KR20240066644A - Fuse structure capable of controlling warhead power and warhead capable of controlling warhead power including the same, and method of detonating warheads - Google Patents

Abstract

The present invention relates to a fuse structure capable of adjusting warhead power, a warhead including the same with adjustable warhead power, and a method for detonating a warhead. The present invention relates to a method for detonating a warhead by burning part of the gunpowder in the warhead with an auxiliary fuse to control the amount of gunpowder detonated in the warhead. By detonating the warhead with the main fuse, the power of the warhead can be adjusted according to the battle situation, minimizing damage to civilian facilities and civilians other than the target. In particular, when applied to aerial bombs, several types of power can be produced with a single aerial bomb. This is useful when narrowing the damage radius and hitting only specific areas.

Description

A fuse structure capable of adjusting warhead power, a warhead including the same with adjustable warhead power, and a method of detonating a warhead

The present invention relates to a fuse structure capable of adjusting the power of a warhead, a warhead including the same with an adjustable warhead power, and a method of detonating a warhead. More specifically, it relates to a warhead power controllable warhead power capable of adjusting the power of a warhead using two fuses. The invention relates to a fuse structure, a warhead capable of controlling the power of a warhead including the same, and a method of detonating the warhead.

A guided missile is an assembly composed of various parts such as a propulsion engine, airframe, guidance control device, drive device, seeker, inertial navigation device, and warhead/fuse.

In other words, a guided missile is a guided weapon that flies to a target or target point and then explodes to hit the target or target point.

Inside the warhead of a guided missile, a main charge for explosion is located, a detonator tube to detonate the main charge, and a fuse to operate the detonator tube are located.

Not only guided missiles, but also various types of warheads to hit targets must have appropriate penetration power, explosion pressure, or fragmentation performance in order to penetrate the target, and the internal fire

General guided weapons, that is, various types of warheads that explode through a fuse, including guided missiles, have so far been focused on destroying the target, and have a structure in which the entire gunpowder in the warhead is detonated at once with the maximum possible power. there is.

And, in modern warfare, where the population has increased worldwide and urban areas have developed over a wide area, not only the destruction of enemy forces but also the damage to surrounding civilians cannot be avoided.

Conventional warheads had the problem of not being able to adjust their power according to the war situation and having a structure that explodes at the maximum, causing civilian casualties while hitting and neutralizing the target when used.

In particular, conventional warheads, when used in urban battles, had the problem of not only destroying buildings unrelated to the target while hitting the target, but also causing significant casualties to civilians.

Korean Patent Registration No. 0210113 "Serial warhead equipped with piezoelectric percussion fuze" (registered on April 23, 1999)

The object of the present invention is to adjust the power of the warhead by burning a part of the gunpowder in the warhead with an auxiliary fuze and controlling the amount of gunpowder detonated in the warhead, and a warhead with adjustable warhead power including the same. and providing a method for detonating a warhead.

In order to achieve the above object, an embodiment of the fuse structure capable of controlling warhead power according to the present invention includes an auxiliary fuse unit that burns or explodes a portion of the total amount of gunpowder in the warhead, and the remainder of the total amount of gunpowder in the warhead. It is characterized by including a main fuse that explodes the part.

One embodiment of the fuse structure capable of adjusting warhead power according to the present invention connects the main fuse unit and the auxiliary fuse unit and transmits a detonation signal to the auxiliary fuse unit or transmits a detonated signal from the auxiliary fuse unit to the main fuse unit. It may further include a cable section.

One embodiment of the fuse structure capable of adjusting warhead power according to the present invention may further include a power supply unit connected to the cable unit and supplying power to the main fuse unit and the auxiliary fuse unit through the cable unit.

In the present invention, the auxiliary fuse may be provided within the entire gunpowder so as to have the minimum amount of detonation capable of igniting the gunpowder, and the main fuse may be provided within the entire gunpowder amount so as to have the minimum amount of detonation capable of igniting the entire gunpowder. there is.

In the present invention, the main fuse may include a warhead power control unit that adjusts the power of the warhead by delaying the detonation time of the main fuse after applying a detonation signal to the auxiliary fuse unit.

In the present invention, the warhead power control unit includes an explosion power selection switch unit that can select the explosion power of the warhead, and after the auxiliary fuse unit is detonated according to the selected explosion power, the detonation delay time of the main fuse unit is pre-stored in the After the auxiliary fuse is detonated according to the explosion power selected by the explosion power selection switch unit, the main fuse unit may be detonated after a preset detonation delay time.

In the present invention, the warhead power control unit can select the power of the warhead in conjunction with the guidance kit or guidance control device, and after the auxiliary fuse unit is detonated according to the selected explosion power, the detonation delay time of the main fuse unit is pre-stored and the induction After the auxiliary fuse is detonated according to the explosion power selected by the kit or the guidance control device, the main fuse can be detonated after a preset detonation delay time.

