KR102038577B1 - Fuse assembly including structure for buffering impact - Google Patents

Abstract

Disclosed is a fuse assembly for controlling detonation of a warhead. The fuse assembly comprises: a fuse body including a cylindrical housing, a control part for controlling detonation of a warhead, and a buffering part for floating the control part from the housing; a flange part arranged along a circumferential direction of the housing and protruding toward the outside of the housing to support the fuse body; and a buffering pad arranged in a position that surrounds the flange part to buffer impacts delivered to the fuse body.

Description

Fuse assembly including structure for buffering impact

The present disclosure is directed to a fuse assembly that includes an impact relief structure. More particularly, the present disclosure relates to fuse assemblies and warheads comprising the same, including means for mitigating impact in the transverse and rear directions as well as in the flight axial direction.

Fuses can be applied to a variety of weapon systems to ensure operator safety and to detonate warheads at the optimal time or location. The fuse can operate in a variety of ways, including mechanical and electronic, to control where and when the warhead detonates. In order to more precisely control the detonation of the warhead, research is being conducted to improve the performance of the fuse.

In order for the fuse to operate as intended and precisely control the detonation of the warhead, it may be necessary to identify the requirements according to the operating environment of the weapon system to which the fuse is applied and the characteristics of the target target of the warhead and to design the fuse accordingly. have. In particular, in the case of a fuse applied to a weapon system in a high-impact environment, the operation reliability of the fuse in the environment may be a problem.

Therefore, even when the fuse is operated in a high-impact environment, a technique for improving the impact resistance of the fuse may be required so that the fuse can be stably operated to control the bombing of the warhead.

Various embodiments are to provide a fuse assembly that includes an impact relief structure. The technical problem to be achieved by the present disclosure is not limited to the above-described technical problems, and other technical problems may be inferred from the following embodiments.

As a means for solving the above technical problem, a fuse assembly for controlling the detonation of the warhead according to an aspect of the present disclosure, a cylindrical housing, a control unit for controlling the detonation of the warhead and the control unit A fuse body including a buffer for floating from the housing; A flange portion disposed along the circumferential direction of the housing and protruding toward the outside of the housing to support the fuse body; And a buffer pad disposed at a position surrounding the flange to mitigate an impact transmitted to the fuse body.

A warhead to which the fuse assembly according to another aspect of the present disclosure is mounted includes: the fuse assembly; A fuse mount for receiving the fuse assembly and supporting the fuse assembly through the flange portion; And a fuse fixing part configured to close the fuse mounting part to fix the fuse assembly together with the fuse mounting part.

The fuse assembly according to the present disclosure is provided with a buffer for floating the control unit from the housing and a buffer pad for mitigating an impact transmitted to the fuse body, so that the impact resistance of the fuse assembly can be improved. Accordingly, even when the warhead including the fuse assembly is operated in a high impact environment, the detonation of the warhead can be stably controlled, so that the operation reliability of the fuse assembly and the warhead can be improved.

1 is a view for explaining the fuse used in the prior art and its problems.
2 is a block diagram illustrating elements constituting a fuse assembly and a warhead including the same according to some embodiments.
3 and 4 are views illustrating in more detail the fuse assembly according to some embodiments.
FIG. 5 is a diagram more specifically illustrating a warhead including a fuse assembly according to some embodiments. FIG.

Hereinafter, exemplary embodiments will be described in detail with reference to the accompanying drawings. The following description is only intended to embody the embodiments, but does not limit or limit the scope of the invention. It can be interpreted to fall within the scope of rights that can be easily inferred by those skilled in the art from the detailed description and examples.

Terms such as “consisting of” or “comprising” as used herein should not be construed as necessarily including all of the various components or steps described in the specification, and some of the components or some steps It should be understood that it may not be included, or that additional components or steps may be further included.

As used herein, terms including ordinal numbers such as 'first' or 'second' may be used to describe various components, but the components should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from other components.

The terminology used herein has been selected as the most widely used general terms in view of the functions in the present invention, but may vary according to the intention or precedent of a person skilled in the art, the emergence of new technologies, and the like. In addition, in certain cases, there is also a term arbitrarily selected by the applicant, in which case the meaning will be described in detail in the description of the corresponding invention. Therefore, the terms used in the present invention should be defined based on the meanings of the terms and the contents throughout the present invention, rather than the names of the simple terms.

