JP2012042116A - Toy gun, and mounting instrument - Google Patents

Abstract

PROBLEM TO BE SOLVED: To attain the long time use of a toy gun for shooting bullets with compressed gas, without replacing a gas cartridge, and to improve portability of the gas cartridge.SOLUTION: An air chamber body 122 disposed in the toy gun forms an air chamber 126. Compressed gas in the air chamber body 122 passes through a gas exhaust part to shoot bullets held in a bullet holding part, from a muzzle. A valve opens/closes communication between the air chamber body 122 and the gas exhaust part according to the operation of an operating part. The toy gun includes a plurality of gas cartridge mounting parts 210. Gas cylinders 102 are mounted to the gas cartridge mounting parts 210. Each gas cartridge mounting part 210 is provided with a first valve part. Compressed gas in the gas cylinder 102 mounted to the gas cartridge mounting part 210 is led into the air chamber 126 via a gas lead-in part 301.

Description

  The present invention relates to a toy gun that can be equipped with a gas cartridge and that fires a bullet with pressure of compressed gas in the gas cartridge, and an attachment device for attaching the gas cartridge to the toy gun.

  2. Description of the Related Art Conventionally, a toy gun that can be equipped with a gas cartridge and fires a bullet with a pressure of compressed gas in the gas cartridge has been widely used. One example is the toy gun described in Patent Document 1.

  According to the description of Patent Document 1, one cylinder 22 (gas cartridge) is mounted in the toy. The cylinder 22 stores the compressed carbon dioxide gas and fills the air chamber 24 of the toy gun with the carbon dioxide gas. The user of the toy gun pulls the cocking head 34 rearward to position the piston 51 rearward, and then advances the cocking head 34 back to the original position. In this state, when the user pulls the trigger 61, the piston 51 moves forward. When the piston 51 moves forward, the air in the cylinder 44 is released into the barrel 15, and the bullet 12 in the barrel 15 is fired from the muzzle 16. Further, when the piston 51 moves forward, the hammer bar 31 moves forward and hits the valve 26 and breaks the shutoff of the air chamber 24 and the hammer bar storage chamber 25 by the valve 26. As a result, the gas in the air chamber 24 is released into the hammer bar storage chamber 25, pushes the hammer bar 31 rearward, moves the cocking head 34 backward, and positions the piston 51 rearward. Thereafter, each time the trigger 61 is pulled, the cocking head 34 automatically moves forward and backward.

Japanese Utility Model Publication No. 7-41292

  In the toy gun described in Patent Document 1, the cocking head 34 automatically advances and retreats, and many bullets are fired in a short time just like an actual gun. For this reason, the toy gun described in Patent Document 1 consumes a large amount of compressed gas.

  Here, in order to use the toy gun for a long time without replacing the cylinder 22, it is conceivable to make the cylinder 22 large. In this case, however, carrying the cylinder 22 becomes troublesome.

  An object of the present invention is to make it possible to use a toy gun that fires bullets with compressed gas for a long time without replacing the gas cartridge, and to improve the portability of the gas cartridge.

  A toy gun according to the present invention includes a bullet holding unit that holds a bullet, an air chamber body that forms an air chamber, a gas discharge unit that guides compressed gas in the air chamber to a bullet held in the bullet holding unit, A valve that opens and closes communication between the air chamber and the gas discharge unit, an operation unit that opens and closes the valve, a plurality of gas cartridge mounting units to which a gas cartridge that supplies compressed gas is mounted, and the gas cartridge mounting unit Each of the first valve portion and a gas introduction portion that guides the compressed gas from the gas cartridge attached to the gas cartridge attachment portion into the air chamber.

  The mounting device of the present invention is detachably attached to a plurality of gas cartridge mounting portions to which a gas cartridge for supplying compressed gas is mounted and a unit mounting portion provided in a toy gun, and is attached to the gas cartridge mounting portion. A unit mounting portion for guiding compressed gas supplied from a cartridge into the toy gun; a first valve portion provided in each of the gas cartridge mounting portions; a second valve portion provided in the unit mounting portion; Is provided.

  The mounting device of the present invention viewed from another aspect is detachable from a toy gun having a bullet holding portion for holding a bullet, and an air chamber body forming an air chamber, and the toy gun is provided in the air chamber. A gas discharge section for guiding compressed gas to the bullet held in the bullet holding section; a valve for opening and closing communication with the air chamber; a plurality of gas cartridge mounting sections to which a gas cartridge for supplying compressed gas is mounted; A first valve portion provided in each of the gas cartridge attachment portions; and a gas introduction portion that guides compressed gas from the gas cartridge attached to the gas cartridge attachment portion into the air chamber.

  According to the present invention, a plurality of gas cartridges can be mounted. Further, the gas cartridge mounting portion can be closed by the first valve portion. For this reason, a toy gun can be used using a plurality of small gas cartridges instead of a large gas cartridge. Therefore, a toy gun that fires bullets with compressed gas can be used for a long time without replacing the gas cartridge. Furthermore, the portability of the gas cartridge is improved. In addition, since the gas cartridge can be miniaturized, a toy gun can be designed flexibly.

