RU2633838C1 - Safety actuator - Google Patents

Abstract

FIELD: weapons and ammunition.

SUBSTANCE: device contains the body with terminals, inside of which there is the explosive charge, the electric detonator with electrical terminals, the key made in the form of microelectromechanical system (hereinafter - MEMS key), opened in the initial position, triggered by overload, exceeding the threshold level, the electronic time block, that provides the countdown of the overload time, exceeding the threshold level and forming the electric impulse at the output, in case of exceeding the duration of the overload action of the certain time value. One of the MEMS key terminals is connected to the safety-actuator terminals, and the other terminal is connected to the electronic time block input, the output of which is connected to the electric detonator electric terminal. In the embodiment, the safety actuator further comprises the MEMS key, opened in the initial position, triggered by the overload, located in the electrical circuit, connecting the electronic time block output to the electric detonator electric terminal, wherein the additional MEMS key is disposed in such a way, that the contacts closure is carried out under the action of centrifugal force, when the safety actuator is rotated around the longitudinal axis.

EFFECT: small weight-size characteristics, increased reliability indices at combat use and safety at service handling.

5 cl, 1 dwg

Description

The invention relates to explosive technology and can be used in fuses of shells.

Known safety cocking mechanism of the fuse, comprising a housing with an electric detonator, a movable partition located in a guide groove in the transverse plane of the body, in the initial position, overlapping the outlet of the electric detonator. A through hole is made in the partition, filled with explosive, displaced in the initial position of the movable partition relative to the axis of the electric detonator. A switching plate is installed on one of the surfaces of the partition, which closes normally open electrical contacts when moving, located in the housing opposite the groove. In the initial position, the movable partition is held by an inertial locking mechanism containing clamps, one of which is made in the form of a stepped cylinder, which locks under the action of longitudinal overload, partially placed in the housing opening, the other part engages with the corresponding hole in the partition, and two centrifugal clamps, made in the form of spring-loaded cylindrical pins located axially symmetrically and diametrically opposite. When fired, the centrifugal clamps are displaced under the action of centrifugal force, releasing the movable partition, which is held in its original position by the clamp under the action of inertia in the longitudinal direction. When decreasing the longitudinal overload under the action of centrifugal force, the movable partition moves. As a result of the displacement of the partition, the axis of the hole filled with explosive is combined with the axis of the electric detonator, the electrical contacts on the housing, which provide connection to the power source, are closed by a switching plate. The safety-cocking mechanism cocked into a fighting position (RF patent No. 2413176, IPC: F42C 15/24, publ. 02.27.2011).

A disadvantage of the known safety-cocking mechanism is the presence in the design of the mechanism of springs and moving parts, respectively, the stability of the parameters over a long shelf life and the accuracy of manufacture of which significantly affect the reliability of the mechanism. Also, the dependence of the reliability of the closure of electrical contacts on the case as a result of the movement of the partition under the action of centrifugal force on the rotation speed of the munition imposes restrictions on the use of a safety-cocking mechanism by type of ammunition.

The task to which the proposed technical solution is directed is to create a safety-executive device with increased reliability of the fuse during combat use, a high level of security in official use, reduced overall weight characteristics.

The solution of this problem is achieved by the fact that the proposed safety-actuating device according to the invention comprises a housing with current leads, inside which there is an electric detonator with electrical leads, a MEMS key made in the form of a microelectromechanical system, open in the initial position and triggered by an overload exceeding the threshold value, an electronic-time unit providing a countdown of the overload action time exceeding the threshold level and generating an electric output pulse if the duration of the overload action exceeds a certain time value, while the MEMS key is located in such a way that the contacts are closed when the projectile contacts the obstacle under the influence of the overload acting along the longitudinal axis of the safety-executive device, while one of the MEMS key contacts connected to the current output of the safety-executive device, and the other contact is connected to the input of the electronic-time unit, the output of which is connected to the electrical output of the electric detonator.

In an embodiment, the safety-actuating device contains an additional MEMS key, open in the initial position, triggered by overload, placed in an electrical circuit connecting the output of the electronic-temporal block to the electric output of the electric detonator, while the additional MEMS key is located so that the circuit The contacts are carried out under the action of centrifugal force during rotation of the safety-executive device around the longitudinal axis.

In an embodiment, the safety-executive device additionally contains two or more MEMS keys, electrically connected in series, open in the initial position, triggered by overload, placed in an electrical circuit connecting the output of the electronic-temporal block to the electrical output of the electric detonator, while the specified MEMS the keys are located in such a way that the contact closure is carried out under the action of centrifugal force during the rotation of the safety-actuator wok a circle along the longitudinal axis, wherein the MEMS keys are located relative to the longitudinal axis, preferably diametrically opposite.

In an embodiment, the safety-executive device contains two or more MEMS keys, open in the initial position, triggered by the action of overload, while one of the MEMS keys is located so that the MEMS key contacts are closed when the projectile encounters an obstacle under the influence of an overload exceeding the threshold level, acting along the longitudinal axis of the safety-actuating device, while one of the contacts of the specified MEMS key is connected to one of the fuses of the actual actuator, and the other contact is connected to the input of the electronic-time unit, the output of which is connected to one of the electrical outputs of the electric detonator, while the other two or more MEMS keys are connected in series to the electrical circuit, one end of which is connected to the second current output of the safety-executive devices, and the other end is connected to the second electrical output of the electric detonator, while the MEMS keys forming a serial electric circuit are arranged so that the contact closes s is carried out under the influence of centrifugal forces during rotation of slam-actuator around a longitudinal axis, wherein the MEMS keys arranged around the rotation axis are preferably diametrically opposed.

