Gas balance training bomb

Abstract

A gas balance training bomb uses primarily a pressure of gas to substitute a gunpowder explosion to generate a gas thrust for pushing an eruption solid, powder, gas or liquid, so as to achieve an effect of simulating an explosion. The gas balance training bomb is formed with a passive gas chamber and an active gas chamber, the passive gas chamber stores the gas needed upon erupting and the active gas chamber stores the gas used for controlling an eruption time. Through the pressure difference between the active gas chamber and the passive gas chamber, the gas stored in the passive gas chamber is released momentarily to accomplish an operation of eruption, such that the effect of simulating the explosion can be achieved.

Description

BACKGROUND OF THE INVENTION

a) Field of the Invention

The present invention relates to a gas balance training bomb, and more particularly to a gas balance training bomb which uses primarily a pressure of natural gas to substitute a gunpowder explosion to generate a gas thrust to push an eruption solid, powder, gas or liquid, thereby achieving an effect of simulating an explosion, being able to be used in training military personnel or policemen, entertaining or simulating the explosion, as well as being used very safely.

b) Description of the Prior Art

Most of existing training bombs for training military personnel or policemen or simulating an explosion are filled with gunpowder of a smaller explosion power or natural gas, especially the gunpowder of smaller explosion power. These training bombs are more expensive and relatively more dangerous. In addition, when the gunpowder explodes, the training bomb cannot be used again. Therefore, for a training institute, these training bombs will be a kind of training equipment of high cost.

On the other hand, almost all the existing gas-filled training bombs have only an effect of one-way eruption; that is, the eruption can be only occurring at the most front end of the training bomb. However, for the training institute, the simulation effect will be very poor and a real experience cannot be achieved. Furthermore, although the existing gas-filled training bombs can be recycled for use, their parts are mostly distributed, allowing the parts to be dropped everywhere after being used, thereby causing trouble in recycling.

Moreover, for the aforementioned training bomb whether being filled with the gunpowder or gas, its eruption time cannot be adjusted according to a user's requirement, which causes inconvenience in use.

Accordingly, how to improve the aforementioned problems is a technological issue to be solved by the present invention.

SUMMARY OF THE INVENTION

The primary object of the present invention is to provide a gas balance training bomb which is extremely safe in use and can truly simulate an explosion.

Accordingly, the gas balance training bomb of the present invention is primarily formed with a passive gas chamber and an active gas chamber, wherein the passive gas chamber is used to store gas needed upon erupting, and the active gas chamber stores gas which is used for controlling an eruption time, such that through a pressure difference between the active gas chamber and the passive gas chamber, the gas that is stored in the passive gas chamber is released momentarily to accomplish the eruption operation, thereby achieving an effect of simulating the explosion.

The gas balance training bomb of the present invention includes primarily an outer casing, an interior of which is provided with an inner tube sheath, a gas guiding assembly, an inner sleeve, a piston and a gas storage cylinder, wherein a tube wall of a tube unit of the outer casing is provided with a plurality of gas discharge holes, with each gas discharge hole being installed with an eruption material that can be a solid, powder or liquid.

The inner sleeve is a hollow tube unit, a tube wall of which is provided with a plurality of through-holes; whereas, the inner tube sheath and the gas storage cylinder are provided respectively at two ends of the inner sleeve, and constitute a gas storage space with the inner sleeve. The piston is provided in the inner sleeve to separate the gas storage space into the active gas chamber and the passive gas chamber, and the gas guiding assembly is transfixed into the inner tube sheath, with one end being protruded at an exterior of the tube unit, and the other end being abutted on the piston, such that gas can be flooded from the gas guiding assembly that is protruded at the exterior of the tube unit into the gas storage space inside the tube unit to completely fill the active gas chamber and the passive gas chamber and to keep the piston at a balance state.

Upon operating, the gas of the active gas chamber is released first, so as to constitute an imbalance state to the gas pressure between the active gas chamber and the passive gas chamber; that is, the gas pressure of the passive gas chamber is larger than that of the active gas chamber, which in turn pushes the piston, allowing a residual pressure in the active gas chamber to push off the piston to pass through the inner sleeve, and the residual pressures of the passive gas chamber and the active gas chamber to be expelled out through the gas discharged holes on the tube unit at a same time. At this time, the eruption materials installed in the gas discharge holes will be driven by the gas pressure in the active gas chamber to erupt out, thereby achieving an effect of simulating the explosion.

Another object of the present invention is to provide a gas balance training bomb, wherein an eruption time of the entire gas balance training bomb can be controlled. When the gas balance training bomb is filled, the gas is primarily filled into the interior of the training bomb, allowing the gas pressures in the active gas chamber and the passive gas chamber to be balanced. Therefore, the gas pressure in the passive gas chamber becomes a key factor for controlling the eruption of the active gas chamber; that is, the larger the gas pressure of the passive gas chamber is, the longer the eruption time will be; on the other hand, the smaller the gas pressure of the passive gas chamber is, the shorter the eruption time will be. Accordingly, the gas pressure in the passive gas chamber can be adjusted according to training sites.

