixed-set number has been accumulated, the firing circuit detonates the payload. Once the rate at which pulses are to be generated is set, as a function of target range, each projectile must travel the same time, and the same range, before it accumulates the same full count. Thus, by adjusting the pulse rate frequency (PRF) of the transmitter, the gunner adjusts the range at which the payload is detonated.
Some unique advantages of this system are:
(l) The system is insensitive to the rate at which projectiles are fired. That is, with either single-shot or burst fire, payload detonation will occur at the same range.
(2) The desired resolution of the detonation range is limited only by the capacity of the counter within the fuze and the pulse rate of the transmitter.
(3) The detonation range can be automatically adjusted if automatic range information is available.
(4) The detonation range can be intentionally varied while the projectile is in flight to the target.
(5) Jamming is diflicult since a special transmitter is required to communicate with the projectile and the projectile receiving antenna is directional afterwards.
A similar system (as shown in FIG. 7) may be utilized to initiate a rocket motor in a boosted projectile at a range most appropriate for its programmed trajectory. Projectile muzzle velocity, weapon elevation and target range information are processed to provide time-to-ignitionpoint data which is subsequently translated into a transmitter pulse repetition frequency.
BRIEF DESCRIPTION OF THE DRAWINGS These and other objects, features and advantages of the invention will be apparent from the following specification thereof taken in conjunction with the accompanying drawing in which:
FIG. 1 is a diagram of a controlled range air burst fuze system for a shell incorporating this invention;
FIG. 2 is a side view, partially in cross-section, of a fuze package according to this invention particularly adapted for insertion in the forward end of a small caliber projectile;
FIG. 3 is a block diagram of the electronic circuitry of the fuze of FIG. 2;
FIG. 4 is an electronic circuit diagram of the fuze of FIG. 2;
FIG. 5 is a block diagram of the electronic circuitry of the reset flip-flop;
FIG. 6 is a plot of projectile range vs. radar pulse repetition frequency; and
FIG. 7 is a perspective view, partially in cross-section, of a fuze package according to this invention, particularly adapted for insertion in the aft end of a rocket boosted projectile.
THE PREFERRED EMBODIMENT As discussed above with respect to FIG. 1, the preferred embodiment of the system includes a source of range data, such as a ranging lasar 10, a variable pulse rate control 12, a pulse transmitter such as an X-band radar 14, a transmitter antenna 16, a weapon 18, and one or more projectiles 20. Each projectile 20 has a fuze 22 which, as seen in FIG. 2, includes a housing 24 containing an antenna such as a slot antenna 26, electronic circuitry 28, a battery 30, which may be a thermal battery, a rotordetonator assembly 32 and a booster charge 34.
The rotor-detonator assembly 32 may be of the type shown in U.S. patent application Ser. No. 804,443, filed Mar. 5, 1969 by R. T. Ziemba. Briefly, the assembly 32 comprises an out of line ball rotor 36 having a detonator charge 38 with a filament 40 and a contact brush 42, and a C-shaped spring retainer 44. The rotor is held in the out of line, safe disposition until the projectile, in flight, has developed adequate spin to centrifugally enlarge and enable the spring retainer 44 to pass into an annular recess 46 in the housing to release the rotor. The rotor then rotates to axially align its center of gravity and the detonator charge with the longitudinal axis of the projectile. The rotor is journalled on a transverse axis at 48 to constrain the rotor to rotation within a predetermined longitudinal plane so that the contact 42 wipes through this plane.
The thermal battery 30 may be of the type shown in U.S. patent application Ser. No. 695,144, filed Jan. 2, 1968 by R. T. Ziemba. Briefly, the battery includes two electrodes spaced apart by a normally solid and nonconductive thermally fusible electrolyte. Thermitic material is mounted in thermally conductive relation with the electrolyte and is ignitable by a percussion cap which is disposed between two rigid surfaces, one of which is a relatively displaceable striker element. The battery is normally inactive, until the projectile is subjected to a setback force on firing, which causes the striker element to percuss the cap, which explodes and actuates the thermitic material, which melts the electrolyte to activate the battery. The battery 30 is supported in a cavity in the housing by a forward dielectric ring 50 and an aft dielectric ring 52 and is retained forward by a spring clip 54. The outer case 56 of the battery serves as the negative contact, and is adapted to be wiped by the detonator contact 42.
