KR20160073228A - Safety and arming device for fuse and explosive shell having the same - Google Patents

Abstract

The present invention relates to a safe loading device for a fuse and an explosive shell including the same. The safe loading device for a fuse of the present invention includes: a body which includes a flame delivery unit connected to one side of a fuse and delivering a flame to an explosive and a rotation shaft; a rotor which rotates around the rotation shaft; an opening/closing member which includes an opening unit for opening the flame delivery unit and a blocking unit for blocking the flame delivery unit, is placed at one side of the rotor, and is moved to an opening position at which the flame delivery unit is opened by the rotation of the rotor; a first rotor spring which moves by the centrifugal force upon the rotation of the body and allows the rotation of the rotor; a second rotor spring which moves relatively to the rotor by the inertia upon the movement of the body due to the launch of the fuse and allows the rotation of the rotor; and a frame which is integrated with the first rotor spring or second rotor spring and supports the first rotor spring or second rotor spring. By doing so, the present invention can simplify the structure and facilitate easy production and assembly.

Description

FIELD OF THE INVENTION [0001] The present invention relates to a safe loading apparatus for a new ship,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a safe loading apparatus for a new pipe and a shell having the same, and more particularly, to a safety loading apparatus for a new pipe which can be reduced in size, will be.

As is well known, a shell means a shot used in a cannon.

The shell is provided with a shell body and a new tube disposed at the tip end of the shell body to ignite the shell body.

Such a fuse may be classified into, for example, a quick turn, a delay, a time limit, a proximity, and an imperative fuse depending on the function.

In addition, the fuse may be classified into a firing line, an inertia, an electricity, a deadline, a radio wave, a magnetic field, an acoustic fuse, and a hydraulic fuse depending on, for example, an ignition method.

On the other hand, it is required that the shell be equipped with a safety device for the new pipe to prevent the shell from unexpectedly exploding when transported and / or stored in the field or other environment until the moment it is fired from a cannon or weapon.

However, in such a conventional safety device for a new pipe, if it is complicated, it becomes difficult to manufacture and assemble it, so that it takes a relatively long time and effort to manufacture and assemble it.

In addition, if the configuration is complicated, the reliability of the shell can be impaired by malfunction.

In addition, when the number of component parts is increased, the overall appearance size is increased to make it difficult to engage with the shell body, and the range of the shell may be adversely affected.

Further, in the case of a component such as a spring, if the size is reduced, many restrictions on production and / or assembly may occur.

Accordingly, it is an object of the present invention to provide a safe loading device for a new pipe which is simple in construction and can be easily manufactured and assembled, and a shell having the same.

It is another object of the present invention to provide a safe loading device for a new pipe capable of reducing the number of parts to be inserted and having a compact configuration, and a shell having the same.

In order to achieve the above-mentioned object, the present invention provides a flame conveying apparatus, comprising: a flame conveying unit connected to a side of a new pipe and communicating a flame to a peasant; A rotor rotated about the rotation axis; An opening and closing member disposed at one side of the rotor and having an opening for opening the flame transmitting portion and a blocking portion for blocking the flame transmitting portion and being moved to an open position where the flame transmitting portion is opened by rotation of the rotor; A first rotor spring which is moved by a centrifugal force when the body rotates to allow rotation of the rotor; And a second rotor spring which is relatively moved with respect to the rotor by inertia when the body is moved by the firing of the fuse tube to allow rotation of the rotor; And a frame integrally connected to the first rotor spring or the second rotor spring to support the first rotor spring or the second rotor spring.

Here, the first rotor spring and the second rotor spring may be integrally formed on the frame.

The first rotor spring or the second rotor spring includes a spring portion having a zigzag shape, a connecting portion connecting one side of the spring portion to the frame, a mass connecting portion connected to the mass portion on the other side of the spring portion, Respectively.

The second rotor spring may include a zigzag spring portion spaced apart from each other, a connecting portion connecting one side of each spring portion to the frame, and a mass supporting portion formed on the other side of each spring portion to support the mass body .

The second rotor spring may be configured to have a latch portion protruding from the mass body support portion and engaged with the rotation direction of the rotor.

The safety load device of the new pipe may further comprise a rotor delay spring for delaying the rotation of the rotor.

The rotor delay spring may be integrally formed on the frame.