It is a left view of the toy gun in 1st embodiment. It is a left sectional view showing the internal structure of a toy gun in the first embodiment. It is left sectional drawing which shows the internal structure of the toy gun in the state in which the volt | bolt was located in the press position in 1st embodiment. It is a perspective view of a gas cylinder in a first embodiment. It is a left sectional view showing the internal structure of the cylinder attachment instrument in the first embodiment. It is a left sectional view of a communicating passage in a first embodiment. It is a left sectional view of a communicating path in the state where a unit attached part was attached in a first embodiment. It is a left sectional view of a communicating path shown as a modification of a first embodiment. It is a left sectional view of a communicating path in the state where a unit attached part was shown as a modification of a first embodiment. It is a left sectional view of a cylinder attachment instrument in the state where a gas cylinder was attached only to one gas cartridge attachment part in a first embodiment. It is a left sectional view of a cylinder attachment instrument in the state where gas cylinders were attached to all the gas cartridge attachment parts in the first embodiment. It is a left sectional view in the state where the cylinder attachment instrument in which the gas cylinder was attached to all the gas cartridge attachment parts in the first embodiment was connected to the air chamber body. It is a left sectional view in the state where the cylinder attachment instrument in which the gas cylinder was attached only to one gas cartridge attachment part in the first embodiment was connected to the air chamber body. It is a left sectional view of a toy gun in the state where all the gas cartridge attachment parts were attached in a second embodiment. It is a left sectional view of a cylinder unit in a third embodiment. It is a left sectional view of a toy gun in a third embodiment. It is a left sectional view of a cylinder unit shown as a modification of a 3rd embodiment.

  One embodiment will be described with reference to FIGS. This embodiment is referred to as a first embodiment for convenience of explanation. FIG. 1 is a left side view of the toy gun 101. A gas cylinder 102 (gas cartridge) is attached to the toy gun 101. When using the toy gun 101, the user holds the grip 104 with his palm, puts his finger on the trigger 105, points the muzzle 103 toward the shooting target (for example, the target), and pulls the trigger 105. When the trigger 105 is pulled, the bullet B is fired from the muzzle 103 due to the pressure of the compressed gas sealed in the gas cylinder 102. Hereinafter, the side having the muzzle 103 is referred to as the front side of the toy gun 101. The side on which the grip 104 is located is called the rear side of the toy gun 101.

  FIG. 2 is a left sectional view showing the internal structure of the toy gun 101. In FIG. 2, the portion filled with the compressed gas is filled with dots. The toy gun 101 includes a frame 111, a magazine 112, a barrel 113, bolts 121, an air chamber body 122, a valve 123, a bolt spring 124 and a valve spring 129. The frame 111 forms a part of the barrel and defines the front-rear direction of the toy gun 101.

  The magazine 112 extends downward from a bullet inlet 190a (described later) provided in the air chamber body 122. The magazine 112 has a cylindrical shape that is open only at one end, and is attached to and detached from the frame 111 with the closed end positioned downward. In the magazine 112, a magazine spring 112a and a magazine follower 112b are arranged. The magazine spring 112a connects the closed end of the magazine 112 and the magazine follower 112b. The magazine 112 stores the bullet B. The bullet B in the magazine 112 is pushed up by the magazine spring 112a and fed into the passage 190 (described later) from the bullet introduction port 190a.

  The barrel 113 extends in the front-rear direction of the barrel and protrudes from the frame 111 to the front of the toy gun 101. The front end of the barrel 113 is a muzzle 103. The rear end of the barrel 113 is connected to the front side of the frame 111. The barrel 113 may be housed inside the frame 111.

  The air chamber body 122 is housed in the frame 111. A passage 190 is formed in the air chamber body 122. The passage 190 extends linearly from the rear end 103a of the barrel 113 opposite to the muzzle 103 in the front-rear direction of the barrel, and communicates with an air chamber 126 (described later). The bullet B supplied from the magazine 112 to the bullet introduction port 190a is pushed up by the magazine follower 112b, positioned in the passage 190, and held by the bullet holding unit 192. An example of the bullet holding part 192 is a minute recess formed on the upper surface of the inner space of the passage 190.

  An air chamber 126 is formed inside the air chamber body 122. The aforementioned passage 190 extends from the front side of the air chamber 126. The rear side of the air chamber 126 is closed with a rear lid 122a. The rear lid 122a is formed with a through hole 122b penetrating in the front-rear direction of the barrel. A ring-shaped packing 122c is attached around the through hole 122b on the front end surface of the rear lid 122a. The rear side of the through hole 122b has a large inner diameter and serves as a fitting hole 122d. A contact portion 121e (described later) provided in the bolt 121 enters the fitting hole 122d.

  A gas introduction path 122e is formed in the air chamber body 122. Due to the gas introduction path 122e, the air chamber body 122 has a shape protruding downward, and is fitted into the frame 111 and protrudes downward.

  The bolt 121 is housed in the frame 111. The bolt 121 has a cylindrical shape and extends in the front-rear direction of the toy gun 101. The front side of the bolt 121 is an open end 121a. The rear side of the bolt 121 is a closed end 121b. From the upper surface of the bolt 121, the lever 121c protrudes upward. A part of the lever 121c protrudes upward from the frame 111. From the lower surface on the rear side of the bolt 121, a locking projection 121d protrudes downward. The contact portion 121e protrudes from the closed end 121b toward the inner space of the bolt 121.

  The bolt 121 is movable in the longitudinal direction of the barrel. The bolt 121 starts moving forward when the user pulls the trigger 105, and reciprocates between the pressed position 121 </ b> A and the retracted position 121 </ b> B by the bolt spring 124 and the pressure of the compressed gas. Here, the retracted position 121 </ b> B is a position of the bolt 121 such that the contact portion 121 e is separated from a sliding projection 123 b (described later) of the valve 123 on the rear side of the toy gun 101. In FIG. 2, the bolt 121 is positioned at the retracted position 121B. The pressing position 121 </ b> A is a position of the bolt 121 such that the abutting portion 121 e is in contact with the sliding protrusion 123 b of the valve 123 on the front side of the toy gun 101 with respect to the retracted position 121 </ b> B. FIG. 3 shows how the bolt 121 is positioned at 121A.

  The bolt spring 124 is located between the outer surface of the closed end 121 b of the bolt 121 and the rear inner surface 111 b of the frame 111. The bolt spring 124 pushes the bolt 121 positioned at the retreat position 121B forward toward the pressing position 121A.

