JPH04139394A - Ignition device for missile launching device - Google Patents

Abstract

PURPOSE:To enable a safe launching of a missile to be carried out by a method wherein an adjusting member communicating with a combustion chamber and an ignition chamber is formed between these chambers, and both the combustion chamber and a fuel chamber are pressurized by a combustion gas pressure when the fuel is injected. CONSTITUTION:After a specified amount of ignition fuel is supplied into an ignition chamber 10 through a fuel passage 18, the fuel passage 18 is closed. Then, a switch 12 is closed, electrodes 14 and 20 are electrically energized, an arc is generated within the ignition chamber 10, resulting in that the ignition fuel within the ignition chamber 10 is heated by an arc and a part of the fuel is ignited to form gas, an interior part of the ignition chamber 10 is increased up to its high temperature and at the same time a pressure within it is increased. With such an arrangement, ignition fuel not gasified within the ignition chamber 10 is ignited in a chain-reaction manner and gasified, and then combustion gas of high temperature and high pressure passes through a fixed adjusting part 16 and then the combustion gas is injected into a combustion chamber 40. An injection piston 32 is pushed by a pressure of the combustion gas in a rightward direction as viewed in the figure, liquid fuel 44 within a fuel chamber 42 passes through a nozzle 46, is pushed into the combustion chamber 40 and explosively ignited. With such an operation, a large amount of combustion gas is generated and a missile 38 is launched at a high speed from a canon while being pushed by this gas pressure.

Description

[Detailed Description of the Invention] (a) Industrial Application The present invention is a liquid #? This invention relates to an ignition device for a projectile launcher that launches a projectile using the combustion gas pressure obtained by burning a fuel.

(b) Prior Art A conventional flywheel launcher is shown in FIG. The flying object launcher includes a cylindrical gun barrel 30, a jet q/↑ piston 32 attached to the inner diameter of the barrel, an ignition chamber 33 provided in the gun barrel 30, and an ignition device in the ignition chamber 33. fuel 45
an ignition device 34 that ignites the combustion chamber 40 and the ignition chamber 33;
It has a pressurizing device 36 that applies pressure to. gun barrel 3
A combustion chamber 40 is formed by the inner diameter of the gun, the injection piston 32, and the projectile 38 loaded in the gun barrel 30. The ignition chamber 33 and the combustion chamber 40 are always in communication.

The space on the side opposite to the combustion chamber 40 side of the injection piston 32 is
This is a fuel chamber 42, and this space is filled with liquid fuel 44. The injection piston 32 is provided with a nozzle 46 that communicates the combustion chamber 40 and the fuel chamber 42 . The pressure is applied from the pressurizing device 36 to the ignition fuel 4 in the ignition chamber 33.
When the ignition fuel 45 in the ignition chamber 33 is ignited by the ignition device 34 that pressurizes the fuel 5, combustion gas is generated, and this pressure pushes the injection piston 32, causing the fuel chamber 4 to ignite.
The liquid fuel 44 in the combustion chamber 2 is pushed out through the nozzle 46 into the combustion chamber 40 and explodes and burns. As a result, a large amount of combustion gas is generated5, the projectile 38 is accelerated, and the projectile 38 is ejected from the gun cavity at high speed.

(c) Problems to be Solved by the Invention As shown in FIG. 8, the greater the pressure P applied to the ignition fuel 45, the smaller the energy E required for ignition. things are being done. However, in a conventional projectile launcher such as the one described in ``2'', it is necessary to pressurize the entire combustion chamber 40 as well as the ignition chamber 33. For this reason, from the pressurizing device 36 to the combustion chamber 4
When pressure is applied inside o, there is a possibility that the flying object 38 may be pushed out, which poses a safety problem. Moreover, since the combustion chamber 4o is pressurized before igniting the ignition fuel 45, there is a possibility that the injection piston 32 will start moving due to this pressure. Furthermore, since the combustion chamber 40, which has a large volume, is pressurized, it takes time to pressurize it, and if the number of firings cannot be increased, the N point will occur. The present invention aims to solve these problems.

