RU2475697C1 - Method of time-fuse setting and reckoning - Google Patents

Abstract

FIELD: weapons and ammunition.

SUBSTANCE: proposed method comprises generation of data signals by instrument setter. Data signals are shaped as action time code with time interval between two fixed members equal to t_y. Time-fuse converts time interval t_y during setting into time interval code with its numerical value N_y defined by counting the time-fuse clock frequency pulses generated during t_y, while, in reckoning, time-fuse generates output instruction on reaching the sum of clock frequency pulses equal to product of code numerical value N_y loaded by setter of time interval N_y by numerical value defined by tome code setter and constant scale factor.

EFFECT: higher accuracy of countdown, increased input data volume.

4 cl, 1 dwg

Description

The invention relates to the field of military equipment, and more particularly to electronic remote fuses, and can be used to count the time of the remote action of fuses of artillery and rockets, bombs and other ammunition. In addition, it can be used for counting time of long-range cocking and self-destruction. In particular, the present invention can be used to form fuse commands to detonate ammunition, detachment of the warhead, disclosure of the cluster warhead, ejection of a parachute system, etc.

Known methods for counting the time of action used in remotely-contact fuses according to US patent No. 4389937, IPC Р42С 9/02, Р42С 15/04, Р42С 15/34, published on 06/28/1983; No. 4739706, IPC Р42С 9/02, Р42С 9/14, Р42С 15/24, published on 04/26/1988, in which the remote action time is fixed and cannot be reset before firing.

A known method of setting the time of action of a remote fuse according to US patent No. 4750424, IPC Р42С 9/00, published on June 14, 1988, using a manual installer. This method cannot be used in conditions of an automated shot due to the inability to enter the time for the remote action of the fuse when the projectile is on the launcher.

Closest to the claimed is a method of installing and counting the time of the fuse used in a remote contact fuse for marine multiple launch rocket systems according to the patent for the invention of the Russian Federation No. 221205, publ. 11/27/2004, Bull. No. 33, IPC R42C 9 / 02.15 / 40. This method is selected as a prototype.

The temporary device used in the prototype is made on the basis of a clockwork. It counts the time in a known manner described in the book: Shpolyansky V.A. Timekeeping. - M.: Engineering, - 1974, p. 74, Fig. 1.5, expression (1.15) and p. 249, Fig. 2.4. This method is based on the use of integrating the reference signal (summing the clock pulses) to obtain some parameter (rotation angle, analog electrical signal, time code, etc.) necessary for further use, in particular, for generating an output command when the reference integral is reached signal (sum of clock pulses) of the required value.

The installation and timing of the fuse according to the invention adopted as a prototype is as follows. When setting the action time, the installer generates information signals that determine the required action time of the temporary device. This information is supplied in the form of pulses, the number of which is determined by the required duration of action. At the same time, the fuse installation device, made on a pulsed (step-by-step) electric motor, expands the slot for the clockwork arrow at an angle corresponding to the number of pulses supplied to the fuse and determines the set action time. When counting the action time, integration (summation of pulses) of the reference signal (clock frequency) is carried out with a certain constant scale factor determined by the wheel transmission of the clock mechanism. As the reference signal, the frequency of oscillations of the balance of the clockwork (clock frequency) is used, the time integral (the sum of the periods of oscillations of the balance of the clockwork) which is represented as the angle of rotation of the arrow of the clockwork. If the integral of the reference signal (the sum of the periods of balance fluctuations) is equal to the set value, the output command is formed.

In other words, the described method for setting and counting down the action time consists in performing the following operations:

formation by the installer of information signals in the form of the number of pulses that determine the set action time,

fuse summation of pulses from the installer,

fuse formation of reference signals (clock frequency) in the form of signals corresponding to the frequency of oscillation of the balance of the clockwork,

fuse summing of reference signals (clock pulses) with the necessary scaling,

generating an output signal when the sum of the scaled reference signals (clock pulses) reaches the required value equal to the sum of the pulses received from the installer.

The reason that impedes obtaining the required technical result is the low accuracy caused by the dependence of the measured action time on the parameters of the reference signal (oscillation frequency of the balance of the fuse clock mechanism), as well as the small amount of information entered by the installer and the impossibility of introducing additional information into the fuse related to the need to count additional teams.

The problem to which the claimed invention is directed is to develop a method for installing and counting the time of action of the fuse, which ensures high accuracy of counting the set time of action, to develop a method in which there would be no influence of the instability of the reference signal on the measured time of action at any value. In addition, the task to which the invention is directed is to increase the amount of information entered by the installer into the fuse.