The electronic circuitry 28 includes the antenna 26, and a diode detector 60, a two stage video amplifier 62, a counter 64, a firing circuit 66, and a reset circuit 68. The antenna consists of a double four-port slot antenna, whose dimensions and probe phasing are designed to increase antenna gain to the rear of the projectile. The slot configuration, using two diametrically opposed double pairs of adjacent slots, quarterwave spaced, gives an antenna gain in the aft direction of +5 decibels over a standard dipole. Antenna power is peak-detected with the hot carrier diode 60, whose output signal is the transmitted PRF envelope. The signal voltage level at this point is approximately 0.05 volt, from a 40 kilowatt (peak) transmitter at a 3,000-meter range. The detected pulses are amplified by the two-stage amplifier 62 to a level adequate to drive the counter 64. The counter consists of twelve flip-flop stages in a cascade configuration which provide an input to output count ratio of 2 or 2048. Switchover of the last stage is detected to actuate the output circuit so only a count of 1024 is realized from the counter. When the one-output terminal of the eleventh flip-flop is low, and the zero-output terminal of the twelfth flip-flop is low, the output terminal of the gate 66A will be high, drawing current via the output amplifiers 66B and 66C through the filament 40 of detonator charge 38 to actuate the detonator after a finite interval which is a function of time and current.
After the projectile is accelerated out of the weapon and the battery is actuated, the battery requires a finite period of time to reach full output voltage. When a voltage adequate for operating the flip-flops is reached, each of these flip-flops may assume either of its one terminal high and zero terminal low, or one terminal low and Zero terminal high states. Absent the automatic reset circuit, should the eleventh flip-flop one output terminal be low and the twelfth flip-flop zero terminal be low the detonator filament 40 will start drawing current. Detonation would otherwise occur after a period of time. Less catastrophic, but not desirable, should any of the flip-flop assume its one-output high state, the counter will give a short count.
The automatic reset circuit 68 forces each of the counter flip-flop one output terminals to its low state upon the initial provision of power to the fuze from the battery 30. This reset occurs in less than one microsecond, which precludes premature actuation of the detonator. The reset flip-flop 70, the reset NOR gate 72 and the reset pnp common emitter driver 74 are used to implement the reset circuit as a race loop. The reset flip-flop 70, as seen in FIG. 5 may be structured as two NOR gates and 82. The one output terminal 84 of the gate 82 is coupled to one of the input terminals 86 of the gate 80, whose other input terminal 88 serves as the pulse input terminal. The zero output terminal 90 of the gate 80 is coupled to one of the input terminals 92 of the gate 82, Whose other input terminal 94 serves as the reset input terminal. The zero-output terminal 90 of the flip-flop 70 is coupled to one input terminal 95 of the NOR gate 72, whose other input terminal 96 is coupled to ground. The output terminal 98 of the gate is coupled to the base of the driver 74. The emitter of the driver is coupled to the supply voltage and the collector is coupled to the reset bus 100. The NOR gate 72 provides the longest delay in the loop, i.e., the slowest input to output transfer; and the driver provides the least delay.
The operation of the reset circuit may be broken into three phases, vis: Phase I, the interval during power coming up; Phase II, the interval after reset and before receipt of the first transmitter pulse; and Phase HI, the action on receipt of the first transmitter pulse.