In the present invention, the warhead power control unit may further include a detonation signal application delay switch unit that sets a delay time for applying the initial detonation signal to the auxiliary fuse unit after the preset detonation condition is confirmed.

One embodiment of the fuse structure capable of adjusting warhead power according to the present invention is connected to a cable part that connects the main fuse part and the auxiliary fuse part and transmits a detonation signal from the main fuse part to the auxiliary fuse part, and the cable part. The cable unit further includes a power supply unit that supplies power to the main fuse unit and the auxiliary fuse unit, and the auxiliary fuse unit is provided with a full amount of explosive charge inside so as to have a minimum amount of detonation capable of igniting the gunpowder among the entire gunpowder, The main fuse has a full explosive charge capable of detonating the entire gunpowder of the warhead, and the main fuse controls the power of the warhead by delaying the detonation time of the main fuse after applying a detonation signal to the auxiliary fuse. It includes a power control unit, and the warhead power control unit includes a switch unit for selecting an explosion power that can select the explosion power of the warhead, and adjusts the detonation delay time of the main fuse unit after the auxiliary fuse unit is detonated according to the selected explosion power. The explosive power of the warhead can be adjusted.

In addition, an embodiment of the warhead capable of adjusting the power of the warhead according to the present invention includes a warhead body filled with gunpowder for explosion inside, a fuse mounted on the warhead body to explode the warhead, and the fuse is the main body. It is characterized by a fuse structure capable of adjusting the power of the warhead according to the invention.

In addition, an embodiment of the method of detonating a warhead according to the present invention is a fuse that includes an auxiliary fuse unit that burns or detonates a part of the total amount of gunpowder in the warhead and a main fuse part that explodes the remaining part of the total amount of gunpowder in the warhead. It is a method of detonating a warhead equipped with a structure, an explosion power setting step of setting the explosion power of the warhead before the warhead is launched from a launch device or dropped from an aircraft, a warhead launch step where the warhead is launched from a launch device or dropped from an aircraft, A fuse loading step of loading the auxiliary fuse unit and the main fuse unit under preset conditions, respectively, after the warhead firing step, an explosion signal application step of applying an explosion signal under the detonation conditions of the warhead after the fuse loading step, and the explosion signal application step. After selectively operating the auxiliary fuse unit, and finally operating the main fuse unit, it is characterized in that it includes a warhead explosion step of exploding the warhead with the explosion power set in the explosion power setting step.

In the present invention, the warhead explosion step is the entire explosion process of detonating the warhead by operating only the main fuse when the explosion power of the warhead is set to 100% in the explosion power setting step, and the explosion power of the warhead in the explosion power setting step is 0. If the % is greater than 100%, the auxiliary fuse is activated, and after a preset delay time after the auxiliary fuse is activated, the main fuse is activated to explode the warhead with a preset explosion power.

In the present invention, the detonation delay time of the main fuse is pre-stored according to the explosion power of the warhead, and the partial explosion process is performed after the auxiliary fuse is detonated and after the detonation delay time corresponding to the explosion power set in the explosion power setting step. The main fuse can be detonated.

In the present invention, the partial explosion process does not explode the warhead after detonation of the auxiliary fuse, but reduces the amount of gunpowder during the preset detonation delay time as the gunpowder in the warhead is burned, and the amount of gunpowder suitable for the preset explosion power remains among the total amount of gunpowder. When the main fuse is detonated, the entire amount of gunpowder remaining can be detonated, thereby detonating the warhead.

The present invention controls the amount of gunpowder detonated within the warhead by combusting the gunpowder within the warhead with an auxiliary fuze, and then explodes the warhead with the main fuze to adjust the power of the warhead to suit the combat situation, thereby preventing damage to nearby civilian facilities and civilians other than the target. It has the effect of minimizing damage.

In addition, when the present invention is applied to aerial bombs, it is possible to have various types of power with a single aerial bomb, which is useful when narrowing the damage radius and hitting only a specific part.

Figure 1 is a diagram illustrating a warhead including a fuse structure capable of adjusting warhead power according to the present invention.
Figure 2 is a perspective view illustrating the main fuse part in one embodiment of the fuse structure capable of adjusting warhead power according to the present invention.
Figure 3 is a plan view illustrating the main fuse part in one embodiment of the fuse structure capable of adjusting warhead power according to the present invention.
Figure 4 is a perspective view illustrating an auxiliary fuse unit in one embodiment of the fuse structure capable of adjusting warhead power according to the present invention.
Figure 5 is a plan view illustrating an auxiliary fuse unit in an embodiment of the fuse structure capable of adjusting warhead power according to the present invention.
Figure 6 is a flow chart illustrating a method for detonating a warhead according to the present invention.

