KR20080054673A - Hand grenade - Google Patents

Abstract

A hand grenade is provided to prevent the hand grenade from being exploded when a distance between the hand grenade and a safety pin or a distance between the hand grenade and a terminal is not ensured. Safety pins(21) are inserted into a striker lever. An exploder assembly includes a striker course preventing part and a receiving module. The receiving module receives a signal. The safety pin includes an insertion pin(23) provided at one of a ring(22). A switch(24) is formed at one inner side of the ring. The ring includes a transmission module(25). The insertion pin is thick so that the insertion pin is pulled out only when a predetermined force is exerted. The ring has a length(W2) larger than a width(W1). The transmission module includes a battery and generates a radio signal having a specific frequency.

Description

Grenade {Hand grenade}

1 and 2 is a cross-sectional view showing a conventional grenade.

3 is a view for explaining a grenade according to an embodiment of the present invention.

4 and 5 are exemplary views showing the configuration of the safety pin in the grenade according to an embodiment of the present invention.

Figure 6 is a detailed view showing a striker path obstruction in the grenade according to an embodiment of the present invention.

7 and 8 are cross-sectional view illustrating the state before and after the operation of the grenade according to an embodiment of the present invention.

9 is an exemplary view showing an embodiment of throwing a grenade according to an embodiment of the present invention.

(Explanation of symbols for the main parts of the drawing)

1: grenade 2: safety clip

3: safety pin 4: striker lever

5: lever jaw 6: grenades shell

7: primer assembly 8: peony

9: striker 10: striker jaw

11: striker flange 12: sharpened

13: striker spring 14: primer

15: Primer Fixing Cap 16: Fuse

17: detonation

20: Grenade 21, 21a: Safety pin

22: ring 23: insertion pin

24: switch 25: transmission module

26: pressure pin 27: push spring

28: first contact point 29: second contact point

30: primer assembly 31: first switch

32, 33: contact 34: expansion tube

35: primer fixing cap 36: cap flange

50: receiving module 51: battery unit

52: circuit part 53: partition wall

60: striker path obstruction 61: hole

62: ball 63: plunger

64: internal slope 65: coil

66: groove 67: plunger spring

70: terminal 100: throwing area

110: semi-hazardous area 120: hazardous area

L1: Distance between the grenade and the safety pin

L2: distance between the grenade and the handset

The present invention relates to grenades, and more particularly, to grenades to explode when a safe distance from the throwing area is secured.

The conventional grenade 1 will be described with reference to the accompanying drawings, FIGS. 1 and 2.

The grenade 1 is equipped with a primer assembly 7 inside the grenade shell 6, and the peony 8 is filled with the outer circumference of the primer assembly 7.

The primer assembly 7 described above is mounted in the tubular body 7a such that the striker 9 is shot by the striker spring 13.

The peony 8 described above opens and closes the plug 8a formed on one side of the grenade shell 6.

The striker 9 has a striker jaw 10 formed at an upper end thereof, a striker flange 11 formed at a lower end thereof, and a striker spring 13 compressed between the striker flange 11 and an upper inner surface of the tubular body 7a. It is mounted in a state.

In addition, the striker jaw 10 of the striker 9 is caught by the lever jaw 5 of the striker lever 4.

In addition, a sharp portion 12 is formed at the lower end of the above-described striker 9.

The striker lever 4 is fixed by the safety clip 2 and the safety pin 3, and the striker lever 4 is easily detached from the grenade in the state where the safety clip 2 and the safety pin 3 are removed.

The safety clip 2 described above is a safety device for fixing the striker lever 4 to the body of the grenade so as not to be separated arbitrarily.

The safety pin 3 is a safety device that is physically fixed by being inserted so that the striker lever 4 is not peeled off.

A primer 14 is fixed to the lower end of the primer assembly 7 by a primer fixing cap 15, and a detonator 17 is disposed on one side of the tube 7a, and a primer 14 and a detonator 17. Is connected to the fuse 16.

The above-described conventional grenade 1 is used as follows.

