RU2482441C1 - Detonating fuse of combined action - Google Patents

Abstract

FIELD: weapons and ammunition.

SUBSTANCE: detonating fuse of combined action comprises a body, a radial detonator, a safety mechanism, an electric igniter and a unit of remote control of igniter actuation connected to a contact sensor. The body is equipped with an optical window. Within the remote control unit there are the following electrically connected components: a receiving device of a time code and clock-oscillator-controlled time delay device, delayed cocking scheme and output key for igniter switching with a source of power supply. The contact sensor with the delayed cocking scheme is connected via a normally closed switchboard of a control unit. The control unit switchboard is controlled by the scheme of matching of a contact sensor closing signal and a polling pulse from a shaper. The shaper is connected to a counter of a clock oscillator. The axial electric igniter with one of its outputs is connected to a positive pole of a power supply source via a resistor and a diode, and via a capacitor - to its negative pole connected to the output key.

EFFECT: minimised dimensions of a detonating fuse for equipment of small-calibre artillery ammunition.

3 dwg

Description

The invention relates to guided artillery shells with a combined, contact and contactless fuse triggering for remote initiation from an external source of control radiation and detonation directly upon encountering a target on a flight path.

The level of this technical field is characterized by a fuse for combined initiation of detonation installed in an artillery shell, including a converter, safety and actuating mechanisms, a fuse remote control unit connected to an electric power source and containing a serial time code receiver, a decoder and a time delay device described in RU patent 2135947 C1, F42B 15/01, 1999

Between the remote control unit and the standard fuse containing the piezoelectric transducer, an additional shock pulse generator is installed, made in the form of an electric detonator, the operation of which upon the command of the temporary deceleration device in the projectile body excites the shock wave transmitted to the piezoelectric transducer of the fuse.

The shock impulse created by the electric detonator at a given point in the projectile’s flight path is equivalent to the impulse from a standard element during contact operation, which determines the identity of the operation of the detonation circuit in different initiation modes.

The described ammunition is characterized by a universal filling detonation mechanism, which is initiated from an impact when meeting with a target under the influence of inertia on a piezoelectric transducer, and also alternatively: from a shock pulse of a simulator of a similar meeting from an autonomous electric detonator, triggered by an external coded control command containing information about the detonation time converted to a standard executive signal after a delay time.

The output signal from the remote control unit is transformed by means of an additional electric detonator into a shock pulse that generates a shock wave in the shell of the projectile that is adequate to the standard fuse received by the piezoelectric transducer in a real encounter with an obstacle.

The control unit is indirectly connected with the fuse converter, which allows the use of a standard safety-executive mechanism, unifying the design and equipment of ammunition, which reduces production costs.

Entering the energy-containing battery mode - the power source of the control unit - occurs with a delay of 0.1 s after the shot (100 m flight) to ensure safety, eliminating unauthorized shell rupture near the firing position.

The shock pulse generator is located in the shell of the ammunition regardless of the fuse, that is, without electrical and kinematic connections with it, which provides constructive mobility to the remote control unit.

This universal technical solution is suitable for large-caliber artillery shells, aerial bombs and mines, however, the practical use of small-caliber artillery shells is difficult due to the limited volume for accommodating additional electric detonator and a remote control unit with a power source.

The use of a standard fuse provides adaptive adaptability of ammunition, but at the same time the combat effectiveness of the projectile is reduced due to the large total dimensions of the remote control unit with a power source and a fuse with a relatively powerful piezoelectric transducer that operates autonomously, initiating the operation of an electric detonator without an additional current source.

In addition, the remote control unit and the shock pulse generator must be isolated from direct exposure to high pressure propellant gases propellant charge. In a limited projectile volume, this can be done only by reducing the mass of the combat load, which reduces the combat power of the products.

A highly sensitive fuse of the described ammunition can cause a false positive from interaction with landscape obstacles, tree branches, shrubs and with atmospheric precipitation in the form of hail, torrential jets, which leads to the rupture of the projectile near the firing position and the location of the personnel of their troops.