The safety loading device of the new pipe may further include an opening / closing member spring provided at one side of the opening / closing member and allowing movement of the opening / closing member by a centrifugal force when the new pipe is fired.

The opening and closing member spring may be formed integrally with the frame.

The safety load device of the new pipe may further include a rotor driving spring for providing an elastic force to the rotor to rotate the rotor.

The rotor driving spring may be integrally formed with the frame when the frame is manufactured.

According to another aspect of the present invention, A fuse coupled to the shell body; And a safety load device of the fuse disposed between the shell body and the fuse.

As described above, according to the embodiment of the present invention, since the frame and the first rotor spring or the second rotor spring are integrally formed, the configuration can be simplified, and fabrication and assembly can be facilitated.

Further, since the frame and the first rotor spring or the second rotor spring are integrally formed, the configuration (or the input part) for supporting the first rotor spring or the second rotor spring can be reduced, and the overall appearance size can be reduced A compact configuration is possible.

Particularly, by integrally forming the frame and the first rotor spring, the second rotor spring, the rotor delay spring, the opening and closing member spring and / or the rotor driving spring integrally, the configuration (or the number of inserted parts) .

Further, since the first rotor spring, the second rotor spring, the rotor delay spring, the opening and closing member spring, and / or the rotor driving spring can be manufactured at the same time during manufacturing of the frame, the manufacturing process can be facilitated, .

In addition, the manufacturing cost and the assembly cost can be remarkably reduced by the integral manufacture of the frame and each spring.

In addition, since the frame and each spring are integrally manufactured, the tolerance for assembling each other is reduced, thereby enhancing the reliability of the product.

FIG. 1 is a perspective view of a shell having a safety loading apparatus for a new pipe according to an embodiment of the present invention,
Fig. 2 is a perspective view of the safety loading device of the fuse of Fig. 1,
FIG. 3 is a perspective view of a first body in which the second body of FIG.
Figure 4 illustrates the interior of the second body of Figure 1,
Fig. 5 is a plan view of the rotor drive spring in a state of being manufactured using the semiconductor manufacturing process of the frame and spring of Fig. 2,
Figure 6 is a plan view of the initial position of Figure 3,
Figure 7 is a top view of the loading position of Figure 3,
8 is a sectional view taken along the line VIII-VIII in Fig. 6,
9 is a cross-sectional view taken along line IX-IX of Fig.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIG. 1, a shell having a safety load device for a new pipe according to an embodiment of the present invention includes a shell body 110, a fuse 120 coupled to the shell body 110; And a safe loading device 140 of the fuse 120 disposed between the shell body 110 and the fuse 120.

The shell body 110 may include an envelope 111 that forms a receiving space therein and a peony 113 that is filled in the envelope 111.

The main pipe 120 includes a body 121 coupled to the shell body 110, a primer 123 provided in the body 121, and a mechanism for detonating the primer 123 when necessary 125, respectively.

A flame transmission path 127 may be formed in the main pipe 120 and the main body 110 to transmit the flame generated when the primer 123 is detonated to the pea pod 113.

The flame transmission path 127 is provided with the flame transmission path 127 before the can body 110 is shut off and the flame transmission path 127 is opened after the can body 110 is fired. A safety loading device 140 of the new pipe 120 according to an embodiment of the present invention may be provided.

The flame transmission path 127 connecting the main pipe 120 and the main body 110 is blocked before the main body 110 is fired so that the main body of the can body 120, It is possible to suppress the explosion of the battery 110.

As shown in FIGS. 2 and 3, the safety loading device 140 of the new pipe 120 is connected to one side of the new pipe 120 and connected to the flame transmitting part 154, and a rotating shaft 153; A rotor 180 rotated about the rotation shaft 153; And an opening 192 for opening the flame transmitting portion 154 and a blocking portion 194 for blocking the flame transmitting portion 154 are disposed on one side of the rotor 180, An opening / closing member 190 which is moved to an open position where the flame transmitting portion 154 is opened by rotation of the opening / closing member 190; A first rotor spring 220 which is moved by the centrifugal force when the body 150 rotates to allow rotation of the rotor 180; And a second rotor spring (230) that is moved relative to the rotor (180) by inertia when the body (150) is moved by the firing of the fuse (120) to allow rotation of the rotor (180). And a frame 210 integrally connected to the first rotor spring 220 or the second rotor spring 230 to support the first rotor spring 220 or the second rotor spring 230 .