The thrower removes the safety clip 2 while holding the body of the striker lever 4 and the grenade 1 at the same time, removes the safety pin 3 and then throws it.

At the moment when the grenade 1 is thrown, the striker 9 is lowered by the repulsive force of the striker spring 13 and the striker lever 4 is thrown off and separated.

The striker 9 then passes through the tubular body 7a to exert a predetermined impact pressure on the primer 14.

Primer 14 is shocked by the sharp portion 12 of the striker 9 is ignited due to the energy caused by the impact.

Afterwards, the fuse 16 gradually burns for about 3 to 5 seconds and eventually causes the detonation agent 17 to explode.

The detonator 17 explodes the peony 8 and the grenade shell 6 made of metal is damaged and scattered and killed by the explosion of the peony 8.

However, the following problems have been pointed out in the conventional grenade 1.

Soldiers are trained to throw grenades, and if thrown incorrectly, there is a risk that it can lead to an injustice disaster.

In particular, the most common mistake in throwing grenades is when the thrower misses his hand rather than throwing it away.

In this case, the safety clip (2), the safety pin (3) and the striker lever (4) is removed from the grenades (1), the grenades (1) is inevitably lead to a large disaster when located close to the thrower.

Also, when the thrower misses a grenade and drops it around, there is practically no time to deal with the dangerous situation after knowing that the missile has missed.

In other words, not only the thrower, but also fellow soldiers and assistants overseeing the training, causing numerous casualties.

On the other hand, mock grenade was developed and distributed for training purposes. However, the grenade had a different weight from the actual grenade and the feeling felt in the hand, so the problem of struggling when throwing a real grenade was pointed out.

In addition, there was a problem that requires a lot of cost and time in order to make a separate grenade.

On the other hand, some unfortunate incidents have been reported in the media, such as attempting suicide with grenades in unforeseen circumstances, or deliberately destroying grenades for malicious purposes.

Therefore, the technical problem to be achieved by the present invention is to ensure safety and protect human life by preventing the grenade from bursting even if the distance between the thrower and the grenade is not secured even if the safety clip, the safety pin and the striker lever are removed from the grenade. The purpose is to provide.

Another object of the present invention is to perform a military training with a real grenade to learn the sense of actual grenade throwing.

Technical problems to be achieved by the present invention are not limited to the above-mentioned technical problems, and other technical problems not mentioned above will be clearly understood by those skilled in the art from the following description. Could be.

Grenade according to an embodiment of the present invention for achieving the above technical problem, the striker is carried out by the striker spring; A striker lever for holding the striker; A safety pin to secure the striker lever not to be separated; A primer ignited by the striker; A fuse burned by the primer for a predetermined time; An explosive agent exploded by the fuse; Peony exploded by the detonator; A primer assembly to which the striker and the primer are mounted; And a grenade shell that bounces into debris due to the explosion of the peony, the grenade comprising: a safety pin for generating a specific frequency radio signal when drawn from the grenade; A striker path blocker physically obstructing the striker; And a receiving module configured to receive the specific frequency radio signal generated by the safety pin and to advance the striker at the striker path obstruction unit when the specific frequency radio signal is not received.

The apparatus may further include a first switch disposed at an inner diameter of the primer assembly to sense the progress of the striker and to operate the receiving module at the moment the striker progresses.

The terminal may further include a terminal generating a specific frequency radio signal identical to the specific frequency radio signal, and the terminal and the grenade form a suit.

In addition, the safety pin, a ring; An insertion pin disposed on one side of the ring and inserted into a grenade; A transmission module formed at the other side of the ring and mounted with a battery and generating a specific frequency radio signal; And a switch disposed inside the ring to receive the pressure when the ring is pulled to operate the transmission module.

In addition, the ring may have a different width and length, and the switch may be disposed on an inner surface of the longer side of the ring.

