JP3207942U - Mock gun - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a simulated gun that is relatively easy to handle with one hand even for a young person such as 10 years old and easy to fire a simulated bullet with one hand. A simulated gun that introduces air into a pump by pulling down a hammer 3 and compresses a spring, releases a compression of the spring by pulling a trigger, compresses air, and fires a bullet by compressed air. 1, the hammer 3 has a finger placement portion 3 a on which a user places a thumb, and the finger placement portion 3 a has a width in the direction perpendicular to the barrel direction of 14 mm or more. [Selection] Figure 1

Description

  The present invention relates to a simulated gun that is relatively easy to handle with one hand even for a young person such as 10 years old, and relatively easy to fire a simulated bullet with one hand.

  As a simulated gun called an air gun, air is introduced into the pump by pulling down the hammer, the spring is compressed, the compression of the spring is released by pulling the trigger, and the accumulated pressure of the spring is released. A type is disclosed in which compressed air is generated by compressing air in a pump, and a simulated bullet is fired with the compressed air (Patent Document 1).

No. 7-29435

  For safety, simulated guns such as air guns may only be allowed to be sold to those over the age of 10 due to regulations such as bylaws, and under the age of 18 under the voluntary regulations of industry groups, etc. As described above, the power of the simulated gun is regulated by the target age. In particular, the configuration of the simulated gun having the configuration disclosed in Patent Document 1 is often used for a simulated gun intended for those over 10 years of age.

  That is, for example, it is used by an age group that is still weak, such as 10 years old. In an age group that is weak, such as 10 years old, it is necessary to pull down the hammer and compress the spring. In many cases, it was necessary to use both thumbs of both hands, which was difficult to handle.

  If the strength of the spring is weak, the problem can be solved. However, this reduces the power of the simulated gun, which reduces the attractiveness of the simulated gun itself.

  For this reason, reducing the strength of the spring leads to a decrease in the attractiveness of the simulated gun. Therefore, although it is desired to avoid it as much as possible, there is a desire for young people to handle the simulated gun with one hand as much as possible.

  That is, young people like the characters of movies, dramas, comics, etc., have a desire to handle a simulated gun with one hand and fire a simulated bullet. On the other hand, in actual firearms (real guns), it is difficult for even a strong adult to handle a real gun with one hand because of the weight of the real gun and the reaction when the bullet is fired. Actually, it is rare to operate a real gun with one hand to reduce accuracy.

  However, in the case of a simulated gun, there is a desire (desire) that the young person wants to handle the simulated gun with one hand as easily because of the admiration of the characters in the movies.

  Accordingly, an object of the present invention is to provide a simulated gun that is relatively easy to handle with one hand even for a young person such as 10 years old and relatively easy to fire a simulated bullet with one hand.

  To achieve the above object, the simulated gun of the present invention introduces air into the pump by pulling down the hammer, compresses the spring, and pulls the trigger to release the compression of the spring and compress the air. The hammer has a finger rest on which a user puts a thumb, and the finger rest has a width in the direction perpendicular to the direction of the barrel of 14 mm or more. It is characterized by being.

  The finger placement unit of the present invention is configured to be vertically long along the direction of the barrel, and the hammer can be pulled down by placing the belly of the thumb.

  Further, the simulated gun of the present invention has a cylinder for storing the bullet, and the cylinder has a yoke fixed to a muzzle side of the cylinder and a bolt fixed to a latch arranged on the hammer side of the cylinder. The cylinder is pivotally supported inside the simulated gun body, and the latch is slid in the opposite direction to the muzzle, thereby retracting the bolt in the opposite direction and releasing the cylinder pivot support by the bolt. The latch and the bolt are urged together by a spring with respect to the direction of the muzzle, and the urging force of the spring is With the cylinder positioned outside the simulated gun body, the grip of the simulated gun is held with one hand, and the cylinder is supported by the shaft inside the simulated gun body. When the wrist is swung in the direction of the position to be swung and the wrist is swung toward the position where the cylinder is supported, a part of the cylinder comes into contact with the latch, and the latch and the bolt are The latch and the bolt are moved away from the muzzle in a direction opposite to the muzzle, and the latch and the bolt are moved in the muzzle direction by eliminating a conflict with the bolt and the latch at a part of the cylinder at the pivotally supported position. It is an urging force that allows the bolt to pivotally support the cylinder by sliding.