(d) Means for Solving the Problems The present invention solves the above problems by forming an aperture between the combustion chamber and the ignition chamber, which communicates the compartments. That is, the present invention provides an ignition system for a projectile launcher that has an ignition chamber (1o) and introduces combustion gas generated in the ignition chamber (1o) into the combustion chamber (40) of the gun barrel (30). The ignition chamber (10) includes a cylindrical electrode (14) having an inner diameter, and a rod 11E pole (2o) arranged concentrically at intervals on the inner diameter of the cylindrical electrode (14). , both electrodes (14・
20) It is composed of a cylindrical insulator (22) that insulates between the cylinders and positions the stiffness.
The I pole (14) includes a throttle (16) that communicates the ignition chamber (10) with the above-mentioned combustion chamber (40), and an ignition chamber (10).
A fuel passageway (18) capable of supplying ignition fuel to
) and are formed.

In addition, when a gas pressure of a predetermined level or higher is generated in the ignition chamber (10), a buffer member (25) is provided that can move the insulator (22) in the direction of expanding the volume of the ignition chamber by this gas pressure.
It is recommended to provide a

In addition, a cylindrical electrode (54) is located adjacent to the first ignition chamber (50).
) and the insulator (58), thereby forming a buffer chamber (60), and the insulator (58) includes a flow path (6o) that communicates the ignition chamber (50) with the buffer chamber (6o). 72) is preferably formed.

Furthermore, it is preferable to provide a buffer piston (62) that fits into the buffer chamber (60) and a spring (64) that pushes this toward the ignition chamber (5o).

Further, in the ignition device for a projectile launcher according to claim 5 of the present invention, the ignition chamber (5o) is spaced concentrically from the cylindrical electrode (54) having an inner diameter portion and the inner diameter portion of the cylindrical electrode (54). It is composed of a rod electrode (56) arranged and a piston (62) fitted in both (54) and movable in a direction to increase or decrease the volume of the ignition chamber (5o), and a cylindrical electrode ( 54) includes the ignition chamber (50) and the #Am chamber (4).
A throttle (68) communicating with the piston (62) and a fuel passageway (70) capable of supplying ignition fuel to the ignition chamber (50) are formed. 5o
) A spring (64) is provided which pushes in the direction of volume reduction. Note that the symbols in parentheses indicate corresponding members in the embodiments described later.

(E) Operation A predetermined amount of ignition fuel is supplied into the ignition chamber from the ignition fuel supply flow path, and the ignition mechanism is operated to generate an arc.

As a result, the ignition fuel in the portion of the ignition chamber heated by the arc becomes a high-temperature combustion gas, increasing the pressure and temperature within the ignition chamber. As a result, the remaining ignition fuel in the ignition chamber is combusted in a chain reaction, and this combustion gas is guided into the combustion chamber of the gun barrel through the throttle. As a result, the fuel in the combustion chamber is pressurized and ignited, causing explosive combustion, and combustion gas is injected toward the rear end of the projectile contained in the gun barrel, causing the projectile to be launched from the gun barrel at high speed. be done. By supplying a predetermined amount of ignition fuel into the ignition chamber from the ignition fuel supply port again, it becomes possible to prepare the ignition for the primary projectile launch.

By providing a buffer chamber communicating with the ignition chamber (or 5. providing a buffer member linked to the ignition chamber), the combustion speed of the ignition fuel in the ignition chamber is too fast, and the pressure inside the ignition chamber is higher than the set value. When this occurs, part of this pressure can be released into the buffer chamber, thereby preventing the interior of the ignition chamber from being exposed to abnormally high pressure.