Also, rings; An insertion pin disposed on one side of the ring and inserted into a grenade; A pressure pin disposed in a direction parallel to the longitudinal direction of the insertion pin and being elastically mounted by a push spring; A first contact disposed on one side of the pressure pin; A second contact disposed at a position spaced apart from the first contact; And a transmission module disposed at the other side of the ring, mounted with a battery, and configured to generate the specific frequency radio signal by energizing the first contact point and the second contact point.

In addition, the striker path obstruction unit, a hole formed in the inner diameter of the primer assembly; A ball inserted into the hole and partially protruding into the inner diameter of the primer assembly to physically hinder the progress of the striker; A plunger mounted on an outer circumference of the primer assembly and made of a metal material moved by a magnetic field, and pushing the ball to protrude into the inner diameter of the primer assembly; A plunger spring disposed under the plunger and pushing the plunger to maintain a state in which the plunger is always moved upward; And a coil disposed on an outer circumference of the plunger to generate a magnetic field.

In addition, the hole and the ball may be a plurality of.

The receiving module may include a battery unit for supplying power and a circuit unit for receiving and calculating the specific frequency radio signal.

In addition, a partition wall disposed on one side of the circuit unit to prevent the circuit unit and the battery unit physically movement; may be further included.

Specific details of other embodiments are included in the detailed description and the drawings.

Advantages and features of the present invention and methods for achieving them will be apparent with reference to the embodiments described below in detail with the accompanying drawings.

Throughout the specification, the same reference numerals refer to the same components, the same reference numerals are assigned to the same components as in the prior art, and description thereof will be omitted.

Hereinafter, a grenade according to an embodiment of the present invention will be described with reference to FIGS. 3 to 8.

3 is a view for explaining a grenade according to an embodiment of the present invention.

As shown in FIG. 3, the grenade 20 according to the embodiment of the present invention has the safety pins 21 and 21a fitted into the striker lever 4, and the striker path obstruction portion 60 to the primer assembly 30. And a receiving module 50 for receiving a signal.

The safety pin 21 described above will be described with reference to FIG. 4.

Safety pin 21 has an insertion pin 23 is formed on one side of the ring 22, the switch 24 is formed on one side of the inner surface of the ring 22, the transmission module 25 is mounted.

The above-described insertion pin 23 is formed to have a thick end portion when the safety pin 21 is pulled out from the grenade 20 to be removed only by applying a predetermined force.

The above-described ring 22 is formed to have a length (W2) longer than the width (W1) is formed in an elliptic shape or a rounded square shape to put a finger on the ring 22, so that pressure is naturally applied to the switch 24 do.

The above-described transmission module 25 includes a battery and generates a radio signal of a specific frequency.

Generating a specific frequency radio signal in the transmission module 25 uses a known technique, and a detailed description thereof will be omitted.

The switch 24 operates the transmission module 25 when a predetermined pressure is applied to generate a radio signal of a specific frequency.

As another example of the above-described safety pin (21a) will be described with reference to the accompanying drawings, FIG.

The safety pin 21a forms an insertion pin 23 on one side of the ring 22 and installs the pressure pin 26 by the push spring 27 in a direction parallel to the length direction of the insertion pin 23. The other end of the ring 22 is mounted with a transmission module 25.

The first contact 28 is integrally formed on one side of the pressure pin 26 described above, the second contact 29 is formed at a position spaced apart from the first contact 28, and the pressure pin 26 moves. The first contact 28 and the second contact 29 are energized or short-circuited to act as a switch.

When the safety pin 21a described above is inserted into the grenade 20, the pressure pin 26 is pressed against the surface of the grenade 20 and is pushed out, and the push spring 27 is compressed in a tensioned state and the first contact point. (28) and the second contact point 29 are kept spaced apart.

That is, at the moment when the safety pin 21a is pulled out from the grenade 20, the push spring 27 pushes the pressure pin 26 and the first contact 28 and the second contact 29 described above are energized.

When the first contact point 28 and the second contact point 29 are in contact with each other, the transmission module 25 is operated to generate a radio signal having a specific frequency.

The above-described receiving module 50 will be described with reference to FIGS. 7 and 8.