The present invention will be described in more detail.

A preferred embodiment of the present invention will be described in detail with the accompanying drawings as follows. Prior to the detailed description of the present invention, the terms or words used in the specification and claims described below should not be construed as limited to their ordinary or dictionary meanings. Accordingly, the embodiments described in this specification and the configurations shown in the drawings are only one of the most preferred embodiments of the present invention and do not represent the entire technical idea of the present invention, so at the time of filing the present application, various options that can replace them are available. It should be understood that equivalents and variations may exist.

Figure 1 is a diagram illustrating a warhead 1 including a fuse structure capable of adjusting warhead power according to the present invention, and Figure 2 shows the main fuse part (1) in one embodiment of the fuse structure capable of adjusting warhead power according to the present invention. 200), and Figure 3 is a plan view illustrating the main fuse unit 200 in one embodiment of the fuse structure capable of adjusting warhead power according to the present invention.

In addition, Figure 4 is a perspective view illustrating the auxiliary fuse unit 100 in an embodiment of the fuse structure capable of adjusting warhead power according to the present invention, and Figure 5 is an embodiment of the fuse structure capable of adjusting warhead power according to the present invention. This is a plan view illustrating the auxiliary fuse unit 100 in the example.

With reference to FIGS. 1 to 5 , a fuse structure capable of adjusting warhead power according to the present invention and a warhead including the same with adjustable warhead power will be described in detail.

The warhead capable of adjusting the power of the warhead according to the present invention includes a warhead body 10 filled with gunpowder for explosion, and detonates the gunpowder in the warhead body 10, and adjusts the amount of gunpowder to be detonated. (1) includes a fuse structure capable of adjusting the power of the warhead according to the present invention.

One embodiment of the fuse structure capable of controlling warhead power according to the present invention includes an auxiliary fuse unit 100 that combusts or detonates part of the entire gunpowder 20 in the warhead 1, and the entire gunpowder in the warhead 1. It includes a main fuse unit (200) that explodes the remaining part of (20).

That is, one embodiment of the fuse structure capable of adjusting warhead power according to the present invention is mounted on the warhead body 10 and includes an auxiliary fuse 100 and a warhead body that burn or detonate a portion of the entire gunpowder 20. It is characterized by including a main fuse unit (200) that explodes the remaining portion of the entire gunpowder (20) in the unit (10).

The fuse structure capable of adjusting warhead power according to the present invention connects the main fuse unit 200 and the auxiliary fuse unit 100 and transmits a detonation signal to the auxiliary fuse unit 100 or a signal when the auxiliary fuse unit 100 is detonated. It further includes a cable unit 300 that transmits to the main fuse unit 200.

The cable unit 300 connects the main fuse unit 200 and the auxiliary fuse unit 100 and transmits a detonation signal to the auxiliary fuse unit 100 when a preset condition is satisfied through the main fuse unit 200. As an example, the fuse unit 100 can be detonated, and when the auxiliary fuse unit 100 is detonated according to preset conditions, the detonation signal of the auxiliary fuse unit 100 is transmitted to the main fuse unit 200. Please note that it can be used as .

That is, the auxiliary fuse unit 100 may be detonated by receiving a detonation signal from the main fuse unit 200, or may be detonated on its own under preset conditions. However, in the present invention, the auxiliary fuse unit 100 may be detonated by receiving a detonation signal from the main fuse unit 200. As an example, it is delivered and detonated.

In addition, the fuse structure capable of adjusting warhead power according to the present invention includes a power supply unit 400 that is connected to the cable unit 300 and supplies power to the main fuse unit 200 and the auxiliary fuse unit 100 through the cable unit 300. It further includes.

The cable unit 300 includes a first cable member 310 connecting the power unit 400 and the auxiliary fuse unit 100, and a second cable member 320 connecting the power unit 400 and the main fuse unit 200. Includes.

The auxiliary fuse unit 100 is connected to the power source unit 400 through the first cable member 310 and receives power from the power unit 400, and the main fuse unit 200 is connected to the power unit 400 through the second cable member 320. ) is connected to the power supply unit 400, and the auxiliary fuse unit 100 and the main fuse unit 200 are connected to the first cable member 310 and the second cable member 320 through the power supply unit 400. The signal lines can be connected to each other to transmit a detonation signal.

As an example, the power unit 400 is a generator that generates power by wind power received when the warhead 1 falls or flies, and can be implemented by various modifications to known generators used in the warhead 1. Please note that detailed explanations are omitted.