(F) Embodiment FIG. 1 shows a first embodiment of the present invention. A rod electrode 20 is arranged concentrically on the inner diameter of one end of the cylindrical electrode 14, and insulators 22 and 24 hold the rod electrode 20 insulated from the simple electrode 14. The insulator 22 on the upper side in FIG. 6 is made of a highly elastic material such as nylon 66, for example. The insulator 24 on the lower side of the figure is made of a material with excellent impact resistance, such as FRP (fiber reinforced resin).

A stepped cylindrical screw member 26 is screwed to the lower end of the cylindrical electrode I4, and thereby the insulator 22 and the rod electrode 2
0 and the insulator 24 are positioned and fixed to the cylindrical electrode 14 in this order. Cylindrical electrode I4, rod electrode 20 and insulator 2
2 forms an ignition chamber 10. A narrow fixed throttle 16 is formed in the cylindrical part of the cylinder electrode 14 located at the upper side in the figure of the ignition chamber 1o. It communicates with room 40. A fuel passage 18 is formed in the cylindrical electrode 14, which penetrates from the outer circumferential portion of the cylindrical electrode 14 to the ignition chamber 1o. Fuel passage 1 from an ignition fuel supply device (not shown)
It is possible to supply ignition fuel into the ignition chamber 10 through the ignition chamber 8 . The switch 12 and the electric! The end of the six-cylinder electrode 14 to which the electrode 13 is connected is fixed to the gun barrel 30 so as to face the combustion chamber 4o thereof. A projectile object 38 can be loaded into the gun cavity of the gun barrel 3o. An injection screw 1-632 is fitted into the inner diameter of the gun barrel 3o. The space defined by the rear end I4 of the flying body 38 in the gun M30, and the inner diameter part of the gun zl 30, by the left end of the injection piston 32 in the figure. A combustion chamber 40 is formed therein.
A fuel chamber 42 is formed by a space on the right side of the injection piston 32, which is opposite to the fuel oil. The combustion chamber 40 and the fuel chamber 42 are provided with 32 injection pistons and communicate with each other through a knee nozzle 46. The fuel chamber 42 can be filled with liquid fuel 44.

Next, let us explain about the operation of this first embodiment.

Fuel passage 18 from the ignition fuel supply device (not shown)
supplying a predetermined amount of ignition fuel into the ignition chamber 10 through the
The stop valve of the fuel supply device for the 7th ton fire is closed to close the fuel passage 18. Next, in this state, the switch 12 is closed, and both electrodes 14 and 20 are energized to generate an arc within the ignition chamber 10. As a result, the ignition fuel in the ignition chamber 10 is heated by the arc, and a part of it is combusted and gasified, and the temperature and pressure in the ignition chamber 10 increase. This causes the ignition fuel in the ignition chamber 10 that has not turned into a bush to form a chain reaction! This high-temperature, high-pressure combustion gas passes through the fixed throttle 16 and is injected into the combustion chamber 40. Pushed by the pressure of the NFF1 combustion gas, the injection piston 32 moves to the right in the figure. , the liquid fuel 44 in the fuel chamber 42 is forced out through the nozzle 46 into the combustion chamber 40 and explodes and burns. This generates a large amount of combustion gas, which is pushed by the pressure of the gas and causes the The gun body 38 is fired from the gun barrel at high speed. After firing, open the stop valve of the ignition fuel supply device (not shown) and fill the ignition chamber 10 in the same manner as described above.
FIG. 2 shows a second embodiment of the ignition system of the present invention. A ring-shaped buffer member 25 is provided between the insulator 24 and the screw member 27. The volume of the buffer member 25 is reduced by receiving a compressive force of a predetermined magnitude or more, and the compressive force is removed. It is made of a material such as acrylic resin that has the property of restoring to its original volume. The rest of the configuration is the same as that of the first embodiment k).