The embodiments of the present invention relate to a fuse assembly including a shock absorbing structure, and detailed descriptions of matters well known to those skilled in the art to which the following embodiments belong will be omitted.

1 is a view for explaining the fuse used in the prior art and its problems.

Referring to FIG. 1, a conventional fuse 1 is shown fixed to the mounting portion 2 by a fixing portion 3. The fuse 1, the mounting part 2, and the fixing part 3 are all mounted on a warhead or the like, and the detonation of the warhead may be controlled by the fuse 1.

The warhead on which the fuse 1 is mounted may fly toward the target along the flight axis direction D0. In the process of the warhead on which the fuse 1 is mounted reaches the target, various kinds of impacts may be applied to the fuse 1 depending on the weapon system to which the fuse 1 is applied. In particular, even after the warhead on which the fuse 1 is mounted approaches the target as in the case of a penetrating coal or the like, when the starting point and the position of the detonation are controlled by the fuse 1, the fuse 1 is large from several directions. The shock can be transmitted.

In the case of the conventional fuse (1), a buffer pad (4) may be provided between the fuse (1) and the mounting portion (2) in order to mitigate the impact that the warhead proceeds in the flight axis direction (D0). As the shock absorbing pad 4 is provided, the shock transmitted from the flight axis direction D1 to the fuse 1 can be alleviated.

However, in addition to the impact in the flight axis direction (D1), the fuse 1 can be transmitted from the transverse direction (D2) and the rear direction (D3), due to the impact in the transverse direction (D2) and rear direction (D3) Internal components of the fuse 1 may be damaged. Accordingly, the detonation of the warhead may not be properly controlled, and a design for enhancing the impact resistance of the fuse 1 may be required to prevent this.

2 is a block diagram illustrating elements constituting a fuse assembly and a warhead including the same according to some embodiments.

Referring to FIG. 2, the warhead 10 including the fuse assembly 100 may include a fuse assembly 100, a fuse mount 200, and a fuse fixation 300. However, the present invention is not limited thereto, and other general elements other than the elements illustrated in FIG. 2 may be further included in the warhead 10.

Fuse assembly 100 may control the detonation of warhead 10. Fuse assembly 100 may control the ignition of explosives, gunpowder, etc. loaded on warhead 10 so that warhead 10 may detonate at its intended location and time. For example, the fuse assembly 100 may control the detonation of the warhead 10 via electronic, mechanical, or a combination thereof. Fuse assembly 100 may include electronic or mechanical control means for controlling the detonation of warhead 10.

The fuse assembly 100 may include a fuse body 110, a flange portion 120, and a buffer pad 130. Fuse body 110 may include control means for controlling the detonation of warhead 10, flange portion 120 may be a means for supporting fuse assembly 100 mounted to warhead 10, and The shock absorbing pad 130 may be a means for mitigating an impact transmitted to the fuse assembly 100.

The fuse mount 200 may receive the fuse assembly 100 and support the fuse assembly 100 through the flange portion 120. The fuse mounting unit 200 may include an accommodation space in which the fuse assembly 100 is accommodated, and the fuse assembly 100 may be accommodated in the accommodation space to be fitted. However, in order to alleviate the shock transmitted to the fuse assembly 100 in a high impact environment, the accommodation space may include some free space in addition to the space occupied by the fuse assembly 100.

The fuse fixing unit 300 may close the fuse mounting unit 200 to fix the fuse assembly 100 together with the fuse mounting unit 200. The fuse assembly 100 may be preferentially accommodated in the fuse assembly 200, and then the fuse fixing part 300 may be coupled to the fuse mount 200 so that the fuse assembly 100 may be separated from the warhead 10. It can be mounted stably on the warhead 10 without.

3 and 4 are views illustrating in more detail the fuse assembly according to some embodiments.

Referring to FIG. 3, a perspective view of a specific shape of the elements constituting the fuse assembly 100 is shown. Referring to FIG. 4, a cross section of the fuse assembly 100 with respect to the centerline A-A 'of FIG. Is shown.