In addition, the main fuse unit 200 and the auxiliary fuse unit 100 are each equipped with a full-explosive charge for detonating the gunpowder in the warhead body 10, and the full-explosive charge of the main fuse unit 200 is provided by the auxiliary fuse unit. It is possible to detonate a larger amount of gunpowder than the amount of gunpowder detonated by the detonation of the auxiliary fuse unit 100, which is larger than the full explosive amount of (100), and thus partially detonates or burns some of the gunpowder in advance with the auxiliary fuse unit 100. Afterwards, the remaining gunpowder is detonated through the main fuse unit 200 to control the explosive power of the warhead (1).

The fuse structure capable of adjusting warhead power according to the present invention can use 100% of the power of the warhead (1) by detonating all the gunpowder (20) of the warhead (1) at once with the main fuse unit (200), and can use 100% of the power of the warhead (1). ), when the power of the warhead (1) is used at 100%, the auxiliary fuse unit (100) does not operate and only the main fuse unit (200) must operate, so the auxiliary fuse unit (200) operates according to the setting for the power of the warhead (1). It is desirable to operate the fuse unit 100 by applying a detonation signal.

The auxiliary fuse unit 100 detonates only a portion of the entire gunpowder 20 of the warhead 1, that is, the entire explosive amount is provided inside so as to have the minimum amount of detonation capable of igniting the gunpowder among the entire gunpowder 20. , the main fuse unit 200 is provided with a full amount of explosive charge capable of detonating the entire gunpowder 20 of the warhead 1.

As an example, the auxiliary fuse unit 100 is provided with a full explosive amount capable of detonating less than 10% of the total gunpowder 20, and in this case, the fuse structure capable of adjusting warhead power according to the present invention is a warhead (1 ), except that the explosion power is generated at 100%, the explosion power can be adjusted from 0 to 90%.

The auxiliary fuse unit 100 is provided with a minimum amount of total explosive power capable of igniting the gunpowder and burning the gunpowder without exploding the warhead 1, and this varies depending on the type of gunpowder and the type of warhead 1. It can be implemented.

The auxiliary fuse unit 100 detonates only a portion of the entire gunpowder 20 of the warhead to the extent that the warhead body 10 does not explode, and the fuse structure capable of adjusting warhead power according to the present invention detonates a portion of the entire gunpowder 20. The gunpowder is detonated by the auxiliary fuse unit 100 and is ultimately detonated in the main fuse unit 200 by controlling the combustion amount of the gunpowder by delaying the detonation time of the main fuse unit 200 after combustion of the gunpowder begins. By adjusting the amount, the explosion power of the warhead (1) can be adjusted.

The main fuse unit 200 controls the power of the warhead 1 by delaying the detonation time of the main fuse after the auxiliary fuse 100 is detonated or after applying a detonation signal to the auxiliary fuse 100. Includes an adjusting unit 220.

The warhead power control unit 220 includes an explosion power selection switch unit 221 that can select the explosion power of the warhead 1, and after the auxiliary fuse unit 100 is detonated according to the selected explosion power, the main fuse unit The explosion power of the warhead (1) is adjusted by adjusting the detonation delay time of (200).

The warhead power control unit 220 is linked with the guidance kit or guidance control device in addition to the switch unit 221 for selecting the explosion power to select the power of the warhead, and after the auxiliary fuse unit 100 is detonated according to the selected explosion power. The explosion power of the warhead (1) is adjusted by adjusting the detonation delay time of the main fuse unit (200).

In addition, the warhead power control unit 220 has a pre-stored detonation delay time of the main fuse unit 200 after the auxiliary fuse unit 100 is detonated in accordance with the explosion power of the warhead 1, and is used to select the explosion power. When the explosion power of the corresponding warhead (1) is selected with the switch unit (221), the main fuse unit (200) is detonated after a delay time corresponding to the explosion power after detonation of the auxiliary fuse unit (100), resulting in the explosion of the warhead (1). Adjust the power.

The fuse structure capable of controlling warhead power according to the present invention does not explode the warhead (1) when the auxiliary fuse unit (100) is detonated, reduces the amount of gunpowder in the warhead (1), and after the auxiliary fuse unit (100) is detonated, The detonation time of the main fuse unit 200 is delayed according to the explosion power of the warhead 1 selected in the explosion power selection switch unit 221, and as the detonation time of the main fuse unit 200 is delayed, the detonation time of the warhead 1 is delayed. As the gunpowder burns and gradually decreases, the main fuse unit 200 is detonated when the preset amount of gunpowder is reached, and the warhead 1 may be exploded by the explosion power of the warhead 1 selected in the explosion power selection switch unit 221. .

The main fuse unit 200 is provided with a first fuse body 210 equipped with a main full-explosive charge inside, a main fuse (not shown) that detonates the main full-explosive charge, and a warhead ( It includes a warhead power control unit 220 that controls the detonation of 1) and adjusts the explosion power of the warhead 1.

