RU2642695C1 - Contact sensor - Google Patents

Abstract

FIELD: weapons and ammunition.

SUBSTANCE: invention relates to the field of armaments and can be used in weapons of bursting munitions. Sensor contains a housing with an electric line and an electrical outlet. Sensor element of the sensor is made in the form of a microelectromechanical system – MEMS device. This device is provided with the ability to operate under overload. an electronic time block providing an overload time counting time exceeding a threshold level, and the formation of a control signal in the event that the measured time exceeds a certain value. In this case, the MEMS device is arranged in such a way that the operation is provided under the effect of an overload exceeding the threshold level, acting along the longitudinal axis of the trigger mechanism. Input of the MEMS device is connected to the electrical conductor of the contact sensor. Output of the MEMS device is connected to the input of the electronic time block providing the counting of the duration of the longitudinal overload action and the supply of the target identification signal exceeding the threshold level and forming an electric pulse at the output in case of exceeding the duration of the overload action exceeding the threshold level of a certain time value.

EFFECT: increase the reliability of the device due to the contact sensor of increased sensitivity during interaction of the ammunition with the purpose, Increase of security in the service circulation and resistance to the impact of small-scale interference on the trajectory.

4 cl, 2 dwg

Description

The invention relates to the field of weapons and can be used in fuses of explosive ordnance.

Known contact sensor of the target, containing the bearing housing, a sensing element in the form of an outer shell, placed with a gap relative to the housing, and at least one pair of electrical contacts made with the possibility of short circuit during deformation of the portion of the outer shell facing the target, by the size of the gap , the electrical contacts are made in the form of contacting insulated conductors placed in the gap between the outer shell and the supporting body. The implementation of electrical contacts in the form of insulated conductors located in the gap between the outer shell and the bearing body eliminates the need to apply voltage to the elements of the shell of the ammunition. In this case, the noise immunity of the contact target sensor is increased, and its design is greatly simplified, since the elements insulating the contacts of the sensor and, accordingly, the elements of the ammunition case from each other are not needed (RF patent No. 2416780, IPC F42C 1/00, publ. 04/20/2011).

The sensor operates as follows. When the munition strikes with a target in the corresponding sensitivity zone, the outer shell is deformed by an amount equal to the gap between the bearing body and the outer shell. In this case, the insulation is destroyed between the conductors and / or between each conductor and the surfaces of the bearing body and the outer shell. Due to the destruction of the insulation, the conductors are closed, and upon their closure, a command is issued to undermine the ammunition.

The main disadvantage of the described device is the low sensitivity, determined by the force necessary for the deformation of the outer shell and destruction of the insulation between the conductors and / or the surfaces of the bearing housing and the outer shell.

The task to which the proposed technical solution is directed is to create a contact sensor, characterized by high sensitivity when meeting ammunition with a target, high safety indicators in official use, and increased resistance to small interference on the trajectory.

The solution to this problem is achieved by the fact that the proposed contact sensor according to the invention comprises a housing with an electric input and an electric output, a sensing element made in the form of a microelectromechanical system (hereinafter referred to as the MEMS device), triggered by the action of an overload, an electronic-time unit that provides an indication of the duration of the overload exceeding the threshold level, and generating a control signal in case the measured time exceeds a certain value, while the MEMS device is located so that the operation is carried out under the influence of an overload exceeding the threshold level acting along the longitudinal axis of the contact sensor, while the input of the MEMS device is connected to the electric input of the contact sensor, and the output of the MEMS device is connected to the input of the electronic-time block, which provides a countdown of the action time longitudinal overload and supplying the target identification signal to the output of the contact sensor in case of exceeding the duration of the overload action exceeding the threshold level, o definiteness nonce.

In the embodiment, the sensing element is made in the form of a MEMS key open in the initial position, one contact of which is connected to the electric input of the contact sensor, the other contact of the switch is connected to the input of the electronic-time block, which provides an indication of the overload action time, the output of which is connected to the output of the contact sensor moreover, the MEMS key is located in such a way that the contact closure is carried out under the action of longitudinal overload exceeding the threshold level.

In the embodiment, the contact sensor contains two MEMS devices, one of the MEMS devices being arranged in such a way that the operation is performed under the action of an overload exceeding the threshold level acting along the longitudinal axis of the contact sensor, while the input of the specified MEMS device is connected to the contact electric input sensor, the output of the specified MEMS device is connected to the input of the electronic-temporal block, providing a countdown of the longitudinal overload, the output of the electronic-temporal block is connected to the input of the second MEMS device, the output of which is connected to the output of the contact sensor, the second MEMS device is located in such a way that the operation, which ensures the transmission of the signal from the output of the electronic-temporary block to the output of the contact sensor, is carried out under the action of centrifugal force exceeding the threshold value that occurs when the contact sensor rotates around the longitudinal axis.

In the embodiment, the contact sensor contains two or more MEMS devices, and one MEMS device is located in such a way that the device is triggered by an overload that exceeds the threshold level acting along the longitudinal axis of the contact sensor, while the input of the MEMS device that accepts the longitudinal overload, connected to the electrical input of the contact sensor, while the output of the specified MEMS device is connected to the input of the electronic-time unit, providing a countdown of the time loads, while the remaining MEMS devices are electrically connected in series and placed around the longitudinal axis of the contact sensor, preferably diametrically opposed, and so arranged that they are triggered by centrifugal forces when the contact sensor rotates around the longitudinal axis, with the input of the first the circuit of the MEMS device is connected to the output of the electronic time device, and the output of the last, in the specified circuit, MEMS device is connected to the output of the contact sensor and, wherein the transmission signal output from the electron-time block at the output of the contact sensor is subject to triggering of MEMS devices centrifugal action.