The body 150 may be formed, for example, in a substantially rectangular parallelepiped shape.

The body 150 may be configured to have, for example, a rectangular parallelepiped shape in which one side edge is obliquely cut.

The body 150 may be provided with a flame transmitting unit 154 for transmitting a flame generated in the flue 120 to the can body 110.

The body 150 may include, for example, a first body 151 and a second body 161 which are vertically contact-coupled to each other.

The first body 151 and the second body 161 may be formed with partial flame transferring parts 152 and 162 which communicate with each other to form the flame transmitting part 154 when they are coupled to each other.

Each of the partial flame transmitters 152 and 162 may be formed in a cylindrical shape, for example.

For example, the first body 151 may be provided with a rotary shaft 153 on an upper surface thereof.

The rotation shaft 153 may be formed to protrude along, for example, a firing direction of the can body 110.

The rotary shaft 153 may be configured to have, for example, a semi-cylindrical shape in which a half of a circle is cut.

A guide 155 protruding in parallel to the rotation shaft 153 may be provided on one side of the first body 151, for example.

The guide 155 may be inserted into the guide receiving portion 165 formed on the second body 161, for example.

As a result, the first body 151 and the second body 161 can be easily coupled to each other.

Here, the number of the guide 155 and the guide receiving portion 165 can be appropriately adjusted.

For example, a rotor 180 may be rotatably coupled to the rotating shaft 153.

An opening and closing member (not shown) having a blocking portion 194 for blocking the flame transmitting portion 154 and an opening portion 192 for opening the flame transmitting portion 154 is provided on one side of the rotating shaft 153 190 may be provided.

The opening and closing member 190 may be configured such that, for example, the rotation of the rotor 180 is relatively slid.

The first body 151 may be provided with an opening and closing member receiving portion 157 such that the opening and closing member 190 can be slidably received.

Although the opening and closing member 190 has a long plate-like shape and is relatively slid in the present embodiment, the opening and closing member (not shown) for opening and closing the flame transmitting unit 154 may be rotatable.

The partial flame transmitting portion 152 of the first body 11 may be formed in one side region of the opening and closing member receiving portion 157.

The opening and closing member 190 may be formed, for example, in a rectangular plate shape.

The opening 192 may be formed through the plate surface of the opening and closing member 190, for example.

The rotor 180 may have, for example, a cylindrical shape.

A rotating shaft hole 182 may be formed at the center of the rotor 180 so that the rotating shaft 153 can be inserted therein, for example.

The rotating shaft hole 182 may be formed in a circular cross section so that the rotor 180 may be rotated about the rotating shaft 153, for example.

On one side of the rotor 180, for example, an action rod 184 protruding outward along the radial direction may be provided.

On the other side of the rotor 180, for example, a locking portion 186 protruding toward the opening / closing member 190 may be formed.

On the other side of the rotor 180, for example, a first rotor spring 220 which is moved by the centrifugal force when the body 150 rotates to allow the rotation of the rotor 180 is provided .

The other end of the rotor 180 is moved relative to the rotor 180 by inertia when the body 150 is moved by the firing of the fuse 120, And a second rotor spring 230 that allows relative rotation with respect to the rotation shaft 153 may be provided.

The first rotor spring 220 or the second rotor spring 230 is integrally connected to the upper surface of the first body 151 and integrally connected to the first rotor spring 220 or the second rotor spring 230, 230 may be provided.

The first rotor spring 220 may include a locking portion 228 protruding toward the rotor 180, for example.

The rotor 180 may be configured to include a first stopping jaw 188 engaged with (engaged with) the stopping portion 228 of the first rotor spring 220 in the rotating direction.

The first stopping jaw 188 of the rotor 180 may be recessed along the radial direction on the outer circumferential surface of the rotor 180, for example.

The second rotor spring 230 may include a locking portion 238 protruding toward the rotor 180, for example.

The rotor 180 may be configured to include a second locking protrusion 189 engaged with (constrained to) the locking portion 238 of the second rotor spring 230 in the rotating direction.

The second stopping jaw 189 may be formed to be recessed along the radial direction and extend along the axial direction, for example, on the outer circumferential surface of the rotor 180.

The engagement portion 238 moves relative to the second engagement protrusion 189 when the second rotor spring 230 is moved relative to the can body 110 due to the inertia of the fuselage body 110 And can be separated.

