KR101043308B1 - Method for reducing ranges of test shell, fuse device for reducing ranges and test shell having the same - Google Patents

Abstract

The present invention relates to a method for reducing a range of test shells, a range reducing fuse, and a test shell having the same, wherein the test shell includes a body having an appearance inclined with respect to a central axis, and a fuse coupled to one end of the body. And the fuse includes a drag portion formed at least partially into a circular cross section having a diameter larger than one end of the body, and a coupling portion protruding from the drag portion and formed to be coupled to the body. Thereby, the present invention reduces the firing range of the test shell while maintaining the kinetic characteristics of the test shell at launch.

Shell, fuse, crossroad

Description

METHOD FOR REDUCING RANGES OF TEST SHELL, FUSE DEVICE FOR REDUCING RANGES AND TEST SHELL HAVING THE SAME}

The present invention relates to a method for reducing the firing range of the test shell by increasing the air resistance, a fuse capable of reducing the firing range, and a test shell having the same.

Currently, the shell's performance test site fires at sea as a point of impact, so a wide range of near- and near-by-shore introductions of fishing vessels are necessary.

As a result, complaints from nearby fishermen have been raised, and some of them have failed to introduce marines. In addition, the delayed introduction of the sea makes it difficult to conduct a smooth shooting test, which has a significant impact on the production schedule of the companies concerned.

If the range can be tested at a reduced range, the efficiency of the test can be improved and the complaints from local fishermen can be reduced, but the design and manufacture of new warheads for this is costly and time consuming.

Accordingly, a method of reducing the firing range of the shell may be proposed by using the shell fuse in order to perform an effective shooting test.

One object of the present invention is to provide a method for reducing the range of a test shell, a fuse for reducing the range and a test shell having the same.

Another object of the present invention is to provide a method, a fuse and a test shell having the same while maintaining the kinetic characteristics of the test shell at launch, while reducing the range of the test shell.

In order to achieve one object of the present invention, the test shell according to an embodiment of the present invention includes a body and a fuse. The body has an appearance inclined with respect to the central axis. The fuse is coupled to one end of the body. The fuse includes a drag addition portion and a coupling portion. The drag portion is formed in a circular cross-section with at least a portion having a diameter larger than one end of the body. The engaging portion protrudes from the drag portion and is formed to be engageable with the body. The range reducing fuse according to another embodiment of the present invention is mounted to one end of the body and includes the drag portion and the coupling portion.

According to one aspect of the invention, the drag portion includes a cone portion and a cylindrical portion. The cone portion is formed such that the diameter of the lower portion is larger than the upper portion. The cylindrical portion protrudes from the lower end with the same diameter as the lower end. The coupling portion may include an insertion portion and a stepped portion. The insertion portion is inserted at one end of the body to be coupled to the body. The stepped portion is formed between the insertion portion and the cylindrical portion, and is formed to have a diameter larger than the insertion portion and smaller than the cylindrical portion. The stepped portion may be formed to have the same diameter as one end of the body.

According to another aspect of the invention, the drag portion is provided with a groove along the circumference to increase the resistance of the air. The inclination angle of the drag portion may be formed to be larger than the inclination angle of the portion adjacent to one end of the body.

In addition, the present invention provides a method for reducing the range of the test shell in order to realize the above object. The method for reducing the range of test shells includes selecting a modifier and determining a modifier value. The step of selecting a change factor selects a change factor that changes the shape of the conical fuse. Determining the value of the change factor determines the value of the change factor to increase the resistance of the air.

According to another aspect of the invention, the modifying factor is at least one of the inclination angle and the diameter of the fuse. The inclination angle of the fuse may be set to be larger than the inclination angle of the portion adjacent to one end of the body in which the fuse is mounted.

The range reduction method of the test shell, the range reduction fuse and the test shell having the same according to the present invention configured as described above can reduce the range of the shell by increasing the air resistance to the fuse. This can reduce the area of naval introduction of fishing boats for performance testing of shells.

 In addition, according to the present invention by changing the shape of the fuse can be easily reduced the range of the shell without changing the body. In addition, the kinetic characteristics of the shell can be maintained through this.

Hereinafter, a method for reducing the range of a test shell according to the present invention, a range reducing fuse and a test shell having the same will be described in more detail with reference to the accompanying drawings. In the present specification, the same or similar reference numerals are assigned to the same or similar configurations in different embodiments, and the description thereof is replaced with the first description. As used herein, the singular forms "a", "an" and "the" include plural forms unless the context clearly indicates otherwise.