The fuse body 110 includes a cylindrical housing 111, a control unit 112 for controlling the detonation of the warhead 10, and a buffer unit 113 for floating the control unit 112 from the housing 111. It may include.

The housing 111 may be formed in a cylindrical shape. As the housing 111 is formed in a cylindrical shape, the impact transmitted from all directions may not be concentrated on a specific portion, and thus the fuse body 110 may be suitable to have high impact resistance. However, the shape of the housing 111 is not limited to the cylindrical shape, and the shape of the housing 111 may be another shape that allows the fuse assembly 100 to be accommodated in the fuse mounting unit 200.

The controller 112 may be a means for controlling the detonation of the warhead 10. The controller 112 may be an electronic component for controlling the detonation of the warhead 10, and the fuse assembly 100 may operate electronically. However, the present invention is not limited thereto, and the controller 112 may be a means for controlling the detonation of the warhead 10 mechanically, or may be implemented by a combination of electronic and mechanical.

The control 112 may be required to be protected for the fuse assembly 100 to operate normally. If high impact is continuously applied to the control unit 112 during operation of the warhead 10, the control unit 112 may be damaged and the detonation of the warhead 10 may not be controlled. Therefore, the shock absorbing unit 113 and the shock absorbing pad 130 to be described later may be provided in the fuse assembly 100 to mitigate the shock transmitted to the control unit 112.

The buffer unit 113 may be a means for floating the control unit 112 from the housing 111. Floating may mean physically spaced apart from the impact being transmitted directly. The buffer unit 113 may be disposed between the housing 111 and the controller 112, and may fill the interspace with a buffer material to float the controller 112 from the housing 111.

The buffer unit 113 may be formed of glass beads. Glass beads may be utilized as a buffer material for filling the space between the housing 111 and the control unit 112. The glass bead is a bead-shaped filler formed of a glass material such as a ceramic, and can absorb an external shock and prevent the shock from being transmitted to the inside.

In particular, as the buffer 113 is formed of glass beads, unlike the case of the filler of the existing foam or non-foamable polyurethane (polyurethane) material, even if the impact delivered to the fuse assembly 100 is long lasting The buffering effect can be maintained continuously.

The flange portion 120 may be disposed along the circumferential direction of the housing 111, and may protrude toward the outside of the housing 111 to support the fuse body 110. The flange portion 120 may protrude along the side surface of the housing 111 in a donut shape.

The flange portion 120 may support the fuse assembly 100. When the fuse assembly 100 is accommodated in the fuse mounting unit 200, the fuse assembly 100 may be supported by the flange part 120 to be mounted to the fuse mounting unit 200. The flange portion 120 may be formed at any height suitable for mounting the fuse assembly 100 to the fuse mount 200.

The buffer pad 130 may be a means for mitigating an impact transmitted to the fuse body 110 by being disposed at a position surrounding the flange portion 120. When the fuse assembly 100 is mounted to the warhead 10, the impact may be concentrated on the flange portion 120 supporting the fuse assembly 100, so that the flange portion 120 is wrapped with the buffer pad 130. The shock transmitted to the flange portion 120 and the fuse body 110 can be alleviated.

The buffer pad 130 may be composed of a plurality of buffer pads. Each of the plurality of buffer pads may be disposed at a position surrounding a portion of the flange portion 120, and the entirety of the flange portion 120 may be wrapped by the plurality of buffer pads. For example, the buffer pad 130 may include a first buffer pad 131 disposed on the flight axis direction side and a second buffer pad 132 disposed on the transverse direction and the rear direction side.

When the shock absorbing pad 130 is composed of the first shock absorbing pad 131 and the second shock absorbing pad 132, the first shock absorbing pad 131 is a flight axis direction in which the warhead 10 of the flange portion 120 flows. It can be disposed on the side to mitigate the impact in the flight axis direction, the second buffer pad 132 is disposed on the transverse and rear direction side of the flange portion 120 to mitigate the transverse impact and the impact in the rear direction Can be.

Accordingly, the impact resistance of the fuse assembly 100 may be improved compared to the case where only a shock absorbing pad is provided to mitigate the impact in the flight axis direction. In particular, since the shock absorbing in the transverse direction and the rear direction by the second buffer pad 132 can be alleviated, the shock transmitted to the fuse body 110 and the control unit 112 can be reduced, the operation of the fuse assembly 100 Reliability can be improved.