Meanwhile, the rotor 180 may be provided with a rotor driving spring 260 that provides an elastic force to rotate the rotor 180 about the rotation axis 153.

 The rotor 180 may include a rotor drive spring receiving portion 185 to receive the rotor drive spring 260, for example.

The rotor drive spring receiving portion 185 may be formed at a lower portion of the rotor 180, for example.

The opening and closing member spring 240 may include a latching portion 248 protruding toward the opening and closing member 190.

The catching portion 248 of the opening and closing member spring 240 may be configured to protrude in a direction opposite to the direction of centrifugal force that acts upon firing of the shell body 110, for example.

The latching portion 248 of the opening and closing member spring 240 may be disposed on the path of the opening and closing member 190, for example.

Thus, the opening / closing member 190 can be prevented from moving to the open position before the can body 110 is fired.

More specifically, the latching portion 248 of the opening / closing member spring 240 may protrude in contact with the end of the opening / closing member 190.

According to such a configuration, a process of adding a separate structure that interacts with the latching portion 248 to the opening / closing member 190 may be omitted.

Meanwhile, the first rotor spring 220 may be integrally formed with the frame 210, for example.

The second rotor spring 230 may be integrally formed with the frame 210, for example.

The rotor driving spring 260 may be integrally formed with the frame 210, for example.

The opening and closing member spring 240 may be integrally formed with the frame 210, for example.

One side of the frame 210 may be provided with a rotor delay spring 250 that contacts the rotor 180 to delay the rotation of the rotor 180, for example.

The rotor delay spring 250 includes a spring portion 252 having an arc shape and a spring portion 252 projecting from the spring portion 252 toward the rotor 180 and spaced apart from each other in the rotational direction of the rotor 180 And a delay projection 254.

The spring portion 252 of the rotor delay spring 250 may be embodied as an arc having a concave center toward the rotor 180, for example.

Each of the delay protrusions 254 may contact the operation rod 184 of the rotor 180 during rotation of the rotor 180 to delay the rotation speed of the rotor 180.

A slit 256 may be formed in the rear of the spring portion 252 of the rotor delay spring 250 so that the spring portion 252 is elastically deformed outwardly.

The spring portion 252 elastically deforms outward along the radial direction of the rotor 180 when the operation rod 184 of the rotor 180 and the delay projection 254 are in contact with each other, The rotating speed of the rotor 180 can be reduced while repeating the process of passing the working rod 184 and returning to the initial position by the elastic force of the working rod 184.

The first rotor spring 220, the second rotor spring 230, the rotor delay spring 250, the rotor driving spring 260, and the opening and closing member spring 240 are mounted on respective frames (not shown) As shown in Fig.

Although not shown in the drawing, the first rotor spring 220, the second rotor spring 230, the rotor delay spring 250, the rotor driving spring 260, and the opening / closing member spring 240 may be configured to include a plurality of frames so that a plurality of springs are formed in one frame.

More specifically, for example, a first rotor spring 220 and a second rotor spring 230 are formed in one frame, and the rotor delay spring 250, the rotor drive spring 260, The opening and closing member spring 240 may be formed to have two frames.

4, the first rotor spring 220, the second rotor spring 230, the rotor delay spring 250, the rotor driving spring 260, and the opening / closing member spring (not shown) 240 are integrally formed when the frame 210 is manufactured, so that a minimum number (one) of the frames 210 is formed.

The frame 210, the first rotor spring 220, the second rotor spring 230, the rotor delay spring 250, the rotor driving spring 260, and the opening / closing member spring 240 are, for example, And can be manufactured using a manufacturing process.

 The frame 210, the first rotor spring 220, the second rotor spring 230, the rotor delay spring 250, the rotor driving spring 260, and the opening / closing member spring 240 are, for example, And can be fabricated using a wet etching process, one of the fabrication processes.

The frame 210 may have a frame shape corresponding to a shape of a frame of the body 150, for example.

The frame 210 may be formed to be accommodated in the first body 151 and the second body 161, for example.

The frame 210 may be formed of, for example, a metal member having a small thickness.

The frame 210 may be formed of, for example, a stainless steel member.

In the frame 210, for example, the rotor receiving portion 214 may be formed so that the rotor 180 can be rotatably received.