The noted shortcomings were eliminated in the more advanced fuse according to patent RU 2229678 C1, F42B 13/00, 2002, which, according to the technical nature and the number of matching features, was chosen as the closest analogue to the proposed fuse for small-caliber artillery ammunition.

Known fuse for artillery ammunition includes placed in a case equipped with an optical window, a beam detonator, a safety mechanism, an electric igniter and a remote control unit for activating an electric igniter connected to a contact sensor associated with a power source.

The remote control unit contains a series-connected time code receiving device and a time delay device controlled by a clock, a long-range cocking circuit and an output key for switching an electric igniter to a power source.

The well-known fuse is characterized by a reduction in the dimensions of a fuse with remote control of the detonation to acceptable for use in small-caliber artillery shells, in rifle grenades, which significantly expanded the scope of application while increasing the effectiveness of the intended ammunition.

The direct connection of the remote control unit with the converter, which uses a sensitive electric igniter that is susceptible to the control signal of the time delay device without effort, ensures that the fuse is triggered both during contact action when meeting the target and at a predetermined time from the outside, without the use of an additional energy-intensive detonator and a powerful piezoelectric transducer.

Introduction to the structure of the time delay device of a controlled long-range cocking scheme allows you to block the accidental operation of the electric igniter from mechanical stress on the contact sensor during firing and premature munition detonation, which increases the safety of use and functional reliability.

Additional equipment of the fuse with a contact sensor unified its action in both modes of operation of the ammunition: upon contact with the target and controlled detonation at a given flight distance.

A continuation of the advantages are inherent disadvantages. So reliable initiation of an electric igniter in a known fuse comes from a relatively large current pulse (150-200 mA), which forces the use of a sufficiently large-sized power source.

This is possible only due to the volume of explosive filling with a concomitant deterioration in the ammunition destination.

In small-caliber ammunition for this reason, it is practically impossible to ensure accurate initiation of detonation without significant loss of damaging fragmentation.

In addition, the autonomous location of the contact sensor also reduces the payload of the ammunition.

A significant drawback of the known fuse is the unsatisfactory safety of the fuse due to the possibility of unauthorized detonation of ammunition in the barrel or over its own positions in case of any failure of the long-range cocking scheme, since the electric igniter with the output key is connected directly.

The technical problem to which the present invention is directed is to expand the scope of application of a safe multifunctional fuse by minimizing its dimensions while increasing the functional reliability of accurate operation at a given point on the flight path of small-caliber artillery ammunition.

The required technical result is achieved by the fact that a well-known fuse of combined action for artillery ammunition, comprising a beam detonator, a safety mechanism, an electric igniter and an electric igniter remote control unit connected to a contact sensor, located in a case equipped with an optical window, is included in the remote control unit in series electrically coupled time code receiver and clock controlled device the delay time, the long-range cocking circuit and the output key for switching the electric igniter to the power source, characterized in that the contact sensor with the long-range cocking circuit is connected through a normally closed switch of the control unit, controlled by the matching circuit of the contact signal of the contact sensor and the polling pulse from the shaper connected to the counter a clock generator, and the axial electric igniter is connected to the positive pole of the power supply through a resistor and a diode, and through the capacitor - to its negative pole associated with the output key.

Distinctive features made it possible to improve the well-known fuse with remotely controlled accurate and safe operation, minimizing its dimensions for equipping small-caliber artillery ammunition, while providing a multiple reduction in the dispersion from the nominal time of detonation at a chosen point on the trajectory, which increased the combat effectiveness of the ammunition as a whole.

The connection of the contact sensor with the long-range cocking circuit by means of a normally closed switch of the control unit connected to the pulse counter of the clock generator through the comparison circuit allows an additional cocking stage to be made, preventing unauthorized early firing of the fuse over the firing position.