In an embodiment, the safety-actuating device contains a two-component MEMS key, which includes two groups of electrically independent contacts arranged so that the contact closure of different groups is effected by forces whose directions of action for different contact groups are mutually perpendicular, while the MEMS key is located in the housing of the safety-executive device in such a way that the closure of the contacts of one group is carried out upon contact of the projectile with an obstacle under a longitudinal overload exceeding the threshold level, and the closing of the contacts of the other group is carried out under the action of centrifugal forces, when the safety-actuating device rotates around the longitudinal axis, while the group of contacts operating under the action of the longitudinal overload is connected by one of the contacts to the current output of the safety-executive device and the other contact is connected to the input of the electronic-time unit, the output of which is connected to the contact group, which is triggered by the action of cent robust force, the other contact of which is connected to the electrical output of the detonator.

The technical result is the creation of a safety-actuating device with lower overall weight characteristics, increased safety and reliability.

The invention is illustrated in FIG. 1. In FIG. 1 shows a structural diagram of a safety-actuating device.

The safety-executive device contains a housing 1 with current outputs, an electric detonator 2 with electrical outputs, a MEMS key 3, which is activated by longitudinal overload, an electronic-time unit 4.

The proposed safety-executive device operates as follows.

Preliminary safety-actuating device is placed in the fuse of the projectile so that the longitudinal axis of the device coincides with the longitudinal axis of the projectile. When the projectile encounters an obstacle under the action of longitudinal overload exceeding the threshold level, the MEMS key 3 closes, and the voltage supplied to the current outputs of the safety-executive device is fed to the input of the electronic-temporal block 3, which starts counting the duration of the longitudinal overload exceeding threshold level. If the counted time interval exceeds a certain value, an electric signal is generated at the output of the electronic-time block 4, which arrives at the electrical output of the detonator 2 and initiates its operation.

A positive effect achieved by the implementation of the proposed technical solution is to reduce the overall weight and weight characteristics of the safety-executive device, increase the reliability of the device during combat use, and ensure a high level of security in official use.

Claims (5)

1. Safety-actuating device, characterized in that it contains a housing with current leads, inside of which there is an electric detonator with electrical leads, a MEMS key made in the form of a microelectromechanical system, open in the initial position and triggered by an overload that exceeds the threshold value, electronic-time a unit providing a countdown of the overload action time exceeding the threshold level and generating an electric pulse at the output in case of exceeding the duration of action overload of a certain time value, while the MEMS key is located in such a way that the contacts are closed when the projectile contacts the obstacle under the influence of an overload acting along the longitudinal axis of the safety-executive device, while one of the contacts of the MEMS key is connected to the current output of the safety-executive device, and the other contact is connected to the input of the electronic-time unit, the output of which is connected to the electrical output of the detonator. 2. The device according to p. 1, characterized in that it contains an additional MEMS key, open in the initial position, triggered by overload, placed in an electrical circuit connecting the output of the electronic-temporal block to the electric output of the electric detonator, while the additional MEMS key is located so that the contact closure is carried out under the action of centrifugal force during rotation of the safety-actuating device around the longitudinal axis. 3. The device according to claim 1, characterized in that it further comprises two or more MEMS keys, electrically connected in series, open in the initial position, triggered by overload, placed in an electrical circuit connecting the output of the electronic-temporal block to the electric output of the electric detonator, while the specified MEMS keys are located in such a way that the contact closure is carried out under the action of centrifugal force during rotation of the safety-actuating device around the longitudinal axis, and MEMS keys are located relative to the longitudinal axis, preferably diametrically opposed. 4. The device according to claim 1, characterized in that it contains two or more MEMS keys, open in the initial position, triggered by overload, while one of the MEMS keys is located in such a way that the contacts of the MEMS key are closed when they meet a projectile with an obstacle under the influence of an overload exceeding the threshold level acting along the longitudinal axis of the safety-executive device, while one of the contacts of the specified MEMS key is connected to one of the current outputs of the safety-executive device device, and the other contact is connected to the input of the electronic-time unit, the output of which is connected to one of the electrical outputs of the electric detonator, while the other two or more MEMS keys are connected in series to the electrical circuit, one end of which is connected to the second current output of the safety-executive device, and the other end is connected to the second electrical output of the electric detonator, while the MEMS keys forming a serial electric circuit are arranged so that the contacts are closed under tviem centrifugal forces during rotation of slam-actuator around a longitudinal axis, wherein the MEMS keys arranged around the rotation axis are preferably diametrically opposed. 5. The device according to any one of paragraphs. 1, 2, 3, characterized in that it contains a two-component MEMS key, including two groups of electrically independent contacts, arranged in such a way that the contact closure of different groups is effected by forces whose directions of action for different contact groups are mutually perpendicular, while MEMS - the key is located in the housing of the safety-executive device in such a way that the closure of the contacts of one group is carried out when the projectile contacts the obstacle under the action of longitudinal overload, exceeding th threshold level, and the closing of the contacts of the other group is carried out under the action of centrifugal forces, when the safety-actuating device rotates around the longitudinal axis, while the group of contacts operating under the action of longitudinal overload is connected by one of the contacts to the current output of the safety-executive device, and the other contact connected to the input of the electronic-time block, the output of which is connected to a contact group operating under the action of centrifugal force, the other contact of which union of a elektrovyvodom EB.

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