In the frame 210, for example, the opening and closing member receiving portion 216 may be formed to pass through the opening and closing member 190 such that the opening and closing member 190 can be movably received.

The first rotor spring 220 may be formed on one side of the rotor accommodating portion 214.

The first rotor spring 220 includes a spring portion 222 having a zigzag shape, a connecting portion 224 protruding from one side of the spring portion 222 and connected to the frame 210, And a mass connecting portion 226 formed to connect the mass body 229 to the other side of the spring portion 222.

The spring portion 222 is formed by connecting a first side portion 223a and a first side portion 223a which are adjacent to each other and which are connected to each other in a zigzag shape, And two side portions 223b.

The latch portion 228 may be provided on one side of the mass connection portion 226 of the first rotor spring 220.

The mass connecting portion 226 of the first rotor spring 220 may be formed with an insertion hole 227 through which the mass body 229 can be inserted.

The mass body 229 of the first rotor spring 220 may be formed, for example, in a cylindrical shape.

The second rotor spring 230 may include a spring portion 232 spaced apart from each other, a connecting portion 232 connecting one side of each spring portion 232 and the frame 210, And a mass support portion 236 formed to connect the other side of the spring portion 232 to each other to support the mass body 239.

Each of the spring portions 232 of the second rotor spring 230 has a first side portion 233a and a first side portion 233a which are adjacent to each other and are connected to each other, And a second side portion 233b that opens in a zigzag shape so as to be opened.

The mass support portion 236 of the second rotor spring 230 is bent and extended from the other end of each spring portion 232 toward the connection portion 234 and extends in a mutually approaching direction May be formed to be connected.

The mass support part 236 of the second rotor spring 230 may be formed with a locking part 238 protruding toward the rotation shaft 153.

The mass body 239 may be provided so as to be in contact with and supported by one side of the mass body support portion 236 and the engaging portion 238 (the upper side in the drawing and the front side along the direction in which the shell body 110 is fired).

The rotor 180 and the body 150 are moved in the firing direction of the shell body 110 and the mass body 239 of the second rotor spring 230 is rotated, The engaging portion 238 is separated from the second engaging protrusion 189 of the rotor 180 and can be released from engaging (restraining) with respect to the rotational direction by relative movement with respect to the rotor 180 by inertia .

For example, the opening and closing member spring 240 may be provided on one side of the opening and closing member receiving portion 216. [

The opening and closing member spring 240 includes a spring portion 242 having a zigzag shape, a connecting portion 244 connecting one side of the spring portion 242 and the frame 210, And a mass connecting portion 246 formed to connect the mass body 249 to the other side of the first and second connecting portions 241 and 242.

The spring portion 242 of the opening and closing member spring 240 is connected to the first side portion 243a and the first side portion 243a adjacent to each other, And a second side portion 243b which is connected in a zigzag manner.

The mass connecting portion 246 of the opening and closing member spring 240 may have an insertion hole 247 through which the mass body 249 can be inserted, for example.

Meanwhile, the rotor driving spring 260 may be formed integrally with the frame 210 when manufactured.

The rotor driving spring 260 includes a rotating shaft receiving portion 262 in which the rotating shaft 153 is received and a spring portion 264 extending spirally from the rotating shaft receiving portion 262 Lt; / RTI >

The rotating shaft receiving portion 262 may be formed in, for example, a semicircular shape.

The rotor driving spring 260 may include a connecting portion 266 extending outwardly from the spring portion 264 and connected to the frame 210.

The rotor driving spring 260 extends from one side of the rotor delay spring 250 to the rotor accommodating portion 214 side during fabrication so that the spring portion 262 contacts the rotor accommodating portion 214, As shown in Fig.

The rotor drive spring 260 may be formed by cutting a connecting portion 266 connected to one side of the frame 210 and the rotor delay spring 250, Can be separated.

The connecting portion 262 of the rotor driving spring 260 may be bent to be fixedly coupled to the lower end of the rotor 180 to form the bent end portion 268.

The folded end 268 of the rotor drive spring 260 may be coupled to the rotor 180 to be constrained, for example, with respect to the direction of rotation of the rotor 180.

The rotation shaft receiving portion 262 is fixed to the rotation shaft 153 when the rotor 180 rotates and the bent end portion 268 is engaged with the rotor 180 to rotate the rotation shaft 153 The spring portion 262 is compressed and the elastic force is accumulated in the spring portion 262.