  The valve 123 is positioned between the air chamber 126 and the passage 190 and is disposed inside the air chamber 126. On the rear end side of the valve 123, a flange portion 123a and a sliding projection 123b are formed. The flange portion 123a protrudes radially from the outer periphery of the valve 123. The sliding protrusion 123b enters the through hole 122b and protrudes toward the fitting hole 122d. The valve 123 forms a straight path 123c and an inclined path 123d through which the compressed gas passes. The straight path 123c opens at the front end face of the valve 123 and extends in the front-rear direction of the barrel. The inclined path 123d is connected to the straight path 123c, extends in a direction inclined with respect to the straight path 123c, and opens between the flange portion 123a and the sliding protrusion 123b. An O-ring 127 and a washer 128 are attached to the outer periphery on the front end side of the valve 123. The O-ring 127 is sandwiched between the washer 128 and the inner wall of the air chamber body 122.

  The valve spring 129 is located between the washer 128 and the flange portion 123 a and is disposed so as to wrap around the outer periphery of the valve 123. The valve spring 129 pushes the washer 128 forward to press the O-ring 127 against the inner wall of the air chamber body 122. Further, the valve spring 129 presses the flange portion 123a against the packing 122c. Thereby, the communication between the passage 190 and the air chamber 126 is closed.

  FIG. 3 is a left sectional view showing the internal structure of the toy gun 101 in a state where the bolt 121 is positioned at the pressing position 121A. When the bolt 121 moves forward and reaches the pressing position 121A, the outer peripheral portion on the rear side of the air chamber body 122 is fitted into the opening end 121a (see FIG. 2) of the bolt 121. When the bolt 121 further advances, the contact portion 121e pushes the sliding protrusion 123b of the valve 123 protruding into the fitting hole 122d forward. As a result, the valve 123 slides forward, the flange portion 123a is separated from the packing 122c, and the communication between the passage 190 and the air chamber 126 is released.

  When the communication between the passage 190 and the air chamber 126 is released, the compressed gas filled in the air chamber 126 passes through the inclined passage 123d and the straight passage 123c into the passage 190 as shown by the arrows in FIG. It flows in and pushes the rear surface of the bullet B (see FIG. 2) held by the bullet holder 192. As a result, the bullet B jumps out of the muzzle 103 (see FIG. 2). Here, the inclined path 123d, the straight path 123c, and the passage 190 constitute a gas discharge unit 194 that guides the compressed gas in the air chamber 126 to the bullet B held by the bullet holding unit 192. The valve 123 opens and closes communication between the air chamber 126 and the gas discharge unit 194.

  Further, when communication between the passage 190 and the air chamber 126 is released, the compressed gas also flows into the gap S between the inner wall surface of the through-hole 122b and the sliding projection 123b as shown by the arrows in FIG. Get in. The compressed gas passes through the through hole 122b and pushes the contact portion 121e backward. Thereby, the bolt 121 starts to retreat and reaches a retreat position 121B (see FIG. 2). The bolt 121 that has reached the retreat position 121B is pushed forward by the bolt spring 124 and moves forward again. When the bolt 121 reaches the pressing position 121A, it pushes the sliding projection 123b of the valve 123 forward. Thus, the bolt 121 reciprocates repeatedly moving forward and backward. The bolt 121 contacts and separates from the valve 123 during one reciprocation, and opens and closes communication between the passage 190 and the air chamber 126.

  By the way, when the contact portion 121e is separated from the sliding projection 123b, the valve spring 129 pushes the valve 123 backward. As a result, the valve 123 slides backward, and the flange portion 123a comes into close contact with the packing 122c. As a result, the communication between the passage 190 and the air chamber 126 is closed. Thereafter, the air chamber 126 is filled with compressed gas supplied from the gas introduction path 122e.

  Reference is again made to FIG. The toy gun 101 includes a trigger 105, a trigger spring 131, a bolt sear 132, and a bolt sear spring 133. The trigger 105 is located in front of the grip 104 (see FIG. 1). The trigger 105 is attached to the frame 111 so as to be rotatable about a fulcrum 105a. The trigger 105 has a finger hooking part 105d and a rearward extension part 105b. The finger hook portion 105d extends downward from the fulcrum 105a. The rear extension 105b extends rearward from the fulcrum 105a. A bolt shear push-up portion 105c protrudes upward from the upper surface of the rear extension portion 105b. The trigger spring 131 pushes the finger hook portion 105d in the clockwise direction in FIG.

  The bolt sear 132 is provided at a position sandwiched between the bolt shear push-up portion 105c and the bolt 121 below. The bolt sear 132 is attached to the frame 111 so as to be rotatable about an axis 132a. The bolt sear 132 has a flat front protrusion 132b and a rear protrusion 132c spreading in a fan shape when viewed from the side. The front protrusion 132b protrudes forward relative to the shaft core 132a. The rear projecting portion 132c projects rearward from the shaft core 132a. A stopper portion 132d for stopping the locking projection 121d of the bolt 121 is provided above the rear protrusion 132c. The bolt sear spring 133 contacts the lower surface of the rear protrusion 132c, rotates the bolt sear 132 counterclockwise in FIG. 2, and lifts the stopper 132d upward. When the stopper portion 132d is lifted upward, the stopper portion 132d is caught by the locking protrusion 121d of the bolt 121 and prevents the bolt 121 from moving forward.

  When the user holds the lever 121c and moves it backward, the bolt 121 moves backward, and the locking projection 121d gets over the stopper portion 132d. Subsequently, when the user releases his hand from the lever 121c, the bolt 121 is pushed forward by the bolt spring 124, and the locking projection 121d is hooked on the stopper portion 132d. Thereafter, when the user pulls the trigger 105 backward with a finger, the trigger 105 rotates counterclockwise in FIG. 2, and moves the bolt shear push-up portion 105c to displace the front protrusion 132b upward. As a result, the bolt sear 132 rotates clockwise in FIG. 2, and the locking projection 121d is displaced downward. As a result, the bolt 121 is pushed forward by the bolt spring 124, the valve 123 moves forward, and the communication between the air chamber 126 and the gas discharge part 194 is opened and closed. In FIG. 2, the state of the trigger 105, the trigger spring 131, the bolt sear 132, and the bolt sear spring 133 when the trigger 105 is pulled backward is indicated by a two-dot chain line.