The main fuse (not shown) is not shown, but it can be implemented as a known mechanical or electronic fuse that can detonate the main explosive charge in a loaded state, so a more detailed description is omitted.

In addition, the warhead power control unit 220 applies a detonation signal to the auxiliary fuse unit 100 or the main fuse under preset conditions so that the auxiliary fuse unit 100 or the main fuse unit 200 can be detonated.

As an example, the warhead power control unit 220 applies a detonation signal when the warhead 1 collides with the target and receives an impact greater than a preset, and applies a detonation signal when the warhead 1 receives an impact greater than a preset. Since the applying structure is a known structure, further detailed description will be omitted. In addition, the known structure for applying the detonation signal from a known fuse can be modified and implemented in various ways.

The warhead power control unit 220 is a detonation signal application delay switch unit that sets the delay time for applying the detonation signal to the auxiliary fuse unit 100, that is, the delay time for applying the first detonation signal after the preset detonation conditions are confirmed. It further includes (222).

For example, the switch unit 222 for delaying detonation signal application immediately applies a detonation signal to the auxiliary fuse unit 100 when the warhead 1 collides with the target and receives an impact exceeding a preset value. It is possible to delay application of the detonation signal to the auxiliary fuse unit 100 for a set delay time without detonating it.

In addition, the main fuse unit 200 includes a first main loading locking unit (not shown) that locks the loading of the fuse and unlocks it under a preset first condition, and a first main loading locking unit that locks the loading of the fuse and unlocks it under a preset first condition. It includes a second main loading lock (not shown) that unlocks under a preset second condition after being released.

In addition, the main fuse unit 200 is a first loading device that sets the delay time for unlocking the second main loading lock after the warhead 1 is launched or dropped from an aircraft, that is, the unloading time of the second main loading lock. It further includes a switch unit 230 for time setting.

The switch unit 230 for setting the first loading time maintains the locked state of the second main loading lock for a preset time after the warhead 1 is launched from the launch device or dropped from the aircraft, so that the warhead 1 is released from the launch device or It allows the final loading of the fuse to be carried out at a distance greater than a preset distance from the aircraft, thereby preventing an accident in which the warhead (1) explodes at close range to the launcher or aircraft.

The first main loading lock has a structure in which the lock is released after the warhead 1 is launched or dropped when the preset acceleration condition, that is, the acceleration of the warhead 1 reaches the preset acceleration, which is known in the general fuse structure. It should be noted that a more detailed explanation is omitted due to the locking structure.

That is, the first condition for unlocking the first main loading lock is a preset acceleration condition after the warhead 1 is launched or dropped, that is, when the acceleration of the warhead 1 reaches the preset acceleration, and the second condition is The second condition for unlocking the main loading lock is when the warhead (1) falls beyond a preset distance from the launching device or aircraft after the warhead (1) is launched from the launch device or dropped from the aircraft, which is the case when the first loading lock is released. It can be set to the switch unit 230 for time setting.

In addition, the main fuse unit 200 further includes a first safety pin structure 240 capable of locking and unlocking the first main loading lock, so that the first safety pin structure 240 is removed from the first safety pin structure 240 before launch of the warhead 1. 1 Safety pin is separated to activate the first main loading lock. After the warhead (1) is launched, the first main loading lock and the second main loading lock are sequentially unlocked so that the fuze can be loaded.

The first safety pin structure 240 locks the first main loading lock to completely prevent an accident in which the first main loading lock is unlocked due to external conditions when the warhead 1 is transported or stored and the fuse is loaded. can do.

The first main loading locking unit, the second main loading locking unit, the first loading time setting switch unit 230, and the first safety pin structure 240 are variously modified from the fuse structure of the general warhead 1 to a known structure. Since it can be implemented, a more detailed description will be omitted.

The auxiliary fuse unit 100 is a second fuse body 110 equipped with an auxiliary full-explosive charge inside, an auxiliary fuse (not shown) that is provided in the second fuse body 110 and detonates the auxiliary full-explosive charge, and a fuse. A first auxiliary loading lock (not shown) that locks the loading and unlocks it under a preset first condition, locks the loading of the fuse, and after the first auxiliary loading lock (not shown) is released, a preset condition is set. The second auxiliary loading lock (not shown), which unlocks under two conditions, the loading release time of the second auxiliary loading lock (not shown), that is, the second auxiliary loading after the warhead (1) is launched or dropped from the aircraft. It further includes a second loading time setting switch unit 120 that sets a delay time for unlocking the locking unit (not shown).

The auxiliary fuse (not shown) is not shown, but it can be implemented as a known mechanical or electronic fuse that can detonate the auxiliary explosive charge in a loaded state, so a more detailed description is omitted.