The folded end 268 of the rotor drive spring 260 may be implemented, for example, to have a reverse 'U' or inverted U 'shape.

A guide receiving hole 218 may be formed in one side of the frame 210 to receive the guide 155 of the body 150.

5, the second body 161 may be formed with a rotary shaft receiving portion 163 in which the rotary shaft 153 is received.

The first mass accommodating portion 164 may be formed in the second body 161 so that the mass body 229 of the first rotor spring 220 can be accommodated.

The second body 161 may be formed with a second mass accommodating portion 166 to accommodate the mass body 29 of the second rotor spring 230, for example.

The third mass accommodating portion 168 may be formed in the second body 161 so that the mass body 249 of the opening and closing member spring 240 may be accommodated.

Here, the first mass accommodating portion 164 and the third mass accommodating portion 168 are configured such that, for example, the mass bodies 229, 249 are respectively moved to the outside of the second body 161 by a centrifugal force It can be formed into a long hole shape.

The mass body 229 of the first rotor spring 220 and the mass body 249 of the opening and closing member spring 240 are constrained with respect to the direction of emission of the shell body 110 when the shell body 110 is fired It is possible to move in the outward direction when the centrifugal force is caused by the rotation of the shell body 110.

The second mass accommodating portion 166 may be cylindrical such that the mass body 239 of the second rotor spring 230 can be moved by inertia when the shell body 110 is fired .

The mass body 239 of the second rotor spring 230 is restricted in the direction of centrifugal force and can be slidably moved relative to the firing direction of the shell body 110.

The first mass accommodating portion 164 and the second mass accommodating portion 164 that accommodate the mass body 229 of the first rotor spring 220 and the mass body 249 of the opening and closing member spring 240, The receiving portion 168 is formed inside the second body 161 and accommodates the rotating shaft 153 having a relatively high height, the mass body 239 of the second rotor spring 230, and the guide 155, The second mass body accommodating portion 166 and the guide accommodating portion 165 are formed to penetrate through the second body 161. However, the present invention is not limited to this, When the height of the object to be accommodated in the second body 161 is low and the height of the object accommodated in the accommodating portion is high, the second body 161 may be formed to pass through the second body 161 to be.

With this structure, the frame 210 of the first body 151 is engaged and the rotor drive spring 260 can be coupled to the rotation shaft 153.

The rotor 180 may be coupled to the rotating shaft 153 and the opening and closing member 190 may be coupled to the opening and closing member receiving portion.

The respective mass connecting portions of the first rotor spring 220, the second rotor spring 230, and the opening and closing member spring 240 may be connected to each other in a mutually operable manner.

Meanwhile, the rotor 180 is coupled to the rotor driving spring 260, and the rotor driving spring 260 can be rotated in the direction in which the elastic force is accumulated, that is, the initial position.

More specifically, the rotor 180 may be rotated to the initial position and fixed by the first rotor spring 220 and the second rotor spring 230.

6 and 8, the opening and closing member 190 may be opened and closed at a position where the blocking portion 194 blocks the flame transmitting portion 154, that is, in a blocking position (initial position) The stopper 186 of the rotor 180 and the stopper 248 of the opening and closing member spring 240 are restrained from moving to move the position where the flame transmitting portion 154 is opened, Unexpected movement to the position can be suppressed.

The second body 161 may be coupled to the upper side of the first body 151.

The masses of the guide 155, the rotary shaft 153, the mass body 229 of the first rotor spring 220, the mass body 239 of the second rotor spring 230, 249 may be received and coupled to the respective mass receiving portions, respectively.

The safe loading device 140 of the new pipe 120 of the present embodiment in which the first body 151 and the second body 161 are coupled is provided with a flame passing path between the new pipe 120 and the can body 110 (Not shown).

Meanwhile, when the shell body 110 is fired, the safety loading device 140 of the fuse 120 may be moved along the firing direction and rotated with the firing direction as a rotation center axis.

7, the mass body 229 of the first rotor spring 220 and the mass body 249 of the opening and closing member spring 240 are rotated in the same direction as the first embodiment, Can be moved to the outside of the body 150 by centrifugal force.

At the same time, the mass body 239 of the second rotor spring 230 can be relatively moved backward in the direction of fire by inertia.

When the mass body 229 of the first rotor spring 220 is moved outward and the mass body 239 of the second rotor spring 230 is moved backwardly, the rotor 180 can be released from the restraint .