1 is a conceptual diagram showing a state of testing the performance of the test shell 100 according to an embodiment of the present invention.

Referring to this figure, the performance of the test shell 100 through the sea fire is being tested. The fishing boat 102 outside the firing range 101 of the shell fired at sea may continue to operate, but the fishing vessel 103 in the firing range 101 may be hit by the shell.

The test shell 100 is formed to reduce the firing range 101 of the shell. The test shell 100 includes a body 110 and a fuse 120.

The bullet body 110 has an appearance inclined with respect to the central axis. The body 110 may be, for example, a body of howitzer shells. The fuse 120 is coupled to one end of the body 110, the drag portion 121 is formed in the fuse 120.

The drag portion 121 is formed in a circular cross-section having at least a portion having a larger diameter than one end of the body 110. This results in an increase in fore drag and wake, which are drags acting on the test shell 100 that is fired.

Therefore, the range 101 of the test shell 100 is reduced compared to the case without the drag portion 121.

Figure 2 is a flow chart showing a method for reducing the range of the test shell according to the present invention.

First, a change factor for changing the shape of the fuse is selected (S100).

The change factor may be at least one of an inclination angle and a diameter of the fuse (see FIG. 3 above). The fuse is at least partially formed in a cone shape. In the conical form, the larger diameter portion is referred to as the lower end, and the smaller diameter portion is referred to as the upper end. The fuse is coupled to one end of the body and the lower end is disposed to be adjacent to one end of the body.

Next, to determine the value of the change factor to increase the resistance of the air (S200).

Hereinafter, the step (S200) of determining the value of the change factor will be described by way of example.

The change factor is determined to change the resistance of air (S210).

The diameter of the lower end is set to a value larger in diameter than one end of the carcass. The inclination angle of the fuse is set to be larger than the inclination angle of the portion adjacent to one end of the bullet body to which the fuse is mounted. A range reduction fuse is designed based on the value of the change factor (S220).

Comparing the movement characteristics of the test shell to which the range reduction fuse is applied and the shell to which the fuse was changed before the shape is changed, and compares the degree of reduction of the range with a predetermined standard (S230).

The kinematics of the shell can be of various properties, for example for the main and left locomotion. This can be the retraction of the gun, the round trip time, the return rate, the intraluminal pressure, and so on. The motion characteristics may be intuitively compared by a designer's experience, compared through experiments, or compared through simulation.

The criterion for range reduction may be, for example, about half of the shell to which the fuse was applied before the shape was changed.

If the motion characteristics and the range reduction degree of the shell satisfies a certain condition, it is checked whether the range reduction fuse with increased air resistance is destroyed during flight (S240). For example, calculate the maximum resistivity of air generated in a range reducing fuse and perform a fracture test of the range reducing fuse above the maximum resistance.

If the range reduction fuse is not destroyed against the maximum resistance, the value of the change factor at that time is determined as the design value of the range reduction fuse (S250).

Hereinafter, a test shell and a range reduction fuse related to the present invention to which the method for reducing the range of the test shell can be applied will be described.

3 is a plan view illustrating the test shell 100 of FIG. 1, and FIG. 4 is a perspective view illustrating the fuse 120 of FIG. 3.

The drag portion 121 is formed in the fuse 120, and the material of the fuse 120 may be, for example, aluminum.

The drag portion 121 includes a cone portion 121a and a cylindrical portion 121b. The cone portion 121a is formed to have a larger diameter at the lower end than the upper end. The cylindrical portion 121b protrudes from the lower end with the same diameter as the lower end.

The engaging portion 122 protrudes from the drag portion 121. Coupling portion 122 is formed to be coupled to the body body 110. One end of the body 110 is formed in a hollow so that the fuse is inserted.

Coupling portion 122 includes an insertion portion 122a and a stepped portion 122b.

The insertion part 122a is inserted into one end of the body 110 to be coupled to the body 110. Threads corresponding to each other may be formed in the insertion portion 122a and the hollow portion for coupling.

The stepped portion 122b is formed between the insertion portion 122a and the cylindrical portion 121b. The stepped portion 122b is formed to have a diameter d greater than the diameter t of the insertion portion 122a and smaller than the diameter D of the cylindrical portion 121b. The stepped part 122b may be formed to have the same diameter d as one end of the body 110. Through this, the fuse 120 having a changed shape may be more firmly coupled to the body 110.

As shown in FIG. 3, the inclination angle θ of the drag portion 121 may be a cone angle in the form of a cone. An inclination angle α of a portion adjacent to one end of the body 110 may be an obviated angle formed by the body 110 before the shape is changed.