Consider Phase I: The reset flip-flop zero output terminal 90 may initially assume either a high or low state. Assume the zero output terminal 90 is high, then the NOR gate output terminal 98 is initially and steady state low, the base electrode is initially and steady state 10W, and the driver initially and steady state conducts so that the reset bus 100 is initially and steady state high. The high signal on the reset bus resets all of the counter flipflops. The high reset signal at input terminal 94 also provides a low signal at output terminal 84 and thence a low signal at input terminal 86 and thus maintains output terminal 90 high. Assume the zero output terminal is low, then the NOR gate output terminal 98 is initially low, and, because of the long transfer delay, the base electrode is initially low and the driver initially conducts so that the reset but 100 is initially high. The initial high signal on the reset bus 100 resets all of the counter flip-flops, and also resets the reset flip. After the long transfer delay the NOR gate output terminal 98 becomes high, making the base electrode high and turning off the driver so that the reset bus becomes low. However, the reset flip-flop has already been reset, so that its zero output terminal is now high, and as described previously the driver conducts and the reset bus again becomes high.
Thus, in Phase H, the reset flip-flop zero output terminal is high, the NOR gate output terminal 98 is low, the driver conducts, and the reset bus 100 is high. Also, the reset flip-flop one output terminal 84 is low.
When, in Phase III, the first transmitter pulse is received, it is coupled to the input terminal 94 so that the zero output terminal 90 goes low. However, the transmitter pulse is shaped to have a width greater than the NOR gate 72 transfer delay, so that when the NOR gate output terminal 98 goes high the driver stops conducting, making the reset bus 100 low, while the zero output terminal remains low. The reset bus remains low, and the counter is free to count subsequent transmitter pulses without reset.
The advantages of the reset circuit include:
(1) Priority and speed of operation sufiicient to preclude accidental detonation.
(2) Independence of the rise characteristics of the power supply.
(3) Ease of testing the configuration before assembly to the warhead since operation is dependent only on the presence of a voltage which might cause an accidental detonation.
The variable pulse rate features of the transmitting radar is illustrated in FIG. 6 which shows the variation in pulse rate required to detonate a fuze payload as a function of target range with a counter capacity of 1024 i.e., 2 counts. The pulse rate varies from about 10,000 p.p.s. at 100 meters to 200 p.p.s. at 2,000 meters. At 2,000 meters, fuze detonation resolution is $0.01 meter. This assumes a constant rate PRF which is the manner in which the radar would normally be operated in a burst fire mode. For single-shot firings the PRP may be programmed to increase in rate as the projectile travels down range, thereby providing higher resolution at maximum projectile range.
A SECOND EMBODIMENT As shown in FIG. 7, a fuze embodying this invention may be incorporated in a rocket-boosted projectile as an in-flight igniter assembly. The assembly 200 includes a nozzle plug 202, an inner plug 204 supporting a threeturn helical antenna 206 wound on a dielectric core 208, a detector assembly 210, and a cannister 212. The cannister includes a thermal battery 214, the counter and reset circuitry 216, the detonation initiator 218, and the rocket igniter 220. The circuitry is substantially identical to that shown in FIG. 4, with the substitution of the helical antenna for the slotted antenna.
The counter and reset flip-flops may be 913 elements and the NOR gates may be 910 elements as shown in the May 1964 catalogue of Fairchild Semiconductor Division of Fairchild Camera and Instrument Corporation.
What is claimed is:
1. A weapon system comprising:
an RF. pulse transmitter having a transmitting antenna for transmitting pulses;
a projectile having a fuze;
said fuze including a receiving antenna for receiving pulses transmitted from said transmitter;
an RF. detector having an input terminal coupled to said receiving antenna and an output terminal,
a fixed-set counter having an input terminal coupled to said detector output terminal for accommodating pulses therefrom and an output terminal for presenting a full-count signal when a preset count of pulses has been accumulated;
a firing circuit having an input terminal coupled to said counter output terminal for detonating said fuze when said full-count signal is presented by said counter;
variable pulse rate control means coupled to said transmitter for varying the pulse rate of said transmitter; a gun for discharging said projectile at a target; and
a target ranging means for determining the range of the target from said gun, and coupled to said pulse rate control means for causing said pulse rate control means to vary the pulse rate of said transmitter in inverse proportion to the range of the target from said gun.