  When the user releases his / her finger from the trigger 105, the trigger spring 131 pushes the finger hooking portion 105d clockwise in FIG. 2, and displaces the bolt shear push-up portion 105c downward. Here, the bolt sear spring 133 pushes the bolt sear 132 to rotate counterclockwise in FIG. For this reason, the front protrusion 132b moves downward and the stopper 132d moves upward. As a result, the forward movement of the bolt 121 is blocked, the valve 123 is pushed rearward, and the communication between the air chamber 126 and the gas discharge part 194 is closed. As described above, the trigger 105 constitutes the operation unit 130 for opening and closing the valve 123.

  Here, a gas cylinder 102 used for the toy gun 101 and a cylinder mounting tool 201 for attaching the gas cylinder 102 to the toy gun 101 are considered. The cylinder mounting tool 201 corresponds to the “mounting tool” in the claims. First, refer to FIG. In the present embodiment, the gas cylinder 102 is housed in the cylinder mounting tool 201 and is positioned in front of the trigger 105. The cylinder attaching device 201 is attached to the unit attached portion 122f (see also FIG. 2) in a state where the gas cylinder 102 is accommodated. This unit attached portion 122f is provided at the lower end of the gas introduction path 122e.

  The cylinder mounting tool 201 has a box shape that is long in the vertical direction. A unit mounting portion 202 protrudes from the upper surface of the cylinder mounting tool 201. A storage space 203 for storing two gas cylinders 102 is formed inside the cylinder mounting tool 201. A partition 203 a is provided in the storage space 203. The partition part 203a partitions the storage space 203 into an arrangement space 204a for arranging the individual gas cylinders 102. A gas cylinder introduction port 204 leading to the storage space 203 is opened on the side surface of the cylinder mounting tool 201. Two cylinder holders 206 are disposed in the storage space 203 near the attachment tool bottom 205 opposite to the unit attachment portion 202. A shaft 207 extends from each of the cylinder holders 206. Both shafts 207 pass through the fixture bottom 205. The handle 208 is provided at the end of each shaft 207 outside the storage space 203. A screw portion 209 is provided on the outer periphery of each shaft 207. The screw part 209 is screwed into the mounting tool bottom part 205. When the user rotates the handle 208, the cylinder presser 206 moves up and down. When the user stops the rotation of the handle 208, the cylinder presser 206 stops without dropping due to the screwing of the mounting tool bottom portion 205 and the screw portion 209. The cylinder holder 206, the shaft 207, the handle 208, and the screw portion 209 move the gas cylinder 102 disposed in the arrangement space 204a to the sealing member 102c (see FIG. 4 and the like) of the gas cylinder 102 and the needle portion 217a (see FIG. 6 and the like). And the gas cylinder 102 is fixed in that state.

  As a technique for fixing the gas cylinder 102 by inserting the needle part 217a into the sealing material 102c of the gas cylinder 102 arranged in the arrangement space 204a, in place of the cylinder holder 206, the shaft 207, the handle 208, and the screw part 209, the United States You may employ | adopt the technique described in the patent 7290539 specification. In this case, a panel with a rotating roller is attached to the cylinder mounting tool 201 so that the panel opens and closes the storage space 203. When the panel is closed, the rotating roller pushes the gas cylinder 102 in the storage space 203. When the gas cylinder 102 is pushed by the rotating roller, the gas cylinder 102 is fixed in the storage space 203, and the needle portion 217a pierces the sealing material 102c of the gas cylinder 102.

  FIG. 4 is a perspective view of the gas cylinder 102. The gas cylinder 102 has a cylindrical shape. A compressed gas is sealed in the gas cylinder 102. Examples of the compressed gas are carbon dioxide gas, chlorofluorocarbon gas, and alternative chlorofluorocarbon gas. One first end 102a of the gas cylinder 102 is conically constricted. A gas outlet 102b is provided at the tip of the first end 102a. The gas outlet 102b is sealed with a sealing material 102c. The other second end portion 102d of the gas cylinder 102 is a closed end.

  FIG. 5 is a left sectional view showing the internal structure of the cylinder mounting tool 201. FIG. 6 is a left sectional view of the communication path 213. Please refer to FIG. 5 and FIG. The cylinder mounting tool 201 includes a gas cartridge mounting part 210, a first valve part 211, and a second valve part 212. Further, a communication passage 213 is formed in the cylinder mounting tool 201. In the present embodiment, the gas cartridge mounting part 210, the first valve part 211, the unit mounting part 202, and the second valve part 212 are unitized and provided in the cylinder mounting tool 201. For this reason, the cylinder mounting tool 201 is detachable collectively from the unit mounted portion 122f.

  The communication path 213 has a main path 213a. The main path 213 a is provided in the unit mounting portion 202 and extends inside the unit mounting portion 202. The main path 213a branches into two branch paths 213b. The branch path 213b includes a first path 213ba extending from the end of the main path 213a in a direction intersecting the main path 213a, and a second path 213bb connecting the first path 213ba and the arrangement space 204a.

  A gas cartridge mounting part 210 and a first valve part 211 are arranged in the branch path 213b. Hereinafter, the gas cartridge mounting part 210 and the first valve part 211 will be described. The gas cartridge mounting part 210 has an opening part 217 (described later), and is provided at the end of the branch path 213b on the arrangement space 204a side. A gas jet outlet 102b (see FIG. 4) of the gas cylinder 102 is attached to the gas cartridge attachment portion 210. The gas cartridge attachment portion 210 is provided with a first valve portion 211. The first valve portion 211 opens and closes communication between the communication path 213 and the arrangement space 204a. The first valve portion 211 includes a check valve 211a. The check valve 211 a includes a valve ball 214 and a ball valve packing 215.