The rotor 180 with its restrained state can be rotated to the loading position about the rotation axis 153 by the elastic force of the rotor driving spring 260. [

The rotor delay spring 250 may contact the working rod 184 of the rotor 180 to reduce the rotational speed of the rotor 180.

The working rod 184 of the rotor 180 rotated through the rotor delay spring 250 may press the end of the opening and closing member 190 to move to the loading position.

The opening and closing member 190 can be moved to the loading position, as shown in Fig. 9, by the action of the operating rod 184 of the rotor 180. [

So that the open portion 192 is communicated with the flame transmitting portion 154 so that the flame of the fuse 120 can be transmitted to the shell body 110 in a so-called "armed"

When the primer 125 of the fuse 120 performs its original function and the primer 123 explodes, the flame generated in the fuse 120 flows through the flame transmitter 154, And is transmitted to the shell body 110, whereby the peony shell 113 of the shell body 110 can explode.

The foregoing has been shown and described with respect to specific embodiments of the invention. However, the present invention may be embodied in various forms without departing from the spirit or essential characteristics thereof, so that the above-described embodiments should not be limited by the details of the detailed description.

Further, even when the embodiments not listed in the detailed description have been described, it should be interpreted broadly within the scope of the technical idea defined in the appended claims. It is intended that the present invention cover the modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents.

110: shell body 111: sheath
113: Peony 120: Fuse
121,150: Body 123: Primer
125: Mechanism 140: Safety Loading Device of the Fuse
151: first body 152, 162: partial flame transfer part
153: rotating shaft 154:
155: guide 161: second body
180: rotor 182: rotating shaft
184: working rod 186, 228, 238, 248:
188: first stopping jaw 189: second stopping jaw
190: opening / closing member 192:
194: breaking portion 220: first rotor spring
222, 232, 242, 252, 264: spring portions 224, 234, 244, 266:
223a, 233a, 243a: first side portions 223b, 233b, 243b: second side portions
226, 246: Mass connection 229, 239, 249: Mass
230: second rotor spring 240: opening / closing member spring
250: rotor delay spring 260: rotor driving spring

Claims (10)

A flame transmitting part connected to one side of the new pipe and communicating the flame to the peasant, and a body having a rotating shaft;
A rotor rotated about the rotation axis;
An opening and closing member disposed at one side of the rotor and having an opening for opening the flame transmitting portion and a blocking portion for blocking the flame transmitting portion and being moved to an open position where the flame transmitting portion is opened by rotation of the rotor;
A first rotor spring which is moved by a centrifugal force when the body rotates to allow rotation of the rotor; And
A second rotor spring which is moved relative to the rotor by inertia when the body is moved due to the firing of the fuse and permits rotation of the rotor; And
And a frame integrally connected to the first rotor spring or the second rotor spring to support the first rotor spring or the second rotor spring. The method according to claim 1,
Wherein the first rotor spring and the second rotor spring are integrally formed on the frame. 2. The apparatus of claim 1, wherein the first rotor spring or the second rotor spring comprises:
Characterized in that it comprises a zigzag spring portion, a connecting portion connecting one side of the spring portion to the frame, a mass connecting portion connected to the mass portion on the other side of the spring portion, and a latch portion engaged with the rotor, Safety Loading Device. The rotor according to claim 1, wherein the second rotor spring
A mass supporting part formed to support the mass body on the other side of each of the spring parts; and a mass supporting part protruding from the mass supporting part, And a latching portion which is held in engagement with the rotation direction. The method according to claim 1,
Further comprising a rotor delay spring for delaying rotation of the rotor,
Wherein the rotor delay spring is integrally formed on the frame. 6. The method according to any one of claims 1 to 5,
And an opening / closing member spring provided on one side of the opening / closing member and allowing movement of the opening / closing member by a centrifugal force when the fuse is fired. The method according to claim 6,
Wherein the opening / closing member spring is integrally formed with the frame. The method according to claim 6,
And a rotor drive spring for providing an elastic force to the rotor to rotate the rotor. 9. The method of claim 8,
Wherein the rotor driving spring is formed integrally with the frame when the frame is manufactured. Shell body;
A fuse coupled to the shell body; And
The safety device of claim 1, wherein the safety device is disposed between the shell body and the fuse.

Images