  Further, the cylinder of the present invention has a concave portion in which the bolt is fitted and rotatably supported at the rotation center portion of the surface opposite to the muzzle direction, and the bolt is formed in a cylindrical shape. It is comprised by the comprised protrusion, and the front end side of the side surface of the said protrusion is comprised, and it is characterized by the above-mentioned.

  According to the simulated gun of the present invention, for example, even a young person such as 10 years old is relatively easy to handle with one hand and relatively easy to fire a simulated bullet with one hand.

  That is, according to the simulated gun of the present invention, the hammer has a finger placement portion on which the user places a thumb, and the finger placement portion has a width in the direction perpendicular to the barrel direction of 14 mm or more. Even young people such as 10 years old can efficiently apply force to the hammer with the thumb of one hand, and even a young person pulls down the hammer with one hand and pulls the trigger with the index finger of one hand, so that a simulated bullet can be produced with one hand. It is relatively easy to fire.

  Therefore, even a young person such as a character in a movie or the like can easily fire a simulated bullet from a simulated gun with one hand and easily meet the needs of the young person.

  In addition, since the finger placement portion of the present invention is configured to be vertically long along the direction of the barrel and the thumb belly can be placed and the hammer can be pulled down, the finger placement along the shape of the thumb belly is possible. The loading part is formed, and the force can be transmitted efficiently from the belly of the thumb to the hammer. Even from this, even the younger can pull down the hammer with one hand and pull the trigger with the index finger of one hand, and simulate with one hand Making it possible to fire bullets is relatively easy, and it is easy to satisfy the desire of a young man to operate a simulated gun with one hand.

  Further, according to the simulated gun of the present invention, the latch and the bolt fixed to the latch are urged together by the spring with respect to the direction of the muzzle. The urging force of this spring is such that the grip of the simulated gun is held with one hand while the cylinder is located outside the simulated gun body, and the cylinder is snapped in the direction of the position pivotally supported by the bolt inside the simulated gun body. When the wrist is shaken, the cylinder swings toward the pivotally supported position, part of the cylinder comes into contact with the latch, and the latch and bolt are pushed away in the direction opposite to the muzzle and retracted. At the position where the cylinder is pivotally supported, the latch and the bolt slide in the direction of the muzzle by eliminating the collision of a part of the cylinder, so that the cylinder can be pivotally supported. Is relatively easy to return to the simulated gun body (swing-in operation).

  Therefore, even a young person such as a character in a movie or the like can return the cylinder to the main body of the simulated gun with one hand (it can swing in), which easily satisfies the needs of the young person.

  Furthermore, according to the simulated gun of the present invention, the cylinder has a recess that is rotatably supported by a bolt inserted into the rotation center of the surface opposite to the muzzle direction, and the bolt is cylindrical. Since it is comprised by the comprised protrusion and the front end side of the side surface of a protrusion is chamfered, it is easy to implement | achieve swing-in operation | movement with one hand more easily.

  This makes it relatively easy for a young person to perform a series of operations from swinging in a cylinder, pulling down a hammer, pulling a trigger with one hand, with one hand, like a character in a movie, etc. Even a younger person can operate a simulated gun with one hand to make it easier to fire a simulated bullet, and can easily satisfy the needs of the younger person.

It is a top view which shows centering around the hammer part of the simulation gun of this invention. It is explanatory drawing which showed the state which has located the cylinder outside the simulation gun main body about the simulation gun of FIG. 1 with the user's one hand. It is explanatory drawing of the state which made the cylinder swing in from the state of FIG. It is explanatory drawing which looked at the simulation gun of the state of FIG. 1 from the muzzle direction. It is a side view of the simulation gun of the state of FIG. It is a top view of the simulation gun of the state of FIG. FIG. 4 is a side view of the simulated gun in the state of FIG. 3.

  Hereinafter, an embodiment for implementing a simulated gun according to the present invention will be described with reference to the drawings.