The buffer pad 130 may be formed of at least one of polytetrafluoroethylene (PTFE, polytetrafluoroethylene), nylon, and nylon-based materials. Polytetrafluoroethylene may mean Teflon, and examples of nylon-based materials may include MC nylon (mono cast nylon). The buffer pad 130 may be formed of the fiber material as described above to mitigate the shock transmitted to the fuse body 110 and the control unit 112.

The fuse body 110 may further include an inner partition 114 in addition to the housing 111, the control unit 112, and the buffer unit 113. The inner partition wall 114 may separate the fuse body 110 forward and backward. The control unit 112 and the buffer unit 113 may be disposed at the front side separated by the inner partition wall 114, and the flange portion 120 may be disposed at the rear side separated by the inner partition wall 114.

While operating the warhead 10, the flange portion 120 to which the impact is intensively transmitted is disposed at the rear, while the control unit 112 to be protected from external impact may be disposed at the front. Accordingly, the impact transmitted through the flange portion 120 may be more effectively prevented from being applied to the controller 112.

FIG. 5 is a diagram more specifically illustrating a warhead including a fuse assembly according to some embodiments. FIG.

Referring to FIG. 5, a fuse assembly 100, a fuse mount 200, and a fuse fixation 300 included in the warhead 10 are illustrated. The fuse assembly 100 may be coupled between the fuse mounting unit 200 and the fuse fixing unit 300 to be mounted on the warhead 10.

The fuse fixing part 300 may be coupled to the fuse mounting part 200 in various ways to fix the fuse assembly 100. For example, the fuse fixing part 300 and the fuse mounting part 200 may be formed with a spiral protrusion and a spiral groove, and screw coupling of the fuse fixing part 300 and the fuse mounting part 200 through the spiral protrusion and the spiral groove. This can be done.

When the fuse assembly 100 is mounted to the warhead 10, the warhead 10 may be controlled to detonate at the intended time and location, thereby increasing the operational efficiency of the warhead 10. In addition, the fuse assembly 100 is provided with a buffer unit 113 and the buffer pad 130, the shock transmitted to the control unit 112 can be alleviated to improve the impact resistance of the fuse assembly 100, the shock pad In addition to the first shock absorbing pad 131 in the axial direction of the flight 130, the second shock absorbing pad 132 in the lateral and rear directions is provided, so that the shock in the lateral and rear directions may be alleviated. The operating reliability of can be improved.

Although the embodiments have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements of those skilled in the art using the basic concepts of the present invention defined in the following claims are also within the scope of the present invention. Belongs to.

10: warhead
100: fuse assembly
110: fuse body
111: housing
112: control unit
113: buffer
120: flange
130: buffer pad
131: first buffer pad
132: second buffer pad
200: fuse fitting
300: fuse fixing part

Claims (6)

In a fuse assembly that controls the detonation of the warhead,
A fuse body including a cylindrical housing, a control unit for controlling the detonation of the warhead, and a buffer for floating the control unit from the housing;
A flange portion disposed along the circumferential direction of the housing and protruding toward the outside of the housing to support the fuse body; And
A shock absorbing pad disposed at a position surrounding the flange to mitigate an impact transmitted to the fuse body;
The fuse body,
Further comprising an internal partition wall separating the fuse body forward and rearward,
And the control unit and the buffer unit are disposed at the front, and the flange unit is disposed at the rear. The method of claim 1,
The buffer pad,
A first buffer pad disposed on a flight axis direction side in which the warhead of the flange portion flows to mitigate an impact in the flight axis direction; And
And a second cushioning pad disposed on the transverse and rearward sides of the flange portion to mitigate the transverse shock and the rearward shock. The method of claim 1,
The buffer pad,
A fuse assembly formed of at least one of polytetrafluoroethylene (PTFE), nylon (nylon), and nylon based materials. delete The method of claim 1,
The cushion assembly is formed of a glass bead (glass bead). A warhead in which the fuse assembly of claim 1 is mounted,
The fuse assembly;
A fuse mount for receiving the fuse assembly and supporting the fuse assembly through the flange portion; And
And a fuse lock to close the fuse mount to secure the fuse assembly with the fuse mount.

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