The essence of the invention lies in the fact that in the proposed method, which uses the installer to generate information signals that determine the required fuse time, the fuse generates a reference signal in the form of a clock frequency, sums the clock pulses in the process of reporting the action time and generates an output command when the specified amount is reached necessary value, a number of additional operations are carried out. Installer information signals are generated in the form of an action time code, the time interval between two fixed elements of which is equal to the value of t _y . The fuse during the installation process converts the time interval t _y into the code of the time interval, the numerical value of N _y which is determined by counting the number of clock pulses arriving during the time interval t _y . When counting the action time, the fuse generates an output command when the sum of the clock pulses is reached, the product of the numerical code value of the time interval t _y entered by the installer by the numerical value of the action time code received from the installer and a constant scale factor.

The time interval and the code formed by the installer can be constant or variable.

When choosing a constant time interval t _y independent of the set time, the numerical value corresponding to the action time code entered by the installer is equal to the ratio of the set time to the product of the time interval t _y and a constant scale factor.

If the action time code entered by the installer is constant, the time interval t _y between two elements of the specified code is chosen equal to the ratio of the action time to be set to the product of the number corresponding to the action time code and the scale factor to be entered.

If it is necessary for the installer to enter additional information, at a constant value of the time interval between two code elements, the code supplied by the installer consists of several parts, one part of the code contains information about the action time code, and the subsequent parts contain the code for the duration of additional times. The countdown of the formation of additional time commands is carried out by summing the clock pulses until the specified sum of the product of the numerical value of the code entered by the installer of the time interval t _y by the numerical values of the codes of the duration of additional commands received from the installer and the scale factors of the additional commands is reached.

The technical result of the proposed method is the high accuracy of the set time of the action. When using the proposed method, it becomes possible to increase the amount of information transmitted by the installer to the fuse.

The proposed method involves performing a sequence of the following operations.

1. During prelaunch preparation when entering information about the required duration of action into the fuse:

1.1 the formation by the installer of the signal in the form of an action time code, the time interval between two elements of which is t _y

1.2 the formation of the fuse clock frequency f _t

1.3 conversion by the fuse of the time interval t _y received from the installer into the code of this time interval, the numerical value of N _{y of} which is determined by counting the number of pulses of the fuse clock frequency arriving during the time interval t _y ,

2. When counting the time of action:

2.1 the formation of the fuse clock frequency f _t

2.2 summation of clock pulses,

2.3 formation of the output command when the sum of the pulses of the clock frequency reaches a value equal to the product of the numerical value N _{y of the} code entered by the installer of the time interval N _y by the numerical value of the action time received from the installer and a constant scale factor.

The time interval between two elements of the action time code entered by the installer into the fuse and the numerical value of the action time code can be both constant and variables depending on the action time being set.

In the variant of a constant time interval between two elements of the action time code entered by the installer into the fuse, the numerical value corresponding to the action time code entered is selected to be equal to the ratio of the set action time to the product of the time interval t _y by a constant scale factor.

In the variant of a constant value of the numerical value of the action time code entered into the fuse by the installer, the time interval between two elements of the specified code is the ratio of the action time to be set to the product of the number corresponding to the action time code entered and the scale factor.

If it is necessary for the fuse to count additional times, the time interval between two code elements is selected constant, and the code supplied by the installer consists of several parts, the first part of the code contains information about the action time code, and its subsequent parts contain the code for the duration of additional times, and the countdown of the formation of commands additional times is carried out by summing the clock pulses until the specified sum of the value equal to the product of the numerical value is reached the code entered by the installer of the time interval t _y to the numerical values of the duration of the additional commands received from the installer of the codes and the scale factors of the additional commands.

Common features of the prototype with the present invention is the use of the installer to generate information signals that determine the required fuse time, fuse formation of the clock frequency, summing the clock pulses in the process of counting the action time and the formation of the output command when the specified amount is reached the required value.

We show high accuracy of the countdown of the set action time.

During installation, the fuse converts the time interval t _y supplied by the installer into the time interval code. The numerical value N _y of the time interval code is determined by the fuse by counting the number of pulses of the fuse clock frequency arriving during the time interval t _y ,

When counting the action time, the fuse generates an output command when the sum of the clock pulses reaches a value equal to the product of the numerical value N _{y of the} code entered by the installer of the time interval t _y by the numerical value of the action time from the installer and a constant scale factor.