The switch unit 120 for setting the second loading time maintains the locked state of the second auxiliary loading lock for a preset time after the warhead 1 is launched from the launch device or dropped from the aircraft, so that the warhead 1 is released from the launch device or It allows the final loading of the fuse to be carried out at a distance greater than a preset distance from the aircraft, thereby preventing an accident in which the warhead (1) explodes at close range to the launcher or aircraft.

The first auxiliary loading lock has a structure in which the lock is released after the warhead 1 is launched or dropped when the preset acceleration condition, that is, the acceleration of the warhead 1 reaches the preset acceleration, which is known in the general fuse structure. It should be noted that a more detailed explanation is omitted due to the locking structure.

That is, the first condition for unlocking the first auxiliary loading lock is a preset acceleration condition after the warhead 1 is launched or dropped, that is, when the acceleration of the warhead 1 reaches the preset acceleration, and the second condition is The second condition for unlocking the auxiliary loading lock is when the warhead (1) falls beyond a preset distance from the launching device or aircraft after the warhead (1) is launched from the launch device or dropped from the aircraft, which is the case when the first loading lock is released. It can be set to the time setting switch unit 230.

In addition, the auxiliary fuse unit 100 further includes a second safety pin structure 130 capable of locking and unlocking the first auxiliary loading lock, and is 2. Separate the safety pin to activate the first auxiliary loading lock. After the warhead (1) is launched, the first auxiliary loading lock and the second auxiliary loading lock are sequentially unlocked so that the fuze can be loaded.

The second safety pin structure 130 locks the first auxiliary loading lock to completely prevent an accident in which the first auxiliary loading lock is unlocked due to external conditions when the warhead 1 is transported or stored and the fuse is loaded. can do.

The first auxiliary loading lock, the second auxiliary loading lock, the second loading time setting switch unit 120, and the second safety pin structure 130 can be variously modified from the fuse structure of a general warhead to a known structure. A more detailed explanation will be omitted if possible.

Meanwhile, Figure 6 is a flowchart illustrating a method for detonating a warhead according to the present invention. Referring to Figures 1 and 6, one embodiment of the method for detonating a warhead according to the present invention involves the entire gunpowder (20) in the warhead (1). ) Detonation of a warhead equipped with a fuse structure including an auxiliary fuse unit (100) that burns or detonates some of the gunpowder (100) and a main fuse unit (200) that explodes the remaining part of the entire gunpowder (20) in the warhead (1) This is a method, an explosion power setting step (S100) of setting the explosion power of the warhead (1) before the warhead (1) is launched from a launcher or dropped from an aircraft, and an explosion power setting step (S100) in which the warhead (1) is launched from a launcher or dropped from an aircraft. Warhead launch step (S200), after the warhead launch step (S200), a fuse loading step (S300) in which the auxiliary fuse unit 100 and the main fuse unit 200 are loaded under preset conditions, respectively, and a warhead loading step (S300). Under the explosion conditions of (1), the explosion signal application step (S400), after the explosion signal application step (S400), the auxiliary fuse unit 100 is selectively operated, and finally the main fuse unit 200 is operated. It includes a warhead explosion step (S500) in which the warhead 1 is exploded with the explosion power set in the explosion power setting step (S100).

In the explosion power setting step (S100), the explosion power is selected and set by manipulating the explosion power selection switch unit 221 provided in the main fuse unit 200, or the explosion power is selected in conjunction with the guidance kit or guidance control device. You can.

The fuse loading step (S300) is a first loading process (S310) of releasing the first loading lock state of the auxiliary fuse unit 100 and the main fuse unit 200 under a preset first condition, It includes a second loading process (S320) in which the second loading lock state of the auxiliary fuse unit 100 and the main fuse unit 200 is released under two conditions.

The first condition is a preset acceleration condition after the warhead 1 is launched or dropped, that is, when the acceleration of the warhead 1 reaches the preset acceleration, and the second condition is when the warhead 1 is launched from the launcher or This occurs when the warhead (1) falls beyond a preset distance from the launcher or aircraft after being dropped from the aircraft.

The second condition is that the preset time is delayed after the warhead 1 is launched from the launcher or dropped from the aircraft, and this is due to the switch unit 230 for setting the first loading time provided in the main fuse unit 200 and the auxiliary fuse unit. It can be set with the second loading time setting switch unit 120 provided in the unit 100.

In the fuse loading step (S300), after the warhead (1) is launched from the launch device or dropped from the aircraft, the auxiliary fuse unit (100) and the main fuse unit are separated from the launch device or aircraft by more than a preset distance. (200) is loaded to prevent an accident where the warhead (1) explodes at close range to the launcher or aircraft.

It should be noted that the fuse loading step (S300) can be carried out by various modifications from the known fuse structure of the warhead 1 using a known loading structure and loading method, so a more detailed description will be omitted.