Still another object of the present invention is to provide a gas balance training bomb which can be recycled for filling repeatedly. As upon erupting, the internal piston is operated only by using the gas pressure difference, each part will not be dropped everywhere. Therefore, the parts can be recycled for filling after simulating the explosion, thereby being able to be used repeatedly.

To enable a further understanding of the said objectives and the technological methods of the invention herein, the brief description of the drawings below is followed by the detailed description of the preferred embodiments.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows a perspective view of the present invention.

FIG. 2 shows an exploded view of the present invention.

FIG. 3 shows a cutaway view of the present invention.

FIG. 4 shows a local exploded view of FIG. 3.

FIG. 5 shows a cutaway view of a first operation of the present invention.

FIG. 6 shows a cutaway view of a second operation of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Referring to FIG. 1 and FIG. 2, it shows a perspective view and an exploded view of a gas balance training bomb of the present invention, which comprises primarily an outer casing 10, an interior of which is in a hollow shape and is provided with an inner tube sheath 20, a gas guiding assembly 30, an inner sleeve 40, a piston 50 and a gas storage cylinder 60. In the present invention, the outer casing 10 is further constituted by a tube unit 11 and a cover unit 12, wherein the tube unit 11 is a hollow tube and is covered by the cover unit 12 to form an emplacement space in the outer casing 10, further enabling the inner tube sheath 20, the gas guiding assembly 30, the inner sleeve 40, the piston 50 and the gas storage cylinder 60 to be assembled in the emplacement space orderly. A tube wall of the tube unit 11 is provided with a plurality of gas discharge holes 13, a tube wall of the inner sleeve 40 is provided additionally with a plurality of through-holes 41, and the gas guiding assembly 30 is further composed of a nozzle 31, a guide tube 32 and a gas choking tube 33; whereas, a front end at an exterior of the outer casing 10 is further disposed with a head member 14.

Referring to FIG. 2 and FIG. 3, it shows respectively an exploded view and a cutaway view of the present invention. In assembling, the inner tube sheath 20 and the inner sleeve 40 are emplaced respectively in an interior of the tube unit 11 of the outer casing 10, such that the inner sleeve 40 is sheathed on the inner tube sheath 20 and then the gas guiding assembly 30 is orderly emplaced inside the inner tube sheath 20, allowing the guide tube 32 of the gas guiding assembly 30 to pass through the inner tube sheath 20 and the head member 14 and to protrude out of the head member 14. On the other hand, the nozzle 31 is sheathed at the guide tube 32 and is protruded at an end of an exterior of the head member 14, the gas choking tube 33 is installed on the piston 50 and the piston 50 is emplaced inside the inner sleeve 40. Finally, the gas storage cylinder 60 is emplaced inside the tube unit 11, and constitutes a gas storage space with the inner tube sheath 20 and the inner sleeve 40, with the gas storage space being separated into an active gas chamber 70 and a passive gas chamber 80 through the piston 50. In addition, each gas discharge hole 13 on the tube wall of the tube unit 11 is used for installing an eruption material (not shown in the drawings) which can be a solid, powder or liquid.

Accordingly, after the entire gas balance training bomb has been assembled, the gas can be filled into the training bomb through the nozzle 31 that is exposed, enabling the gas to pass through the gas guiding assembly 30 to be stored between the active gas chamber 70 and the passive gas chamber 80, with a flow route of the gas shown as arrows in the drawings. Therefore, the gas pressure between the active gas chamber 70 and the passive gas chamber 80 will be balanced, allowing the piston 50 to keep at a balance position. In the present invention, the filling gas is the natural gas.

Referring to FIG. 4, it shows a local exploded view of the present invention. When assembling the guide tube 32 and the gas choking tube 33 of the gas guiding assembly 30, a proper gap is provided between the guide tube 32 and the gas choking tube 33; therefore, when the gas is filled into the active gas chamber 70 and the passive gas chamber 80 through the nozzle 31, the gas can be guided into the passive gas chamber 80 by the gap between the guide tube 32 and the gas choking tube 33. In a mean time, a part of the gas will be guided into the active gas chamber 70 through the gas choking tube 33, further achieving the gas pressure balance between the active gas chamber 70 and the passive gas chamber 80, such that the piston 50 is abutted at an exterior of the gas storage cylinder 60, enabling the active gas chamber 70 to form a sealed condition, thereby being able to store the gas.