A predetermined space is formed at the lower end of the primer assembly 30, and the battery unit 51 and the circuit unit 52 are formed in the space.

In addition, the partition wall 53 may be further formed on the surface of the circuit unit 52.

The battery unit 51 described above may use a coin type flat battery.

The above-described circuit unit 52 serves to receive and calculate a specific frequency radio signal, and the electric circuit configuration uses a well-known technique and detailed description thereof will be omitted.

The partition wall 53 is a safety device for preventing the battery unit 51 and the circuit unit 52 from swinging or shaking when the grenade 20 is thrown out, thereby preventing the circuit unit 52 from malfunctioning.

The circuit unit 52 described above receives a specific frequency radio signal generated from the safety pins 21 and 21a.

The fatal effective kill radius of the grenade 20 is known to be around 10M, and the quasi-hazardous area that can cause fatal injury is known as a radius of about 30M.

Therefore, at least 30M distance from the grenade thrown can ensure the safety of the thrower's personality.

That is, the sensitivity received by the above-described receiving module 50 detects a specific frequency radio signal within a distance of 30M and normally receives it, and prevents detecting a specific frequency radio signal at a distance of 30M or more.

The above-mentioned 30M is just an example, and is set according to the performance of the grenade 20.

For example, if the performance of the grenade is greatly improved and the radius of the sub-hazardous area is increased to 40M, the reception sensitivity of the reception module 50 is set to 40M, and the performance of the grenade when the reception module 50 is mounted on the conventional grenade. Can be reset accordingly.

The above-mentioned striker path blocker 60 is configured to block the progress of the striker 9 and will be described in detail with reference to FIGS. 6 to 8.

A hole 61 is formed in the inner diameter of the primer assembly 30, and a ball 62 is inserted into the hole 61, and in particular, a part of the ball 62 passes through the hole 61 of the primer assembly 30. Protrudes to the inside diameter.

The above-described holes 61 may be provided in plural numbers, and in this case, the plurality of holes 61 may be formed at equal intervals at the center of the primer assembly 30.

Moreover, the 1st switch 31 is arrange | positioned above the hole 61 mentioned above (the side where a striker is initially located), and the 1st switch 31 is energized at the moment the striker 9 advances.

In addition, the above-mentioned striker 9 is mounted in a tensioned state by compressing the striker spring 13, and thus the above-described first switch 31 is disposed below the striker flange 11 with the striker 9 mounted thereon. do.

The first switch 31 described above arranges two contacts 32 and 33 and causes interference to occur when the striker flange 11 of the striker 9 proceeds, so that the two contacts 32 and 33 are energized. It was made possible.

The first switch 31 described above is electrically connected to the above-described circuit unit 52 so that the circuit unit 52 is operated from the time point at which the first switch 31 is energized.

In addition, an expansion tube 34 is formed on the outer circumference of the primer assembly 30, and a plunger 63, a plunger spring 67, and a coil 65 are disposed in the expansion tube 34.

The plunger 63 described above is made of a metallic material that can be moved in a specific direction under the influence of a magnetic field, and an inner inclined surface 64 is formed on the inner circumference of the upper end.

The inclined surface 64 described above pushes the ball 62 toward the inner diameter of the primer assembly 30 when the plunger 63 is in a raised position in contact with the ball 62 described above.

In addition, the plunger spring 67 described above is mounted as a kind of compression spring in contact with the lower end of the plunger 63 to exert a force toward the plunger 63 at all times.

In particular, the plunger spring 67 suppresses the plunger 63 from moving downward when the grenade 20 moves in any direction.

On the other hand, the plunger 63 described above forms a groove 66 at the bottom so that the plunger spring 67 is located in the groove 66 so that the plunger spring 67 does not peel off from the groove 66 and reaches the correct position. .

The above-described coil 65 generates a magnetic field to move the plunger 65 described above, and the generated magnetic field acts larger than the force of the plunger spring 67 described above.

In addition, the coil 65 described above receives power from the battery unit 51 described above.