The drag portion 121 is formed such that the inclination angle θ is greater than the inclination angle α of the portion adjacent to the one end of the carbon body 110. Through this, by increasing the air resistance in the fuse 120 can be reduced the range of the test shell 100. In addition, since there is no change in the body 110, the movement characteristics of the test shell 100 may be maintained.

5 is a graph comparing the movement characteristics of the shell equipped with the range reduction fuse Rd according to the present invention with the shell equipped with the simulation fuse K519.

A simulated fuse K519 refers to a model that simulates a fuse of a shell having no shape change. Referring to this graph, it can be seen that the shell equipped with the range reduction fuse (Rd) shows a graph similar to the shell equipped with the simulation fuse (K519), and the range is decreased.

6 is a perspective view of a fuse 220 according to another embodiment of the present invention.

Referring to this figure, the drag portion 221 is formed with a groove 221c along the circumference to increase the resistance of the air. The groove 221c may be formed in plural. The groove 221c may be formed in the cylindrical portion 221b, for example.

A ring may be coupled to the groove 221c to further increase the resistance of the air. Through this, the fuse 220 is to form a predetermined range to reduce the range of the shell. The absence of engagement of the ring is the maximum range, and the engagement of the most rings is the minimum range.

The range reduction method of the test shell, the range reduction fuse and the test shell having the same according to the present invention as described above are not limited to the configuration and method of the embodiments described above, the embodiments are to be modified in various ways All or some of the embodiments may be optionally combined.

1 is a conceptual diagram showing a state of testing the performance of a test shell according to an embodiment of the present invention.

Figure 2 is a flow chart showing a method for reducing the range of the test shell according to the present invention.

3 is a plan view showing a test shell of FIG.

4 is a perspective view illustrating the fuse of FIG. 3;

5 is a graph comparing the movement characteristics of the shell equipped with a range reduction fuse according to the present invention with a shell equipped with a simulated fuse.

6 is a perspective view of a test shell according to another embodiment of the present invention.

Claims (10)

A bullet body having an exterior inclined with respect to the central axis; And A fuse coupled to one end of the body, The fuse is, A drag portion having at least a portion formed into a circular cross section having a diameter larger than one end of the carbon body; And Protruding from the drag portion, and includes a coupling portion formed to be coupled to the body, The drag addition portion A cone portion formed to have a larger diameter at the lower portion than the upper portion; And And a cylindrical portion protruding from the lower end with the same diameter as the lower end, The cylindrical portion has a plurality of grooves are formed along the circumference to increase the resistance of the air, the test shell, characterized in that the ring is coupled to at least one of the plurality of grooves. delete The method of claim 1, The coupling part An insertion part inserted into one end of the body to be coupled to the body; And A test shell formed between the insertion portion and the cylindrical portion, the test shell including a stepped portion having a diameter larger than the insertion portion and smaller than the cylindrical portion. The method of claim 3, The stepped portion is a test shell, characterized in that formed to have the same diameter as one end of the body. delete The method of claim 1, The drag portion is a test shell, characterized in that the inclination angle is formed to be larger than the inclination angle of the portion adjacent to one end of the body. In the fuse attached to one end of the body, A drag portion having at least a portion formed into a circular cross section having a diameter larger than one end of the carbon body; And Protruding from the drag portion, and includes a coupling portion formed to be coupled to the body, The drag addition portion A cone portion formed to have a larger diameter at the lower portion than the upper portion; And And a cylindrical portion protruding from the lower end with the same diameter as the lower end, The cylindrical portion has a plurality of grooves are formed along the circumference to increase the resistance of the air, at least one of the plurality of grooves, the range reduction fuse, characterized in that the coupling is coupled. Selecting a change factor for changing the shape of the fuse; And Determining the value of the modifier to increase resistance of air; The fuse is, A drag portion having at least a portion formed into a circular cross section having a diameter larger than one end of the body of the test shell; And Protruding from the drag portion, and includes a coupling portion formed to be coupled to the body, The drag addition portion A cone portion formed to have a larger diameter at the lower portion than the upper portion; And And a cylindrical portion protruding from the lower end with the same diameter as the lower end, The cylindrical portion is formed with a plurality of grooves along the circumference to increase the resistance of the air, a ring is coupled to at least one of the plurality of grooves, And said modifier is at least one of an inclination angle of said cone portion and a diameter of said cylindrical portion. delete The method of claim 8, The inclination angle of the fuse is larger than the inclination angle of the portion adjacent to one end of the bullet body to which the fuse is mounted, the method for reducing the firing range of the test shell.

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