2. A weapon system according to claim 1 further including arming means for maintaining said firing circuit in a safe condition until said projectile is in flight.
3. A weapon system according to claim 1 wherein said counter includes a plurality of multi-state stages;
and
further including reset means for automatically forcing each of said stages to a predetermined one of said states.
4. A weapon system according to claim 1 wherein:
said receiving antenna is disposed in the ogive of said projectile and has a maximum gain to the rear of said projectile.
5. A weapon system according to claim 1 wherein:
said receiving antenna is disposed within a central core of the aft end of said projectile and has a maximum gain to the rear of said projectile.
6. A method of detonating a fuze in a projectile at a predetermined range in flight from a gun from which projected,
said fuze having an antenna,
a pulse accumulator coupled to said antenna for receiving pulses therefrom and for providing an output signal on having accumulated a predetermined count of pulses, and
a detonator coupled to said accumulator for receiving said output signal to provide detonation;
said method comprising:
measuring the range from said gun at which the fuze is to be detonated;
transmitting pulses to said fuze antenna and thence to said accumulator at a pulse repetition rate inverse to the measured range so as to provide the predetermined count of pulses in the accumulator at the measured range;
providing a signal upon the accumulator accumulating the predetermined count of pulses;
detonating the detonator upon the provision of said signal.
7. A method of enabling the detonation of a fuze in a projectile at a predetermined range in flight from a gun 55 from which projected;
said fuze having an antenna,
a pulse accumulator coupled to said antenna for receiving pulses therefrom for providing an output signal on having accumulated a predetermined count of pulses,
a detonator,
a firing circuit coupled to said accumulator for receiving said output signal and coupled to said detonator for enabling detonation subsequent to receipt of said output signal;
said method comprising:
measuring the range from said gun at which detonation is to be enabled,
transmitting pulses to said fuze antenna and thence to said accumulator at a pulse repetition rate inverse to the measured range so as to provide the predetermined count of pulses in the accumulator at the measured range,
providing a signal to the firing circuit upon the 7 accumulator accumulating the predetermined 3,113,305 12/1963 Trounson et a1. 343-7 ED count of pulses. 3,076,191 1/1963 Williams 3437 PF 2,981,942 4/ 1961 Gross 343-7 A References Cited UNITED STATES PATENTS 5 STEPHEN C. BENTLEY, Primary Examiner 2,769,975 11/1956 Rines 10270.2P
3,063,345 11/1962 Harmon et a]. 343-7 ED 2443.14; 340-206; 343-6 R, 7PF, 17.1 PF; 356-4
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US3754249A (en) * 1969-07-28 1973-08-21 Us Navy Laser fire control system small boat application
US3844217A (en) * 1972-09-28 1974-10-29 Gen Electric Controlled range fuze
US3992708A (en) * 1975-07-18 1976-11-16 The United States Of America As Represented By The Secretary Of The Navy Optical tracking analog flywheel
US4015531A (en) * 1975-01-31 1977-04-05 General Electric Company Electrical fuze with selectable modes of operation
US4083308A (en) * 1973-05-19 1978-04-11 Ferranti Limited Projectile fuzes
US4085680A (en) * 1977-02-17 1978-04-25 General Electric Company Fuze encoder
US4145970A (en) * 1976-03-30 1979-03-27 Tri Electronics Ab Electric detonator cap