In addition, the explosion signal application step (S400) is an example of applying a detonation signal when the warhead 1 collides with the target and receives an impact greater than a preset, and the warhead 1 detonates when it receives an impact greater than the preset. Since the structure for applying the signal is a known structure, further detailed description will be omitted. In addition, the known structure for applying the detonation signal from a known fuse can be modified and implemented in various ways.

The warhead explosion step (S500) is the entire explosion process (S510) in which only the main fuse unit (200) is activated to explode the warhead (1) when the explosion power of the warhead (1) is set to 100% in the explosion power setting step (S100). And in the explosion power setting step (S100), if the explosion power of the warhead (1) is more than 0% and less than 100%, the auxiliary fuse unit (100) is activated, and after a preset delay time after the operation of the auxiliary fuse unit (100), the main fuse is activated. It includes a partial explosion process (S520) in which the warhead 1 is exploded with a preset explosion power by operating the unit 200.

The detonation delay time of the main fuse 200 is pre-stored according to the explosion power of the warhead 1, and the partial explosion process (S520) is performed in the explosion power setting step (S100) after the auxiliary fuse 100 is detonated. After the detonation delay time corresponding to the set explosion power, the main fuse unit 200 is detonated to adjust the explosion power of the warhead (1).

The partial explosion process (S520) does not explode the warhead (1) after detonation of the auxiliary fuse 100, but reduces the amount of gunpowder during the preset detonation delay time as the gunpowder in the warhead (1) is burned, and the entire gunpowder (20) When there is enough gunpowder remaining for the preset explosion power, the main fuse 200 is detonated, detonating the entire remaining gunpowder and exploding the warhead 1.

For example, in the partial explosion process (S520), when the preset explosion power is 60% of the total explosion power, when 60% of the total gunpowder (20) in the warhead (1) remains, the main fuse unit (200) is operated to explode the remaining gunpowder. Detonates the entire vehicle and explodes the warhead (1).

The delay time during which the gunpowder is burned after detonation of the auxiliary fuse 100 and the amount of gunpowder remaining according to the explosion power can be modified in various ways depending on the type of gunpowder and the type of warhead 1, and this can be performed through data through testing. The explosion power selected after detonation of the auxiliary fuse unit 100 using the detonation delay time data of the main fuse unit 200, which is pre-stored and pre-stored to match the explosion power of the warhead 1 in the partial explosion process (S520) After the pre-stored delay time, the main fuse unit 200 is detonated to control the explosion power of the warhead (1).

The present invention adjusts the amount of gunpowder detonated within the warhead (1) by burning within the warhead (1) with the auxiliary fuse unit (100), and then explodes the warhead with the main fuse unit (200) to adjust the power of the warhead according to the combat situation. It can be adjusted to minimize damage to nearby civilian facilities and civilians other than the target.

In addition, when the present invention is applied to aerial bombs, it is possible to have various types of power with a single aerial bomb, which can be useful when narrowing the damage radius and hitting only a specific part.

The present invention is not limited to the above-described embodiments, and may be implemented with various changes without departing from the gist of the present invention, and these are included in the scope of the present invention.

1: warhead 10: warhead body
20: Total gunpowder 100: Auxiliary fuse part
110: Second fuse body portion 120: Second loading time setting switch portion
130: Second safety pin structure 200: Main fuse part
210: First fuze body 220: Warhead power control unit
221: Switch unit for selecting explosion power 222: Switch unit for delaying detonation signal application
230: First loading time setting switch unit 240: First safety pin structure
300: Cable part 310: First cable member
320: second cable member 400: power unit
S100: Explosion power setting step S200: Warhead launching step
S300: Fuse loading step S310: First loading process
S320: Second loading process S400: Explosion signal application step
S500: Warhead explosion stage S510: Entire explosion process
S520: Partial explosion process

Claims (14)