  The valve ball 214, the ball valve packing 215, the first auxiliary packing 216, the opening part 217, and the second auxiliary packing 218 are introduced into the second path 213bb in this order from the arrangement space 204a. The valve ball 214 has a true spherical shape. The ball valve packing 215 is formed with a receiving portion 215a and a through hole 215b. The receiving portion 215a forms an inclined surface that is inclined with respect to the through hole 215b, and receives the valve ball 214 on the inclined surface. The through hole 215 b extends from the receiving portion 215 a and penetrates the ball valve packing 215. The opening part 217 includes a needle part 217a, a presser part 217b, and a fitting part 217c. The needle portion 217a protrudes toward the arrangement space 204a. The presser portion 217 b protrudes toward the unit mounting portion 202 and presses the ball valve packing 215. The fitting portion 217c is fitted into a fitting groove 213c formed on the inner peripheral surface of the second path 213bb. The opening part 217 has a vent hole 217d. The vent hole 217d passes through the needle portion 217a and the fitting portion 217c and continues to the through hole 215b. The first auxiliary packing 216 surrounds the outer surface of the opening part 217 and is sandwiched between the ball valve packing 215 and the fitting portion 217c. The second auxiliary packing 218 sandwiches the fitting portion 217 c together with the first auxiliary packing 216. The first auxiliary packing 216, the opening part 217, and the second auxiliary packing 218 are all press-fitted into the second path 213bb and do not move in the second path 213bb. As a result, the ball valve packing 215 is pressed by the presser portion 217b and the first auxiliary packing 216, and does not move in the second path 213bb. Here, the diameter of the valve ball 214 is larger than the inner diameter of the first passage 213ba. For this reason, the valve ball 214 does not roll into the first path 213ba.

  Here, the first valve portion 211 may include a manual valve that can be opened and closed by a user's operation instead of the check valve 211a.

  The 2nd valve part 212 is arrange | positioned at the main path 213a. Hereinafter, the second valve portion 212 will be described. The 2nd valve part 212 is provided in the middle of the main path 213a, and opens and closes communication with the communicating path 213 and external space. The second valve portion 212 includes a valve body spring 219, a valve body 220, and a valve body packing 221.

  In the main path 213 a, the valve body spring 219, the valve body 220, the valve body packing 221, the third auxiliary packing 222, the press-fitting member 223, and the nozzle support member 224 are arranged in this order from the opening 202 a that opens to the unit mounting portion 202. be introduced. The valve body packing 221 slightly protrudes from the third auxiliary packing 222 to the inside of the main path 213a to form a minute step portion 221b. In the present embodiment, the valve body 220 is a cylindrical body that is long in the extending direction of the main path 213a. A vent hole 220a is formed in the valve body 220. The vent hole 220 a connects the end surface of the valve body 220 on the opening 202 a side and the side surface of the valve body 220. A flange portion 220b protrudes from the side surface of the valve body 220 at a location closer to the branch path 213b than the opening of the vent hole 220a. The valve body spring 219 is located between the flange portion 220b and the spring receiving portion 213d, and pushes the valve body 220 toward the opening 202a. The spring receiving portion 213d is provided at the boundary between the main path 213a and the branch path 213b and protrudes toward the inside of the communication path 213. The valve body packing 221 forms a through hole 221a into which the valve body 220 enters. The flange 220 b of the valve body 220 pressed by the valve body spring 219 is pressed against the valve body packing 221. The third auxiliary packing 222, the press-fitting member 223, and the nozzle support member 224 prevent the valve body packing 221 from moving toward the opening 202a. The opening of the vent hole 220a that appears on the side surface of the valve body 220 is in contact with the inner peripheral surface of the through hole 221a. Thereby, the main path 213a is blocked.

  FIG. 7 is a left sectional view of the communication path 213 with the unit attached portion 122f attached. Incidentally, the unit attached portion 122f has a nozzle 122g (see FIG. 2). The nozzle 122g communicates with the gas introduction path 122e. The outer periphery of the tip of the nozzle 122g is slightly recessed, and a minute step portion 122h is formed. The nozzle 122g is inserted into the main path 213a from the opening 202a. For such a nozzle 122g, the nozzle support member 224 holds the side surface of the inserted nozzle 122g and closes the gap between the nozzle support member 224 and the nozzle 122g. Thereby, the inner space of the inserted nozzle 122g and the vent hole 220a of the valve body 220 communicate with each other. The tip of the inserted nozzle 122g moves the valve body 220 toward the branch path 213b. Here, when the minute step portion 221b of the valve body packing 221 and the minute step portion 122h of the nozzle 122g are engaged, the valve body 220 pushed by the nozzle 122g does not hit the spring receiving portion 213d. For this reason, the valve body spring 219 is not crushed and the main path 213a is not blocked. Thereby, the inner space of the nozzle 122g, the vent hole 220a, and the main path 213a communicate with each other. In addition, the valve body 220 moved by the nozzle 122g is drawn with the dashed-dotted line in FIG. When the nozzle 122g is pulled out from the main path 213a, the valve body spring 219 pushes the valve body 220 toward the opening 202a and blocks the main path 213a.

  Here, the modification regarding the 2nd valve part 212 is demonstrated based on FIG.8 and FIG.9. FIG. 8 is a left sectional view of the communication path 213. The second valve portion 212 includes a check valve 212a. The check valve 212 a includes a valve ball 225 and a valve body packing 221. The valve ball 225 is disposed in place of the valve body 220 and has a true spherical shape. The valve ball 225 is pressed toward the opening 202a by the valve body spring 219 and the pressure of the compressed gas in the communication passage 213, and the valve ball 225 is pressed against the edge of the through hole 221a. Thereby, the main path 213a is interrupted.