The function of this second embodiment is that the ignition chamber lO is used for ignition.
When ignited, the calcination rate was too high and the ignition chamber [
0 (J) When the combustion gas IT force becomes larger than a predetermined value, the volume of the buffer member 25 decreases, causing the insulator 22, 24 and the rod electrode 20 to move in the direction of the figure, causing the ignition chamber lO( The operation is similar to that of the first embodiment, except that the volume 'D is temporarily increased by I to reduce the gas pressure.

Figures 3 and 4 show a third embodiment of the ignition device of the present invention.
As in the case of the first embodiment, a cylindrical electrode 54 and a rod electrode 56 are arranged concentrically with an interval between them, and a cylindrical insulator 58 is arranged between them. Cylindrical electrode 54, rod [
The ignition chamber 50 is formed by the pole 56 and the insulator 581Y.The cylindrical portion of the cylindrical electrode 54 located on the upper side in the figure of 6 ignition ¥50 has a narrow fixed throttle 68 formed therein, and the ignition chamber 50 is A fixed aperture (through 313) is connected to the combustion chamber 4 ( ) of the gun barrel 30 at the upper part of the figure. A fuel passage 70 having a width of 1" is formed in the ignition chamber 50 through the ignition chamber 54.Ignition fuel can be supplied into the ignition chamber 50 through the fuel passage 70 from an ignition fuel supply device (not shown). It is possible.A buffer chamber 60 is formed on the right side of the cylindrical electrode 54 in the figure, and is divided into a voice and a firebox 50 by an insulator 58. The buffer chamber 60 communicates with the ignition chamber 50 through the through hole 72 ).

The operation of the third embodiment is such that when the gas pressure in the ignition chamber 50 reaches a predetermined amount -F, the combustion gas in the ignition chamber 50 flows into the buffer chamber 60 through the through hole 72, and the combustion gas in the ignition chamber 50 flows into the buffer chamber 60. This embodiment is almost the same as that of the first embodiment except that the gas pressure is lowered below a predetermined value.

FIG. 5 shows a fourth embodiment of the ignition device of the present invention. A buffer piston 62 is fitted into a buffer chamber 60 so as to be movable in the left-right direction in the figure, and has a force-pushing action to push it leftward in the figure. A spring 64 is provided in the buffer chamber 60. , the buffer chamber 60 is connected to the ignition chamber 5 by the compression piston 62.
0, and by moving the buffer piston 62 rightward in the figure, the volume of the ignition chamber 5o becomes thicker.

The function of this fourth embodiment is that while the gas pressure in the ignition chamber 50 is less than a predetermined value, the volume of the ignition chamber 50 is constant, and when the gas pressure in the ignition chamber 50 exceeds a predetermined value, the volume of the ignition chamber 50 is constant. The second embodiment is the same as the first embodiment except that the volume is increased to lower the gas pressure.

FIG. 6 shows a fifth embodiment of the ignition device of the present invention. In this embodiment, in the third embodiment shown in FIG.
0, a buffer piston 62 and a spring 64 are provided in the same way as in the fourth embodiment shown in FIG.

The operation of the fifth embodiment is almost the same as that of the third embodiment, but while the gas pressure in the ignition chamber 50 is less than a predetermined value,
It is possible to reliably prevent combustion gas from entering the buffer chamber 60, and when the buffer piston 62 moves from side to side, the throttling effect of the through hole 72 prevents vibration and allows smooth operation. , there is one.

(G) As described in detail, according to the present invention, by burning the ignition fuel in the ignition chamber with a small volume, the ignition chamber can be heated to a high temperature and pressurized. The ignition fuel is combusted in a chain reaction, and the high-temperature, high-pressure combustion gas generated in this way is guided into the combustion chamber, so that the combustion chamber and fuel chamber are filled with combustion gas only during fuel injection. The air is pressurized by pressure, and the flying object and injection piston do not move before the combustion gas is introduced, allowing the flying object to be launched safely.The ignition chamber and combustion chamber are pressurized before ignition. Since there is no need for pressurization, there is no need for time to pressurize, and the firing interval of the projectile can be shortened.Since a pressurization device is not required,
The structure of the ignition device becomes simple and can be made small.