US4214534A (en) * 1969-06-30 1980-07-29 The United States Of America As Represented By The Secretary Of The Army Command fuzing system
US4217827A (en) * 1970-04-23 1980-08-19 The United States Of America As Represented By The Secretary Of The Army Radar fuzing system
US4267776A (en) * 1979-06-29 1981-05-19 Motorola, Inc. Muzzle velocity compensating apparatus and method for a remote set fuze
US4291627A (en) * 1979-11-27 1981-09-29 General Electric Company Electrical fuze with a plurality of modes of operation
US4457206A (en) * 1979-07-31 1984-07-03 Ares, Inc. Microwave-type projectile communication apparatus for guns
US4495851A (en) * 1981-12-18 1985-01-29 Brown, Boveri & Cie Ag Apparatus for setting and/or monitoring the operation of a shell fuse or detonator
US4641801A (en) * 1982-04-21 1987-02-10 Lynch Jr David D Terminally guided weapon delivery system
US4859054A (en) * 1987-07-10 1989-08-22 The United States Of America As Represented By The United States Department Of Energy Proximity fuze
DE3835656A1 (en) * 1988-10-20 1990-04-26 Asea Brown Boveri Method for correction of the detonation time of a projectile which is fired from a weapon barrel, and a circuit arrangement for carrying out the method
US5343795A (en) * 1991-11-07 1994-09-06 General Electric Co. Settable electronic fuzing system for cannon ammunition
US6142080A (en) * 1998-01-14 2000-11-07 General Dynamics Armament Systems, Inc. Spin-decay self-destruct fuze
US6145439A (en) * 1998-01-14 2000-11-14 General Dynamics Armament Systems, Inc. RC time delay self-destruct fuze
US6349652B1 (en) * 2001-01-29 2002-02-26 The United States Of America As Represented By The Secretary Of The Army Aeroballistic diagnostic system
US20030136291A1 (en) * 2000-06-02 2003-07-24 Diehl Munitionssysteme Gmbh & Co. Standoff or proximity optronic fuse
US20060028373A1 (en) * 2004-08-06 2006-02-09 Time Domain Corporation System and method for active protection of a resource
US20060125680A1 (en) * 2004-12-15 2006-06-15 Thackray Robert G Method and system for detecting an object using a composite evidence grid
US20070139247A1 (en) * 2005-12-15 2007-06-21 Brown Kenneth W Multifunctional radio frequency directed energy system
US20080121131A1 (en) * 2006-11-29 2008-05-29 Pikus Eugene C Method and apparatus for munition timing and munitions incorporating same

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US3670652A (en) * 1970-05-11 1972-06-20 Gen Electric Controlled range proximity fuze
DE2413920C1 (en) * 1974-03-22 1986-07-17 Messerschmitt-Bölkow-Blohm GmbH, 8012 Ottobrunn Facility for re-securing a mine
CH621230B (en) * 1975-11-25 Mefina Sa ELECTRONIC IGNITION DEVICE FOR PROJECTILE ROCKET.
CH608604A5 (en) * 1977-09-16 1979-01-15 Oerlikon Buehrle Ag
IT1109714B (en) * 1978-11-17 1985-12-23 Borletti Spa PROXIMITY FUNCTIONING SPOOL WITH DETONATOR WITH IGNITION BY ELECTRIC SIGNAL
JP5979022B2 (en) * 2012-01-27 2016-08-24 ダイキン工業株式会社 Ammo actuation system

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US2981942A (en) * 1952-01-23 1961-04-25 Raytheon Co Pulse echo systems
CH482168A (en) * 1967-11-01 1969-11-30 Crevoisier Rene Remote control explosion grenade

Cited By (29)

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Publication number Priority date Publication date Assignee Title
US4214534A (en) * 1969-06-30 1980-07-29 The United States Of America As Represented By The Secretary Of The Army Command fuzing system
US3754249A (en) * 1969-07-28 1973-08-21 Us Navy Laser fire control system small boat application
US4217827A (en) * 1970-04-23 1980-08-19 The United States Of America As Represented By The Secretary Of The Army Radar fuzing system