The matching circuit of the contact sensor closure signal (in case of malfunction) with the polling pulse from the driver switches the control unit switch, breaking the electrical connection of the contact sensor with the output key, which eliminates the munition detonation. At the same time, autonomous passage through the long-range cocking of signals from the receiving device about the given firing distance is maintained.

After the completion of the polling pulse from the shaper and in the absence of a matching circuit, the switch remains in the normally closed position, connecting the contact sensor in the output key, providing an inertial fuse when meeting the target.

A capacitor connected to both terminals of the electric igniter and closed through a resistor connected to the positive pole of the power source provides the accumulation of electric energy from a low-power source to a predetermined level sufficient to trigger the electric igniter, that is, it performs the functions of a programmable drive.

The installation of a resistor in the electrical connection circuit of the electric igniter with the positive pole of the power source creates an additional stage of fuse protection, eliminating the discharge of the capacitor until it reaches the specified voltage level, thereby preventing unauthorized operation of the electric igniter.

The diode in the electrical circuit of the electric igniter with the positive pole of the power source holds the voltage level accumulated by the capacitor at possible fluctuations in the flight dynamics of the current characteristics of the power source.

The connection of the power source, in particular its negative pole, through the output key with an electric igniter provides the operation of the latter after closing the output key by the control signal of the long-range cocking circuit.

Therefore, each essential feature is necessary, and their combination in a stable relationship is sufficient to achieve a novelty of quality that is not inherent in the characteristics of disunity, that is, the technical problem posed in the invention is achieved not by the sum of the effects, but by a new super-effect of the sum of the attributes.

A comparative analysis of the proposed technical solution with identified analogues of the prior art, from which the invention does not explicitly follow for an ammunition specialist, showed that it is unknown, but taking into account the possibility of serial industrial production at the existing production of 23-30 mm caliber shells and grenade launchers equipped with the described fuse, it can be concluded that the criteria for patentability are met.

The invention is illustrated by drawings, which depict:

figure 1 - design of the fuse in the context;

figure 2 is a functional block diagram of the proposed fuse;

figure 3 - structure of the control unit of the state of the contact sensor.

In the fuse case 1 (Fig. 1) with the end optical window 2, there are sequentially placed: a remote control unit 3, a power supply 4, which are mounted in a coaxial damping shell 5, a contact sensor 6, an axial electric igniter 7, a standard inertial-action safety mechanism 8 and a beam detonator capsule 9.

The electric igniter 7 is placed inside the contact sensor 6 of a ring shape, which ensures the compactness of their spatial relative position in the fuse.

An energy-containing power source 4, made in the form of an electrolytic battery with a nakolny ampoule, and an electronic remote control unit 3 are autonomously placed inside the power shell 5, to which the latter is connected by means of a damping layer 10 of an adhesive compound. This is guaranteed to ensure the integrity and functionality of the source 4 and block 3, since shock axial overloads during firing are perceived by the power shell 5 and are amortized in the interlayer 10.

Structural and functional block diagram of the fuse is made in the following relationship of structural elements (figure 2).

The fuse triggering remote control unit 3, communicating with the contact sensor 6 and the power supply 4, includes a time code receiver 11 electrically connected to each other, comprising a receiver 12 of the control encoded external laser radiation signals and a decoder 13, which is connected to the time device 14 delays.

The time delay device 14 consists of sequential counter 15 of starting pulses of a comparison circuit 16, a long-range cocking circuit 17 connected to a clock counter 18, and an output key 19.

The time delay device 14 comprises a clock 20, one output of which with a clock frequency f is connected to a clock counter 18 and a decoder 13, and another output with a frequency f / k is connected to a start pulse counter 15.

The counter 15 triggering pulses is connected to the control unit 21, which is installed in the electric communication line of the contact sensor 6 with the circuit 17 of the long-range cocking.