[Brief explanation of drawings]

FIG. 1 is a diagram showing a first embodiment of the ignition device of the present invention, and FIG.
The figure shows a second embodiment of the ignition device of the present invention, FIG. 3 shows a third embodiment of the ignition device of the present invention, and FIG. 4 is a cross section taken along the rV-rV line in FIG. 5 shows a fourth embodiment of the ignition device of the present invention, FIG. 6 shows a fifth embodiment of the ignition device of the present invention, and FIG. 7 shows a conventional projectile launcher. The diagram shown in FIG. 8 is a diagram showing the relationship between the pressure applied to the ignition fuel and the energy required for ignition. DESCRIPTION OF SYMBOLS 10... Ignition chamber, 12... Switch, 14... Cylindrical electrode, 16... Throttle, 18... Fuel passage, 2o... Rod electrode. 22・24...Insulator, 25...Buffer member, 26...
27... Screw member, 3o... Gun barrel, 38... Projectile object, 40... Combustion chamber. 50... Ignition chamber, 54... Cylindrical electrode, 56... Rod electrode, 58... Insulator, 60... Buffer chamber, 62...
Buffer piston, 64... Spring, 68... Throttle, 70... Fuel passage. fig fig fig fig fig fig fig fig fig fig fig fig fig fig fig.

Claims (1)

[Claims] 1. An ignition device for a projectile launcher that sends combustion gas generated by igniting and burning ignition fuel in an ignition chamber (10) into a combustion chamber (40) of a gun barrel (30). In the ignition chamber (10), the cylindrical electrode (14) has an inner diameter portion.
, rod electrodes (20) arranged concentrically at intervals on the inner diameter thereof, and a cylindrical insulator (22) that insulates between the two electrodes (14, 20) and positions them. The cylindrical electrode (14) has an ignition chamber (
10) and the combustion chamber (40) are connected to each other.
An ignition device for a projectile launcher, characterized in that: and a fuel passageway (18) capable of supplying ignition fuel to the ignition chamber (10). 2. A buffer member (25) is provided which can move the insulator (22) in the direction of expanding the volume of the ignition chamber by the gas pressure when a gas pressure of a predetermined level or more is generated in the ignition chamber (10). The ignition device for a projectile launcher according to claim 1. 3. A cylindrical electrode (54) is placed adjacent to the ignition chamber (50).
A buffer chamber (60) is formed by the insulator (58) and the insulator (58), and the insulator (58) has a flow path (72) that communicates the ignition chamber (50) and the buffer chamber (60). An ignition device for a projectile launcher according to claim 1 or 2, wherein the ignition device is formed as follows. 4. Buffer piston (6) fitted into buffer chamber (60)
2) and a spring (6) that pushes it toward the ignition chamber (50).
4) The ignition device for a projectile launcher according to claim 1, 2 or 3, wherein the ignition device is provided with: 4). 5. In an ignition device for a projectile launcher that sends combustion gas generated by igniting and burning ignition fuel in an ignition chamber (50) into a combustion chamber (40) of a gun barrel (30), the ignition chamber ( 50) is a cylindrical electrode (54) having an inner diameter part.
, a rod electrode (56) arranged concentrically at intervals on the inner diameter thereof, a cylindrical insulator (58) that insulates between the two electrodes (54, 56) and positions them; A piston (62) fitted into the electrode (54) and movable in a direction to increase or decrease the volume of the ignition chamber (50).
The cylindrical electrode (54) includes a throttle (54) that communicates the ignition chamber (50) with the combustion chamber (40).
68) and a fuel passage (70) capable of supplying ignition fuel to the ignition chamber (50), and a spring that pushes the piston (62) in the direction of decreasing the volume of the ignition chamber (50). (64) An ignition device for a projectile launcher equipped with.