  FIG. 9 is a left sectional view of the communication path 213 with the unit attached portion 122f attached. In this modification, a notch 122i is formed at the tip of the nozzle 122g. When the nozzle 122g is inserted into the main path 213a from the opening 202a, the gap between the nozzle support member 224 and the nozzle 122g is closed. The tip of the inserted nozzle 122g moves the valve ball 225 to the branch path 213b side. Thereby, the inner space of the nozzle 122g and the main path 213a communicate. Here, the presence of the notch 122i ensures communication between the inner space of the nozzle 122g and the main path 213a. Further, since the minute step portion 221b of the valve body packing 221 and the minute step portion 122h of the nozzle 122g are engaged, the valve ball 225 pushed by the nozzle 122g does not hit the spring receiving portion 213d. For this reason, the valve body spring 219 is not crushed and the main path 213a is not blocked. In addition, the valve ball 225 moved by the nozzle 122g is drawn with the dashed-dotted line in FIG. When the nozzle 122g is pulled out from the main path 213a, the valve body spring 219 pushes the valve ball 225 toward the opening 202a and blocks the main path 213a.

  Here, considering that the valve ball 225 shown in FIGS. 8 and 9 is pressed by the pressure of the compressed gas in the communication passage 213 and pressed against the valve body packing 221, the valve body spring 219 may be omitted. However, due to the valve body spring 219, when the nozzle 122g is pulled out from the main path 213a, the valve ball 225 quickly moves to the opening 202a, and the main path 213a is immediately shut off.

  Moreover, you may form the inclined surface which inclines with respect to the through-hole 221a like the receiving part 215a shown by FIG.6 and FIG.7 in the contact location with the valve ball | bowl 225 in the packing 221 for valve bodies.

  Returning to the description of the first embodiment. FIG. 10 is a left sectional view of the cylinder attaching device 201 in a state where the gas cylinder 102 is attached only to one gas cartridge attaching portion 210. In FIG. 10, the portion filled with compressed gas air is filled with dots. The user introduces the gas cylinder 102 into the arrangement space 204a from the gas cylinder introduction port 204 (see FIG. 1). At this time, the first end 102 a is brought closer to the gas cartridge mounting part 210, and the second end 102 d is brought closer to the cylinder holder 206. Subsequently, the user turns the handle 208 so that the cylinder holder 206 moves toward the gas cartridge mounting part 210. Thereby, the needle part 217a of the opening part 217 pierces the sealing material 102c (see also FIG. 4) of the gas cylinder 102. Then, the compressed gas in the gas cylinder 102 is jetted out and enters the vent hole 217 d to separate the valve ball 214 from the ball valve packing 215. As a result, the compressed gas passes through the branch path 213b and flows into the main path 213a, thereby increasing the pressure in the communication path 213 at a stretch.

  Here, in the gas cartridge mounting part 210 to which the gas cylinder 102 is not attached (the gas cartridge mounting part 210 on the left side in FIG. 10), the valve ball 214 is brought to the atmospheric pressure in the communication path 213, and the ball valve packing 215 is received. It is pressed against the part 215a. For this reason, compressed gas does not leak from the gas cartridge attachment part 210 to which the gas cylinder 102 is not attached.

  Moreover, in the 2nd valve part 212, the valve body spring 219 has pushed the valve body 220, and the main path 213a is interrupted | blocked. For this reason, the compressed gas does not leak from the unit mounting portion 202.

  FIG. 11 is a left sectional view of the cylinder attaching device 201 in a state where the gas cylinders 102 are attached to all the gas cartridge attaching portions 210. In FIG. 11, the portion filled with the compressed gas is filled with dots. The user attaches the gas cylinder 102 in the same procedure to the gas cartridge attachment part 210 to which the gas cylinder 102 is not attached. Thereby, the compressed gas enters the communication path 213 from any of the gas cartridge mounting portions 210.

  FIG. 12 is a left sectional view of a state in which the cylinder mounting tool 201 in which the gas cylinders 102 are mounted on all the gas cartridge mounting portions 210 is connected to the air chamber body 122. In FIG. 12, the portion filled with the compressed gas is filled with dots. The user inserts the nozzle 122 g provided in the air chamber body 122 into the opening 202 a of the unit mounting portion 202. Thereby, the gas introduction path 122e in the air chamber body 122 communicates with the communication path 213 in the cylinder mounting tool 201. In addition, a gas introduction part 301 that guides the compressed gas from the gas cartridge attachment part 210 attached to the gas cartridge attachment part 210 into the air chamber 126 is formed. In the present embodiment, as described above, the gas introduction part 301 can be connected and separated by the unit attached part 122f and the unit attaching part 202. Each time the user moves the trigger 105 (see FIG. 1 and the like) and fires a bullet B (see FIG. 1 and the like) from the muzzle 103 (see FIG. 1 and the like) of the toy gun 101, the compressed gas is introduced into the gas. It is supplied from the gas cylinder 102 through the part 301 and is filled in the air chamber 126.

  FIG. 13 is a left cross-sectional view of a state in which a cylinder mounting tool 201 in which the gas cylinder 102 is mounted only on one gas cartridge mounting part 210 is connected to the air chamber body 122. In FIG. 13, the portion filled with the compressed gas is filled with dots. As shown in FIG. 10, even if the cylinder mounting tool 201 in which the gas cylinder 102 is mounted only on one gas cartridge mounting part 210 is mounted on the air chamber body 122, the user can use the toy gun 101 without any problem. This is because the compressed gas does not leak from the gas cartridge mounting part 210 to which the gas cylinder 102 is not mounted as described above. Further, even if the user attaches the cylinder attaching device 201 in which the gas cylinders 102 are attached to all the gas cartridge attaching parts 210 to the toy gun 101 and then removes one gas cylinder 102, the gas in which the gas cylinder 102 is not attached. The compressed gas does not leak from the cartridge mounting part 210.