The technical result is the creation of a contact sensor, characterized by increased sensitivity during contact blasting, increased resistance to small interference on the projectile flight path, and a high level of security in official use.

The invention is illustrated by drawings, where in FIG. Figure 1 shows a structural diagram of an embodiment of a contact sensor with a MEMS device for linear actuation and two MEMS devices for centrifugal actuation, in Fig. 2 shows a block diagram of a contact sensor.

The contact sensor comprises a housing 1 with an electric input 2 and an output contact 3, a MEMS device 4 that is triggered by longitudinal overload, an electronic-time unit 5, two MEMS devices 6 that are triggered by centrifugal force and are located diametrically opposite.

The proposed contact sensor operates as follows.

Previously, the contact sensor is placed in the munition fuse so that the longitudinal axis of the contact sensor coincides with the longitudinal axis of the projectile. When a projectile is fired, voltage is applied to the electric input 2 of the contact sensor. At the time of the shot, when the projectile reaches a certain speed, under the action of centrifugal force, MEMS devices 6 are activated, providing a circuit closure connecting the output of the electronic-temporary block 5 to the output of the contact sensor. Further, when the ammunition collides with the target, when the longitudinal overload of the threshold level is reached, the MEMS device 4 is triggered, a signal is received at the input of the electronic-time block 5, which initiates the counting of the time of the longitudinal overload. When the duration of the longitudinal overload exceeds a certain time value, the target identification signal is generated at the output of the electronic-temporal block 5, which is output to the contact sensor.

If the duration of the longitudinal overload exceeding the threshold value is less than a certain time value, for example, in the event of an ammunition collision with small-sized interference on the trajectory, as a result of reducing the overload below the threshold level and stopping the signal from the output of the MEMS device 4 to the electronic-temporal input of block 5, the countdown is interrupted by the electronic-temporal block 5, the target identification signal is not generated at the output of the electronic-temporal block, and the sensor does not work.

Implementation of the proposed technical solution will allow you to create a small-sized contact sensor, characterized by high sensitivity when meeting ammunition for the purpose, high safety performance in official use, and increased resistance to small interference on the trajectory.

Claims (4)

1. A contact sensor, characterized in that it contains a housing with an electric input and an electric output, a sensitive element made in the form of a microelectromechanical system - a MEMS device, which can be triggered by the action of an overload, an electronic-time unit that provides the possibility of counting the overload action time exceeding threshold level, and the formation of the control signal in case the measured time exceeds a certain value, while the MEMS device is located in this way m, that the operation is ensured under the action of an overload exceeding the threshold level acting along the longitudinal axis of the contact sensor, while the input of the MEMS device is connected to the electrical input of the contact sensor, and the output of the MEMS device is connected to the input of the electronic-temporal block, which provides a countdown of the longitudinal action overload and the signal of identification of the target to the output of the contact sensor in case the duration of the overload exceeds the threshold level of a certain time value. 2. The contact sensor according to claim 1, characterized in that the sensitive element is made in the form of a MEMS key open in the initial position, one contact of which is connected to the electric input of the contact sensor, the other contact of the switch is connected to the input of the electronic-time unit, which provides a countdown an overload action, the output of which is connected to the output of the contact sensor, moreover, the MEMS key is located in such a way that the contact closure is ensured by longitudinal overload exceeding the threshold level. 3. The contact sensor according to claim 1, characterized in that it contains an additional MEMS device, wherein one of the MEMS devices is arranged in such a way that the operation is ensured by an overload exceeding the threshold level and acting along the longitudinal axis of the contact sensor, the input of the specified MEMS device is connected to the electrical input of the contact sensor, the output of the specified MEMS device is connected to the input of the electronic-time block, which provides a countdown of the longitudinal overload, while the output is electric of the electronic-time unit is connected to the input of the second MEMS device, the output of which is connected to the output of the contact sensor, the second MEMS device is located in such a way that the operation, in which the signal is transmitted from the output of the electronic-time unit to the output of the contact sensor, is provided under the action of centrifugal force exceeding the threshold value that occurs when the contact sensor rotates around the longitudinal axis. 4. The contact sensor according to claim 1, characterized in that it contains at least one additional MEMS device, wherein one MEMS device is positioned so that the device is triggered by an overload exceeding the threshold level acting along the longitudinal axis of the contact a sensor, wherein the input of the MEMS device that senses longitudinal overload is connected to the electrical input of the contact sensor, while the output of the specified MEMS device is connected to the input of the electronic-time block, which ensures the countdown of the overload action time, while the remaining MEMS devices are electrically connected in series and placed around the longitudinal axis of the contact sensor, preferably diametrically opposed, and arranged so that their operation is ensured by centrifugal forces when the contact sensor rotates around the longitudinal axis, while the input of the first in the indicated circuit of the MEMS device is connected to the output of the electronic-temporal device, and the output of the last in the specified circuit of the MEMS device is connected to Exit contact sensor, wherein the transmission signal output from the electron-time block at the output of the contact sensor provided under the condition of the MEMS switching devices centrifugal action.

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