An auxiliary fuse unit that burns or explodes a portion of the total amount of gunpowder in the warhead; and
A fuse structure capable of controlling warhead power, comprising a main fuse unit that explodes the remaining portion of the total amount of gunpowder in the warhead.
In claim 1,
A fuse structure capable of adjusting warhead power, further comprising a cable part connecting the main fuse unit and the auxiliary fuse unit and transmitting a detonation signal to the auxiliary fuse unit or transmitting a signal detonated by the auxiliary fuse unit to the main fuse unit. .
In claim 2,
A fuse structure capable of adjusting warhead power, further comprising a power supply unit connected to the cable unit and supplying power to the main fuse unit and the auxiliary fuse unit through the cable unit.
In claim 1,
The auxiliary fuse is provided with a full amount of explosive charge inside so as to have a minimum amount of detonation capable of igniting the gunpowder among all the gunpowder,
A fuse structure capable of adjusting warhead power, characterized in that the main fuse is provided inside a full amount of explosive charge capable of detonating the entire gunpowder.
In claim 1,
A fuse structure capable of controlling warhead power, wherein the main fuse unit includes a warhead power control unit that controls the power of the warhead by delaying the detonation time of the main fuse after applying a detonation signal to the auxiliary fuse unit.
In claim 5,
The warhead power control unit includes an explosion power selection switch unit that can select the explosion power of the warhead, and after the auxiliary fuse unit is detonated according to the selected explosion power, the detonation delay time of the main fuse unit is pre-stored to select the explosion power. A fuse structure capable of controlling warhead power, characterized in that the main fuse unit can be detonated after a preset detonation delay time after the auxiliary fuse unit is detonated according to the explosion power selected by the switch unit.
In claim 5,
The warhead power control unit can select the power of the warhead in conjunction with the guidance kit or the guidance control device, and after the auxiliary fuse unit is detonated according to the selected explosion power, the detonation delay time of the main fuse unit is pre-stored and the guidance kit or the above A fuse structure capable of controlling warhead power, characterized in that the main fuse unit can be detonated after a preset detonation delay time after the auxiliary fuse unit is detonated according to the explosion power selected by the guidance control device.
In claim 6,
The warhead power control unit further includes a detonation signal application delay switch unit that sets a delay time for applying an initial detonation signal to the auxiliary fuse unit after a preset detonation condition is confirmed. A fuse structure capable of controlling warhead power, characterized in that.
In claim 1,
a cable unit connecting the main fuse unit and the auxiliary fuse unit and transmitting a detonation signal from the main fuse unit to the auxiliary fuse unit; and
It further includes a power supply unit connected to the cable unit and supplying power to the main fuse unit and the auxiliary fuse unit through the cable unit,
The auxiliary fuse is provided with a full amount of explosive charge inside so as to have a minimum amount of detonation capable of igniting the gunpowder among all the gunpowder,
The main fuse is equipped with a total amount of explosive charge capable of detonating the entire gunpowder of the warhead,
The main fuse unit includes a warhead power control unit that controls the power of the warhead by delaying the detonation time of the main fuse after applying a detonation signal to the auxiliary fuse unit,
The warhead power control unit includes an explosion power selection switch unit that can select the explosion power of the warhead, and adjusts the explosion power of the warhead by adjusting the detonation delay time of the main fuse unit after the auxiliary fuse unit is detonated according to the selected explosion power. A fuse structure capable of controlling warhead power, characterized in that:
A warhead body filled with gunpowder for explosion inside; and
It includes a fuse mounted on the warhead body to explode the warhead,
A warhead with adjustable warhead power, characterized in that the fuse is a fuse structure capable of adjusting the warhead power of any one of claims 1 to 9.
It is a method of detonating a warhead equipped with a fuse structure that includes an auxiliary fuse unit that burns or detonates part of the total amount of gunpowder in the warhead and a main fuse part that explodes the remaining part of the total amount of gunpowder in the warhead,
An explosion power setting step of setting the explosion power of the warhead before the warhead is launched from a launcher or dropped from an aircraft;
A warhead launching step in which the warhead is launched from a launcher or dropped from an aircraft;
A fuse loading step of loading the auxiliary fuse unit and the main fuse unit under preset conditions, respectively, after the warhead firing step;
An explosion signal application step of applying an explosion signal under the explosion conditions of the warhead after the fuse loading step; and
Detonation of the warhead, comprising a warhead explosion step of selectively operating the auxiliary fuse unit after the explosion signal application step and finally operating the main fuse unit to explode the warhead with the explosion power set in the explosion power setting step. method.
In claim 11,
The warhead explosion step is,
If the explosion power of the warhead is set to 100% in the explosion power setting step, the entire explosion process of detonating the warhead by operating only the main fuse unit; and
In the explosion power setting step, if the explosion power of the warhead is greater than 0% and less than 100%, the auxiliary fuse unit is activated, and after a preset delay time after the operation of the auxiliary fuse unit, the main fuse unit is activated to explode the warhead with the preset explosion power. A method of detonating a warhead comprising a partial explosion process.
In claim 12,
The detonation delay time of the main fuse is pre-stored according to the explosion power of the warhead, and the partial explosion process is performed by detonating the main fuse after a detonation delay time corresponding to the explosion power set in the explosion power setting step after the auxiliary fuse is detonated. A method of detonating a warhead, characterized in that it detonates.
In claim 13,
The partial explosion process does not explode the warhead after detonation of the auxiliary fuse, but reduces the amount of gunpowder during a preset detonation delay time as the gunpowder in the warhead is burned, and when the amount of gunpowder suitable for the preset explosion power remains among the total amount of gunpowder, the main A method of detonating a warhead, characterized in that the warhead is exploded while detonating the entire amount of gunpowder remaining as the fuse is detonated.

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