Thus, the duration of T _d is

where K _d is the numerical value of the action time code entered into the fuse by the installer,

M _d - scale factor of the numerical value of the action time code,

f _ti - the value of the clock frequency during the formation of the i-th clock pulse.

The value of the clock frequency during installation and counting does not change and is equal to

f _ti = f _t .

Then expression (2) takes the form

Substitute the value of N _y from the expression (1)

It was obtained that, since the clock frequency f _m does not enter expression (4), its instability does not cause an error in counting the action time.

If it is necessary to generate additional commands, part of the code supplied by the installer contains codes for the duration of additional times. Moreover, the durations of additional times are determined by an expression similar to the expression (4)

T _add = K _addi · M _addi · t _y ,

where T _dopi is the i-th additional time counted by the fuse,

K _dopi is the numerical value of the i-th code,

M _exti scale factor of the i-th additional team.

An example of the formation of several commands by a remote fuse is a command for the distant cocking of the fuse, separation of the head of the projectile, opening the parachute system, connecting the target’s sensor, slowing down when meeting an obstacle, self-liquidating, etc.

When used to set the binary code as the time interval t _y , the time interval between any two code elements, for example, between the start and stop bits, as shown in FIG. 1 _, can be used.

With the required remote control time from 1 to 100 s, the parameters of the signals entered by the installer can be as follows:

type of transmitted code - binary,

code structure - start bit, 12 data bits, stop bit,

the time interval between the start of the start bit and stop bit is constant, t _y = 100 ms,

the range of the numerical value of the action time code is K _d = (100 ... 4095),

scale factor - M _d = 0.25.

Then, in accordance with the expression (4)

T _d = (100 ... 4095) · 0.25 · 0.1 = (100 ... 4095) · 0.025 = 2.5 ... 102.375 s.

In the particular case, for the version of the action time code that the installer constantly enters, the bits of this code may be absent and only the “start” bit and the “stop” bit will be present in the data input sequence diagram. In this case, the numerical value of the code entered by the installer can be taken equal to any predetermined non-zero number, for example, equal to 1.

In this case, the parameters of the signals entered by the installer can take the following values:

the numerical value of the action time code is constant - K _d = 1,

scale factor - M _d = 2048,

the time interval between the start of the start bit and the ston bit

In accordance with the expression (4)

T _d = 1 · 2048 · t _y = 2048 · t _y .

The laboratory bench tests have confirmed the achievement of the technical result of the proposed method is the high accuracy of the fuse timing and the increase in the amount of information entered by the installer into the fuse.

Claims (4)

1. The method of installation and timing of the action of a remote fuse, including the installer generating information signals that determine the required fuse time, forming the fuse clock frequency, adding the clock pulses in the process of counting the action time and generating the output command when the specified amount of the required value is reached, characterized in that the installer’s information signals are generated in the form of an action time code, a time interval between two fixed the elements of which are equal to the value of t _y , in the fuse during installation, the time interval t _y is converted into a time interval code, the numerical value of N _{y of} which is determined by counting the number of pulses of the fuse's clock frequency arriving during the time interval t _y , and when counting the action time in the fuse, the output command is formed when the sum of the pulses of the clock frequency reaches a value equal to the product of the numerical value N _{y of the} code entered by the installer of the time int the gap t _y by the numerical value of the action time and constant scale factor received from the installer. 2. The method according to claim 1, characterized in that the value of the time interval between two elements of the action time code entered by the installer into the fuse is selected constant, independent of the set action time, and the numerical value corresponding to the action time code entered by the installer is equal to the ratio of the established time actions to the product of the time interval t _y by a constant scale factor. 3. The method according to claim 1, characterized in that the value of the action time code entered by the installer into the fuse is selected constant, and the time interval between two elements of the specified code is equal to the ratio of the action time to be set to the product of the number corresponding to the action time code entered and the scale factor. 4. The method according to claim 1, characterized in that for a constant value of the time interval between two code elements, the code supplied by the installer consists of several parts, the first part of the code contains information about the numerical value of the action time code, and its subsequent parts contain information about the duration codes additional times, while the countdown of the formation of teams of additional times is carried out by summing the pulses of the clock frequency until the specified sum of values equal to the product of the numerical The shutter code entered by the installer time interval t _y on the numerical values of the scale factors and additional commands received from the installer duration additional command codes.

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