US3844217A (en) * 1972-09-28 1974-10-29 Gen Electric Controlled range fuze
US4083308A (en) * 1973-05-19 1978-04-11 Ferranti Limited Projectile fuzes
US4015531A (en) * 1975-01-31 1977-04-05 General Electric Company Electrical fuze with selectable modes of operation
US3992708A (en) * 1975-07-18 1976-11-16 The United States Of America As Represented By The Secretary Of The Navy Optical tracking analog flywheel
US4145970A (en) * 1976-03-30 1979-03-27 Tri Electronics Ab Electric detonator cap
US4085680A (en) * 1977-02-17 1978-04-25 General Electric Company Fuze encoder
US4267776A (en) * 1979-06-29 1981-05-19 Motorola, Inc. Muzzle velocity compensating apparatus and method for a remote set fuze
US4457206A (en) * 1979-07-31 1984-07-03 Ares, Inc. Microwave-type projectile communication apparatus for guns
US4291627A (en) * 1979-11-27 1981-09-29 General Electric Company Electrical fuze with a plurality of modes of operation
US4495851A (en) * 1981-12-18 1985-01-29 Brown, Boveri & Cie Ag Apparatus for setting and/or monitoring the operation of a shell fuse or detonator
US4641801A (en) * 1982-04-21 1987-02-10 Lynch Jr David D Terminally guided weapon delivery system
US4859054A (en) * 1987-07-10 1989-08-22 The United States Of America As Represented By The United States Department Of Energy Proximity fuze
DE3835656A1 (en) * 1988-10-20 1990-04-26 Asea Brown Boveri Method for correction of the detonation time of a projectile which is fired from a weapon barrel, and a circuit arrangement for carrying out the method
US5343795A (en) * 1991-11-07 1994-09-06 General Electric Co. Settable electronic fuzing system for cannon ammunition
US6142080A (en) * 1998-01-14 2000-11-07 General Dynamics Armament Systems, Inc. Spin-decay self-destruct fuze
US6145439A (en) * 1998-01-14 2000-11-14 General Dynamics Armament Systems, Inc. RC time delay self-destruct fuze
US20030136291A1 (en) * 2000-06-02 2003-07-24 Diehl Munitionssysteme Gmbh & Co. Standoff or proximity optronic fuse
US6349652B1 (en) * 2001-01-29 2002-02-26 The United States Of America As Represented By The Secretary Of The Army Aeroballistic diagnostic system
US20060028373A1 (en) * 2004-08-06 2006-02-09 Time Domain Corporation System and method for active protection of a resource
US7046187B2 (en) * 2004-08-06 2006-05-16 Time Domain Corporation System and method for active protection of a resource
US20060125680A1 (en) * 2004-12-15 2006-06-15 Thackray Robert G Method and system for detecting an object using a composite evidence grid
US7142150B2 (en) * 2004-12-15 2006-11-28 Deere & Company Method and system for detecting an object using a composite evidence grid
US20070139247A1 (en) * 2005-12-15 2007-06-21 Brown Kenneth W Multifunctional radio frequency directed energy system
US7629918B2 (en) * 2005-12-15 2009-12-08 Raytheon Company Multifunctional radio frequency directed energy system
US20080121131A1 (en) * 2006-11-29 2008-05-29 Pikus Eugene C Method and apparatus for munition timing and munitions incorporating same
US7926402B2 (en) * 2006-11-29 2011-04-19 Alliant Techsystems Inc. Method and apparatus for munition timing and munitions incorporating same

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DE2035842A1 (en) 1971-02-04
CH514121A (en) 1971-10-15
DE2035842C2 (en) 1982-05-27
NL176396C (en) 1985-04-01
JPS4944760B1 (en) 1974-11-29
FR2053077B1 (en) 1973-05-25
NL176396B (en) 1984-11-01
SE377720B (en) 1975-07-21
FR2053077A1 (en) 1971-04-16
NL7010758A (en) 1971-01-26
BE753740A (en) 1970-12-31
GB1317977A (en) 1973-05-23

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