The control unit 21 (Fig. 3) consists of a normally closed switch 22, electrically connecting the contact sensor 6 with the circuit 17 directly and in parallel through the coincidence circuit 23, which is additionally connected via the polling pulse former 24 to the clock counter 18.

Connected to the negative pole of the power supply 4, the output key 19 of the time delay device 14 (i.e., in general, the output of the fuse initiating remote control unit 3) is connected to one of the two terminals of the axial electric igniter 7, equipped with a standard centrifugal action safety mechanism 8 that blocks the communication fire circuit with a radiation capsule detonator 9.

The second terminal of the electric igniter 7 is connected through a resistor 25 and a diode 26 to the positive pole of the power supply 4, and through the capacitor 27 to its negative pole.

The power source 4 with the device 14 time delay and with the decoder 13 of the receiving device 11 time code is connected through a voltage stabilizer 28, and with its receiver 12 through a voltage stabilizer 29.

In the power supply line of the receiver 12 control encoded signals, between the source 4 and the voltage stabilizer 28, a switch 30 is installed, connected to the output of the decoder 13.

The proposed fuse operates in remote air and contact modes when meeting for the purpose of detonation as follows.

When fired mechanically from projectile acceleration overloads, a power supply 4 of the fuse structural elements is initiated: a receiver 12 of encoded control signals, and a decoder 13 of a receiver 11, and a time delay device 14.

When the power supply, the long-range cocking circuit 17 is locked without passing any pulses to the output key 19, and the clock counter 18 starts counting the pulses of the clock generator 20.

While the counter 18 clock pulses counts the set number, no random signals from the circuit 16 of the comparison will not go to the output key 19 and will not cause unauthorized fuses.

The signal from the counter 18 is supplied to the imaging pulse generator 24, the duration of which is less than the structurally embedded time interval of the long-range cocking. The pulse from the shaper 24 with the duration of this temporary difference is supplied to one of the outputs of the matching circuit 23.

If the contact sensor 6 is faulty (short circuit due to overload of the shot or assembly failure), the electric signal enters the circuit 23 during the duration of the polling pulse from the driver 24, as a result of which the control signal from the circuit 23 switches 22 and disconnects the electrical connection of the contact sensor 6 with the output key 19.

As a result, the signals from the contact sensor 6 after the end of the cocking pulse are not received at the input of the cocking circuit 17, which eliminates the unauthorized operation of the electric igniter 7.

In this case, the remote detonator firing is carried out in the normal mode according to the signal from the comparison circuit 16.

If during the existence in the circuit 23 of the coincidence of the polling pulse from the driver 24 from the contact sensor 6, the signal is not received, then the circuit 23 does not generate a control signal and the switch 30 remains closed, which ensures the fuse is ready for action when meeting with the target from the signal of inertial closure from the contact sensor 6.

At the same time, when the voltage of the source 4 appears, the capacitor 27 starts charging through the resistor 25 and the diode 26, which stores the charge accumulated on the capacitor 27 in case of accidental voltage drops of the power supply 4.

Until the specified voltage level on the capacitor 27 is reached, the electric igniter 7 will not work, even with the key 19 open, which creates an additional level of protection, increasing the safety of the fuse and ammunition as a whole.

The process of charging the capacitor 27 requires time, characterized by the value of τ = R · C (the product of the resistance of the resistor 25 and the capacitance of the capacitor 27).

The selection of the capacitance of the capacitor 27 is carried out on the basis of the necessary energy to operate the electric igniter 7, and the selection of the resistance of the resistor 25 provides the duration of the charge time of the capacitor 27, that is, the effect of this additional protection stage.

So, for the operation of the electric igniter 7, it is sufficient to use a capacitor 27 with a capacity of 10 μF, at a voltage of 8-10 V on the capacitor 27, install a resistor 25 with a resistance of 3 kOhm and at a voltage U _o = 12 V on the power supply 4.