Referring to FIG. 5, it shows a cutaway view of a first operation of the present invention. In using the gas balance training bomb of the present invention, the gas in the passive gas chamber 80 should be released first, which is reached primarily by the head member 14. When the gas of the passive gas chamber 80 is released, due to an operation of the gas pressure, the guide tube 32 will be pushed outward by the gas pressure, further enabling the gas inside the passive gas chamber 80 to be expelled outward through the guide tube 32.

Referring to FIG. 6, it shows a cutaway view of a second operation of the present invention. After the gas of the passive gas chamber 80 has been released, a pressure difference will be resulted between the active gas chamber 70 and the passive gas chamber 80; that is, the gas pressure inside the active gas chamber 70 is larger than that inside the passive gas chamber 80, further enabling the gas pressure inside the active gas chamber 70 to push the piston 50, such that the piston 50 is moving in the inner sleeve 40 toward the passive gas chamber 80 to result in a proper distance between the piston 50 and the gas storage cylinder 60, further enabling the gas inside the active gas chamber 70 to be released outward and expelled outward through the through-holes 41 on the inner sleeve 40.

At this time, the gas inside the active gas chamber 70 will enter into the emplacement space of the outer casing 10. As the tube wall of the tube unit 11 is provided with the plurality of gas discharge holes 13, and each gas discharge hole 13 is disposed with the eruption material, therefore, after the gas has entered into the outer casing 10, the gas will pass through the gas discharge holes 13 on the tube wall of the tube unit 11, and be expelled outward (along a direction pointed by the arrows in the drawings). Accordingly, at a same time when the gas is expelled out, the eruption materials on the gas discharge holes 13 will be expelled out too, thereby achieving an effect of simulating an explosion.

In addition, referring to FIG. 4, when the gas balance training bomb of the present invention is filled with the gas, the gas is especially guided into a place between the active gas chamber 70 and the passive gas chamber 80 through the guide tube 32 from the nozzle 31. Therefore, during the process of filling the gas, if the passive gas chamber 80 is given a larger gas pressure, then the gas pressure inside the passive gas chamber 80 will be larger than that inside the active gas chamber 70, thereby delaying an eruption time of the active gas chamber 70. On the contrary, if during the process of filling the gas, the passive gas chamber 80 is given a smaller gas pressure, then the gas pressure of the passive gas chamber 80 will be smaller than that of the active gas chamber 70, thereby accelerating the eruption time of the active gas chamber 70. Accordingly, the eruption time can be adjusted according to a user's requirement.

Furthermore, when the present invention is operating, the effect of simulating the explosion is achieved primarily by using the gas pressure difference between the active gas chamber 70 and the passive gas chamber 80. Therefore, an operation of each part is conducted inside the outer casing 10, and during the process of simulating the explosion, the parts will not be dropped everywhere. Accordingly, in addition to adding a safety in use, the effect of recycling to refill the gas can be achieved as well.

It is of course to be understood that the embodiments described herein is merely illustrative of the principles of the invention and that a wide variety of modifications thereto may be effected by persons skilled in the art without departing from the spirit and scope of the invention as set forth in the following claims.

Claims

1. A gas balance training bomb comprising an outer casing, an interior of which is provided with an emplacement space and a wall of which is provided with a plurality of gas discharge holes; an inner tube sheath which is provided at a front end of the emplacement space inside the outer casing; an inner sleeve, which is provided inside the outer casing, an end of which is connected with the inner tube sheath and a wall of which is provided with a plurality of through-holes; a gas storage cylinder, which is provided inside the outer casing, is connected with the other end of the inner sleeve and constitutes a gas storage space with the inner tube sheath and the inner sleeve; a piston, which is provided inside the inner sleeve to separate the gas storage space into an active gas chamber and a passive gas chamber; and a gas guiding assembly, which passes orderly through the inner tube sheath and the inner sleeve and an end of which is protruded out of the outer casing to fill gas into the active gas chamber and the passive gas chamber, enabling the active gas chamber and the passive gas chamber to achieve a state of gas pressure balance.

2. The gas balance training bomb according to claim 1, wherein the outer casing is further composed of a tube unit and a cove unit, with the tube unit being a hollow tube and the gas discharge holes being provided on the tube unit; an interior of the outer casing being formed as an emplacement space by covering the outer casing with the cover unit.

3. The gas balance training bomb according to claim 2 wherein a front end of the outer casing is further provided with a head member.

4. The gas balance training bomb according to claim 1, wherein the gas discharge holes are installed with eruption materials.

5. The gas balance training bomb according to claim 2, wherein the gas discharge holes are installed with eruption materials.

6. The gas balance training bomb according to claim 4, wherein the eruption material is a solid, powder or liquid.

7. The gas balance training bomb according to claim 1, wherein the gas guiding assembly is further composed of a nozzle, a guide tube and a gas choking tube, with a proper gap being provided between the guide tube and the gas choking tube.