In addition, the coil 65 described above may be coated on the inner and outer diameters of the coil 65 for insulation and protection.

In addition, the primer 14 is fixed to the interior of the primer assembly 30 by the primer fixing cap 35, the primer fixing cap 35 forms a cap flange 36 on the outer periphery of the lower plunger spring (67). ) And the coil (65).

The grenade 20 described above may form a pair with the terminal 70 generating a separate specific frequency radio signal.

The receiving module 50 of the grenade 20 receives a specific frequency radio signal generated from the safety pins 21 (21a) and the terminal 70, and generates a magnetic field in the coil 65 when the specific frequency radio signal is not received. To generate.

Hereinafter, an operation relationship of the grenade 20 according to an embodiment of the present invention will be described with reference to FIGS. 3 and 9.

The terminal 70 is operated by a commander who directs the training. Conduct training

The thrower throws the grenade 20 toward the target point in the throwing region 100.

The safety clip (2) is secured before the throwing progress, the safety pin (21) (21a) is pulled out after the throwing, and the safety pin (21) (21a) and the striker lever (4) are separated in the vicinity of the throwing area (100). Will fall.

The safety pins 21 and 21a generate a specific frequency radio signal from the moment they are pulled out of the grenade 20.

That is, the switch 24 or the first and second contact points 28 and 29 are energized at the moment of being pulled out to the hook 22 of the safety pins 21 and 21a to operate the transmission module 25.

In the thrown grenade 20, the striker lever 4 is separated and the striker 9 is advanced by the restoring / resilience of the striker spring 13.

At the moment when the striker 9 proceeds, the first switch 31 operates the receiving module 50 to receive a specific frequency radio signal.

In addition, the ball 62 of the striker path blocker 60 protrudes into the inner diameter of the primer assembly 30 so that the striker 9 cannot proceed any further by physically preventing the striker 9 from proceeding. do.

After the grenade 20 enters the dangerous area 120 through the semi-hazardous area 110, the distance L1 between the grenade and the safety pin and the distance L2 between the grenade and the terminal are secured.

That is, the distance L1 between the grenade and the safety pin and the distance L2 between the grenade and the terminal are ensured that the grenade 20 is located far enough from the throwing area 100.

When the reception module 50 does not receive the specific frequency radio signal at a predetermined distance or more, and the specific frequency radio signal is not received, a magnetic field is generated in the coil 65 to move the plunger 63 downward.

The plunger 63 is moved while compressing the plunger spring 67, and the ball 62 is pushed by the striker flange 11 of the striker 9.

The striker 9 propels the striker 9 by the repulsive / repulsive force of the striker spring 13 to apply impact energy to the primer 14, and the primer 14 ignites the fuse 16. The flame of (16) explodes the explosive (17), the explosive (17) explodes the peony (8) to explode the grenade (20).

If the distance L1 between the grenade and the safety pin or the distance L2 between the grenade and the terminal is not secured, the magnetic field is not generated in the coil 65 because a specific frequency radio signal is continuously received in the receiving module 50. As a result, the ball 62 of the striker path blocker 60 prevents the striker 9 from proceeding, so that the grenade 20 does not explode.

This misfire can be safely handled by an explosive removal specialist.

That is, when the grenade falls due to the thrower's mistake, the grenade 20 does not explode, so that the throwing grenade 20 may not be exploded, thereby preventing safety accidents of the thrower as well as fellow soldiers and training conductors.

In addition, when the grenade 20 according to an embodiment of the present invention is used in practice, the use of the terminal 70 is naturally excluded, so that the receiving module 50 is caused by a specific frequency radio signal generated from the safety pins 21 and 21a. Reacting can be used in practice, and because it uses the same grenades 20 when trained, it is possible to minimize unexpected mistakes.

On the other hand, there are several grenades at the grenade throwing training ground, but in the non-threw grenades, the receiving module and the transmitting module do not operate, so it is safe regardless of the terminal.