  When the user removes the cylinder mounting tool 201 from the nozzle 122g, the valve body spring 219 pushes the valve body 220 toward the opening 202a and blocks the main path 213a. Thereby, the compressed gas in the gas cylinder 102 does not leak from the opening 202a.

  Thus, in the toy gun 101 of the present embodiment, a plurality of gas cylinders 102 can be mounted. Further, the gas cartridge mounting part 210 can be closed by the first valve part 211. For this reason, the toy gun 101 can be used using a plurality of small gas cylinders 102 instead of the large gas cylinder 102. Therefore, the toy gun 101 can be used for a long time without replacing the gas cylinder 102. In addition, the portability of the gas cylinder 102 is improved. In addition, since the gas cylinder 102 can be downsized, the toy gun 101 can be designed flexibly. Then, by closing the first valve portion 211, it is possible to fire the bullet B from the toy gun 101 only by attaching one gas cylinder 102 to the cylinder mounting instrument 201.

  Further, in the toy gun 101 of the present embodiment, the first valve portion 211 includes a check valve 211a. For this reason, the user does not need to open and close the first valve portion 211 when attaching and detaching the gas cylinder 102.

  Further, in the toy gun 101 of the present embodiment, the gas cylinder mounting part 210, the first valve part 211, the unit mounting part 202, and the second valve part 212 are provided as a unit in the cylinder mounting tool 201. Yes. For this reason, the usability of the cylinder mounting tool 201 is improved.

  Furthermore, in the toy gun 101 of the present embodiment, the compressed gas does not leak even if the cylinder attaching device 201 is removed from the nozzle 122g or several gas cylinders 102 are removed from the cylinder attaching device 201. For this reason, the gas cylinder 102 attached to this cylinder mounting instrument 201 after removing the cylinder mounting instrument 201 from the nozzle 122g can be used at a later date. The cylinder mounting tool 201 removed with the gas cylinder 102 attached can be attached to another toy gun 101.

  Next, another embodiment will be described with reference to FIG. This embodiment is called a second embodiment for convenience of explanation. In this case, the same reference numerals are used for the same parts as those in the first embodiment, and description thereof is also omitted.

  FIG. 14 is a left sectional view of the toy gun 101 with all the gas cartridge attachment portions 210 attached. In FIG. 14, the portion filled with the compressed gas is filled with dots. In the present embodiment, elements corresponding to the cylinder mounting tool 201 in the first embodiment are formed integrally with the air chamber body 122. That is, the gas cylinder mounting portion 201a extends downward from the air chamber body 122 of the present embodiment. A storage space 203 is formed in the gas cylinder mounting portion 201a, and elements provided in the cylinder mounting tool 201 such as the gas cartridge mounting portion 210 and the first valve portion 211 are stored therein. Here, in the present embodiment, the toy gun 101 does not include the second valve portion 212 (see FIG. 6 and the like). Further, the gas introduction path 122e and the main path 213a are shared. Further, the toy gun 101 is not provided with a spring receiving portion 213d (see FIG. 6) located at the boundary between the main path 213a and the branch path 213b.

  Also in the toy gun 101 of this embodiment, a plurality of small gas cylinders 102 can be used as in the first embodiment. Therefore, the toy gun 101 can be used for a long time without replacing the gas cylinder 102. In addition, the portability of the gas cylinder 102 is improved. Furthermore, in the toy gun 101 of the present embodiment, the air chamber body 122 and the gas cylinder mounting portion 201a are not separated, so that the cylinder mounting instrument 201 (see the first embodiment) is not lost.

  Next, another embodiment will be described with reference to FIGS. 15 and 16. This embodiment is called a third embodiment for convenience of explanation. This embodiment conforms to the second embodiment. In this case, the same parts as those in the second embodiment are denoted by the same reference numerals, and the description thereof is also omitted.

  FIG. 15 is a left sectional view of the cylinder unit 401. In the present embodiment, the air chamber body 122, the gas introduction part 301, the gas cartridge attachment part 210, the first valve part 211, and the valve 123 are unitized as a cylinder unit 401. The cylinder unit 401 corresponds to the “mounting device” in the claims. The cylinder unit 401 is detachable from the frame 111. The configuration of the cylinder unit 401 is the same as that of the air chamber body 122 in the second embodiment. That is, the cylinder unit 401 includes an air chamber body 122 in which the gas cylinder mounting portion 201 a is extended, and a valve 123 that is accommodated in the air chamber body 122. Further, a flange portion 302 extends from the side surface of the gas introduction portion 301.

  FIG. 16 is a left sectional view of the toy gun 101. On the lower surface of the frame 111, a slot 111a for introducing the cylinder unit 401 from below is provided. A guide portion 111 c that guides the cylinder unit 401 extends from the edge of the slot 111 a toward the inside of the frame 111.

  A stopper 111 d is provided on the side surface of the frame 111. The stopper 111d is slidable in the left-right direction of the toy gun 101 and can be moved by the user. The stopper 111d holds the flange portion 302 of the cylinder unit 401 inserted from the slot 111a, and prevents the cylinder unit 401 from moving up and down. Further, as shown in FIG. 16, the upper surface of the front portion of the stopper 111 d supports the lower surface of the front end portion of the air chamber body 122.

  A holding projection 111 e projects from the left and right inner surfaces of the frame 111. The holding protrusion 111e sandwiches the left and right side surfaces of the air chamber body 122 and prevents the cylinder unit 401 from moving in the left-right direction of the toy gun 101. The bolt 121 is formed in a shape that does not interfere with the holding projection 111e.