In this case, the capacitor 27 is charged to the operating voltage U for a time t = 30 ms: U = U _o -e ^{-t / τ} = 8 B.

The average current i of the charge of the capacitor 27 during this time will be i = C · U / t≈3 mA, which is much less than the current (150-200 mA) required to operate the electric igniter 7 when it is directly connected to the current source 4 according to the prototype, that is the performance of the proposed fuse design is provided by a power source 4 of significantly lower power and, accordingly, dimensions.

After the time delay necessary for the guaranteed output of the energy-containing source 4 to the required level, sufficient for the operation of the structural elements of the fuse, an external laser-transmitting device associated with a weapon emits a code message in the form of two pairs of pulses in the direction of the projectile.

Depending on the conditions of use, the transmitting device and, consequently, the receiver 12 on the projectile can operate in the laser or radio range. In the first case, an optical window 2 is installed in the bottom of the housing 1 (Fig. 1), and in the second case, an antenna (not shown) is in the structure of the receiver 12.

Upon receipt of two pairs of control encoded pulses from an external transmitter at receiver 12, the time interval between these pairs of pulses is counted and recorded as the number of pulses of the clock generator 20 received over the time between the pairs of pulses.

The interval between two pairs of pulses is proportional to the delay time of the detonation of the projectile (K times smaller), and the time interval between pulses in pairs serves as an identification sign to exclude the receipt of random interference signals as control signals.

The signal from the decoder 13 about the completion of the reception of the code packet is sent to the switch 30, which turns off the power supply to the receiver 12 as unnecessary, and to the time delay device 14, where a number characterizing the time interval is also transmitted from the decoder 13.

Turning off the receiver 12 control encoded signals after performing the functional purpose (after receiving, processing and transmitting the code package) reduces the current consumption by the fuse by 2–3 times, which further reduces the dimensions of the power supply 4 and also reduces the heat emission in the electronic block 3 of the fuse, which Improve the accuracy of the countdown.

When reducing the temperature error of the frequency of the clock generator 20 increases the probability of hitting the target from reducing the distance of the place of detonation of the projectile to the target.

Then, the counter 15 starts counting the triggering pulses with a frequency of K times less than the clock frequency, and the circuit 16 compares the current value of the number at the output of the counter 15 with the number transmitted to the time delay device 14 from the decoder 13.

When these numbers coincide, the comparison circuit 16 gives a signal to the output key 19, which opens. In this case, from the discharge of the capacitor 27 through a closed output key 19, a current pulse is supplied to the electric igniter 7.

The force of the flame from the triggered electric igniter 7 (through the fire-transfer channel of the standard centrifugal safety mechanism 8, open by that time) enters the beam detonator capsule 9, causing it to fire, which initiates detonation of the explosive filling of the ammunition and its detonation at a given point on the flight path.

When the projectile encounters for the purpose, the signal from the inertial closure of the contact sensor 6, regardless of the stage of operation of the delay device 14, is priority transmitted through the open remote cocking circuit 17 directly to the output key 19, closing it, thereby causing the projectile to undermine.

Bench and full-scale tests of a prototype fuse of the proposed design actually confirmed the achievement of qualitatively new targets, which allows us to recommend it for the assembly of small-caliber artillery ammunition.

Claims (1)

Combined action fuse for artillery ammunition, comprising a beam detonator, a safety mechanism, an electric igniter and a remote control unit for operating an electric igniter connected to a contact sensor in a case equipped with an optical window, while a time code receiver and electrically controlled devices are connected in series with the remote control unit clock generator, time delay device, long-range cocking and output key for switching an electric igniter with a power source, characterized in that the contact sensor with the long-range cocking circuitry is connected through a normally closed switch of the control unit, controlled by the coincidence circuit of the contact signal of the contact sensor and the polling pulse from the shaper connected to the clock meter, and the axial electric igniter is connected to one of the terminals to the positive pole of the power supply through the resistor and diode and through the capacitor to its negative pole associated with output key.

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