In addition, the grenade that is not thrown does not operate the receiving module and the transmitting module, so the battery is not exhausted. However, when the battery life is over, the grenade performance cannot be expected. do.

Although the embodiments of the present invention have been described above with reference to the accompanying drawings, those skilled in the art to which the present invention pertains can understand that the present invention can be implemented in other specific forms without changing the technical spirit or essential features. will be.

Therefore, the above-described embodiments are to be understood as illustrative and not restrictive in all respects, and the scope of the present invention is indicated by the appended claims rather than the detailed description, and the meaning and scope of the claims and All changes or modifications derived from the equivalent concept should be interpreted as being included in the scope of the present invention.

Grenade according to an embodiment of the present invention made as described above can prevent accidental casualties by not exploding grenades when the distance L1 between the grenade and the safety pin or the distance L2 between the grenade and the terminal is not secured. have.

In addition, grenade throwing training is not divided into training and practical use, and the same grenade used in training can be used in practice to throw familiar grenades, thereby minimizing throwing.

In addition, since it is not necessary to manufacture a simulated grenade for training, it is possible to save that much money.

Claims (10)

A striker which is driven by the striker spring; A striker lever for holding the striker; A safety pin to secure the striker lever not to be separated; A primer ignited by the striker; A fuse burned by the primer for a predetermined time; An explosive agent exploded by the fuse; Peony exploded by the detonator; A primer assembly to which the striker and the primer are mounted; And a grenade shell splashing into fragments by the explosion of the peony; A safety pin for generating a specific frequency radio signal when drawn from a grenade; A striker path blocker physically obstructing the striker; And A receiving module configured to receive the specific frequency radio signal generated by the safety pin and to advance the striker at the striker path obstruction unit when the specific frequency radio signal is not received; Grenade comprising a. The method of claim 1, A first switch disposed on an inner diameter of the primer assembly to sense the progress of the striker and to operate the receiving module at the moment the striker proceeds; Grenade, characterized in that it further comprises. The method of claim 1, And a terminal for generating a specific frequency radio signal identical to the specific frequency radio signal. Grenade, characterized in that the terminal and the grenade forms a suit. The method of claim 1, The safety pin, ring; An insertion pin disposed on one side of the ring and inserted into a grenade; A transmission module formed at the other side of the ring and mounted with a battery and generating a specific frequency radio signal; And a switch disposed inside the ring to operate the transmission module under pressure when the ring is pulled. Grenade, characterized in that consisting of. The method of claim 4, wherein The grenade is formed in a different width and length, the grenade, characterized in that the switch is disposed on the inner side of the longer side of the width and length. The method of claim 1, The safety pin, ring; An insertion pin disposed on one side of the ring and inserted into a grenade; A pressure pin disposed in a direction parallel to the longitudinal direction of the insertion pin and being elastically mounted by a push spring; A first contact disposed on one side of the pressure pin; A second contact disposed at a position spaced apart from the first contact; And a transmission module disposed at the other side of the ring, mounted with a battery, and configured to generate the specific frequency radio signal by energizing the first contact point and the second contact point. The method of claim 1, The striker path blocker, A hole formed in the inner diameter of the primer assembly; A ball inserted into the hole and partially protruding into the inner diameter of the primer assembly to physically hinder the progress of the striker; A plunger mounted on an outer circumference of the primer assembly and made of a metal material moved by a magnetic field, and pushing the ball to protrude into the inner diameter of the primer assembly; A plunger spring disposed below the plunger and pushing the plunger to maintain a state in which the plunger is always moved upward; And A coil disposed on an outer circumference of the plunger to generate a magnetic field; Grenade, characterized in that consisting of. The method of claim 1, The grenade, characterized in that the plurality of holes and the ball. The method of claim 1, The receiving module, Battery unit for supplying power; And A circuit unit for receiving and calculating the specific frequency radio signal; Grenade, characterized in that consisting of. The method of claim 9, A partition wall disposed at one side of the circuit part to prevent the circuit part and the battery part from physically moving; Grenade, characterized in that it is further included.

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