  The user has a cylinder unit 401 with the gas cylinder 102 attached to the gas cylinder attachment portion 201a, and introduces the air chamber body 122 of the cylinder unit 401 upward from the slot 111a. The air chamber body 122 is guided by the guide portion 111c, and is positioned at a position where the barrel 113 and the valve 123 are arranged coaxially. At this time, the air chamber body 122 is sandwiched between the holding protrusions 111e. Subsequently, the user moves the stopper 111d to hold the flange portion 302 on the stopper 111d. In this state, when the user moves the trigger 105, the bolt 121 moves forward, the contact portion 121 e pushes the sliding projection 123 b, and the compressed gas in the air chamber 126 pushes the bullet B through the gas discharge portion 194. As a result, the bullet B is fired from the muzzle 103.

  Also in the toy gun 101 of this embodiment, a plurality of small gas cylinders 102 can be used as in the first embodiment. Therefore, the toy gun 101 can be used for a long time without replacing the gas cylinder 102. In addition, the portability of the gas cylinder 102 is improved. Furthermore, in the toy gun 101 of the present embodiment, the air chamber body 122 can be exchanged. Here, the air chamber body 122 includes an air chamber 126 and a valve 123 which are important for causing the bullet B to be fired. For this reason, the user can enjoy various sniper sensations through the toy gun 101 by exchanging the cylinder unit 401.

  As a modification of the third embodiment, as shown in FIG. 17, a magazine 112 may be attached to the side surface of the gas cylinder attachment portion 201 a of the cylinder unit 401.

  In the third embodiment and its modification, the cylinder unit 401 can be fixed to and released from the frame 111 instead of using the flange portion 302 and the stopper 111d.

  An example of fixing and releasing the cylinder unit 401 with respect to the frame 111 is shown. A magazine release portion extending in the left-right direction and having a groove is provided in the frame 111. The cylinder unit 401 inserted from the slot 111a engages with the groove. When the magazine release portion is moved, the engagement between the groove and the cylinder unit 401 is released, and the magazine 112 can be removed.

  Another example of fixing and releasing the cylinder unit 401 with respect to the frame 111 is shown. A magazine catch having a claw portion and an operation lever portion is connected to the frame 111. The pawl portion of the magazine catch is movable forward and backward with respect to the lower surface of the valve 123, and supports the lower surface of the valve 123. The magazine catch is pushed by a spring or the like so that the claw portion enters the lower surface of the valve 123. When the user moves the operation lever portion, the claw portion retracts from the lower surface of the valve 123, and the cylinder unit 401 can be inserted into and removed from the slot 111a. When the user releases his hand from the operation lever portion, the claw portion moves to support the lower surface of the valve 123. Thereby, the cylinder unit 401 is fixed to the frame 111.

  In any of the first to third embodiments, the toy gun 101 is of a continuous fire type that continues to fire the bullet B as long as the trigger 105 is continuously pulled, but the present invention is a single shot toy. It goes without saying that it can be applied to both a gun and a toy gun of a burst type.

  In any of the first to third embodiments and the modifications thereof, the gas cylinder 102 is positioned in front of the trigger 105, but the present invention triggers the mounting location of the cylinder mounting instrument 201 and the cylinder unit 401. Needless to say, the present invention can also be applied to a toy gun provided behind 105 so that the gas cylinder 102 is positioned behind the trigger 105.

  Needless to say, the portions specifically described in the respective embodiments and the modifications thereof can be appropriately combined with the other embodiments and the modifications thereof.

101 Toy gun 102 Gas cylinder (gas cartridge)
122 air chamber body 122f unit attached portion 123 valve 126 air chamber 130 operation portion 192 bullet holding portion 194 gas discharge portion 201 cylinder attachment device (mounting device)
202 Unit mounting portion 210 Gas cartridge mounting portion 211 First valve portion 211a Check valve 212 Second valve portion 301 Gas introduction portion 401 Cylinder unit (mounting device)
B bullet

Claims (7)

A bullet holder for holding bullets;
An air chamber body forming an air chamber;
A gas discharge unit that guides the compressed gas in the air chamber to the bullet held in the bullet holding unit;
A valve that opens and closes communication between the air chamber and the gas discharge unit;
An operation unit for opening and closing the valve;
A plurality of gas cartridge mounting portions to which gas cartridges for supplying compressed gas are mounted;
A first valve portion provided in each of the gas cartridge mounting portions;
A gas introduction part that guides compressed gas from the gas cartridge attached to the gas cartridge attachment part into the air chamber;
Toy gun with The first valve portion includes a check valve,
The toy gun according to claim 1. The gas introduction part includes a unit attachment part provided on the air chamber side and a unit attachment part provided on the gas cartridge attachment part side and detachable from the unit attachment part. Yes,
The unit mounting portion is provided with a second valve portion,
The gas cartridge mounting portion, the first valve portion, the unit mounting portion, and the second valve portion are unitized and are detachable collectively.
The toy gun according to claim 1 or 2. The second valve portion includes a check valve,
The toy gun according to claim 3. The air chamber body, the gas introduction part, the gas cartridge attachment part, the first valve part, and the valve are unitized and are detachable collectively.
The toy gun according to claim 1 or 2. A plurality of gas cartridge mounting portions to which gas cartridges for supplying compressed gas are mounted;
A unit mounting portion that is detachable from a unit mounting portion provided in the toy gun and guides the compressed gas supplied from the gas cartridge attached to the gas cartridge mounting portion into the toy gun;
A first valve portion provided in each of the gas cartridge mounting portions;
A second valve portion provided in the unit mounting portion;
A fixture comprising: An air chamber body that is detachable from a toy gun having a bullet holding portion for holding a bullet and forms an air chamber;
A gas discharge part that is provided in the toy gun and guides the compressed gas in the air chamber to a bullet held in the bullet holding part; and a valve that opens and closes communication with the air chamber;
A plurality of gas cartridge mounting portions to which gas cartridges for supplying compressed gas are mounted;
A first valve portion provided in each of the gas cartridge mounting portions;
A gas introduction part that guides compressed gas from the gas cartridge attached to the gas cartridge attachment part into the air chamber;
A fixture comprising:

Images