  According to the simulated gun of the present invention, for example, even a young person such as 10 years old can handle it with one hand relatively easily, and can be stored in the cylinder body with one hand (swing in) It is relatively easy to lower the hammer with one hand and pull the trigger with one hand, making it relatively easy to launch a simulated bullet with one hand.

[Configuration of simulated gun]
The outline of the simulated gun will be described first with reference to FIGS. FIG. 1 is a plan view showing a hammer portion of a simulated gun according to the present invention. FIG. 2 is an explanatory diagram showing a state in which the cylinder is positioned outside the simulated gun body of the simulated gun of FIG. 1 together with one hand of the user. FIG. 3 is an explanatory diagram of a state in which the cylinder is swung in from the state of FIG. FIG. 4 is an explanatory view of the simulated gun in the state of FIG. 1 as viewed from the muzzle direction.

  The simulated gun 1 in the present embodiment is called an air gun, and by introducing the air into the pump (not shown) of the main body 2 (FIG. 4) of the simulated gun 1 by pulling down the hammer 3, By compressing a spring (not shown) and pulling the trigger 5, the compression of the spring is released and the accumulated pressure of the spring is released, thereby compressing the air in the pump and generating compressed air. A simulated bullet (not shown) that is spherical and made of resin or the like is fired with air.

  As shown in FIGS. 2, 4, and 5, the body 2 of the simulated gun 1 includes a cylinder 9 that can be accommodated in an opening 2 b surrounded by a frame 2 a and a rod 9 that serves as a rotation center axis of the cylinder 6. It is arranged to be movable through a yoke 8 that connects the rod 9 and the main body 2.

  The cylinder 6 is housed in the main body 2 via the rod 9 and the yoke 8 as shown in FIGS. 1 and 3, and as shown in FIGS. It is possible to move in the direction perpendicular to the direction of the barrel 11, that is, in the side surface direction of the simulated gun 1.

  As shown in FIGS. 2 to 4, a muzzle 12 is disposed at the tip of the barrel 11, and a simulated bullet fired from the simulated gun 1 is temporarily fixed in a cartridge (not shown). 6 is stored in a magazine 6e penetrating from a muzzle side surface 6a to a surface 6c opposite to the muzzle side.

  As shown in the enlarged circular portion of FIG. 2, a concave portion 6f whose center is recessed in a disk-like space is formed at the rotation center of the opposite surface 6c of the cylinder 6 on the muzzle 12 side, and around the concave portion 6f. Is provided with a ratchet 6d that extends radially outward from the recess 6f and that is flush with the recess 6f in accordance with the number of magazines 6e.

  As shown in the circular enlarged portion of FIG. 4, when the cylinder 6 is housed in the main body 2, a disk-shaped protrusion is formed on the portion of the cylinder 6 that faces the surface 6 c opposite to the muzzle 12 side. Bolts 17 are arranged.

  The bolt 17 is connected and fixed inside the frame 2a with the latch 7 provided on the side thereof, that is, provided on the side surface of the frame 2a of the main body 2 (the connection structure is not shown). It is configured to be slidable along 11 directions.

  That is, both the bolt 17 and the latch 7 are configured to be able to advance toward the muzzle 12 or to retract toward the opposite side of the muzzle 12, and the bolt 17 and the latch 7 that are connected and fixed to each other are always inside the frame 2a. It is biased by a spring (not shown) in the direction of the muzzle 11. The sliding direction of the bolt 17 and the latch 7 is shown in the enlarged part of FIG.

  When the cylinder 6 is housed in the main body 2, the bolt 17 is fitted into the recess 6 f of the cylinder 6 to rotatably support the cylinder 6 f so that the recess 6 f and the bolt 17 are 6 are mutually arranged so that it may oppose in the state accommodated in the inside of the main body 2 (so that it may be inserted).

  As shown in FIGS. 3 to 5, the latch 7 has a shape such that the Roman letter “T” is rotated 90 ° to the left, and the latch 7 is pointed at a position corresponding to the end of the letter “T”. The portion 7b is arranged, and the user of the simulated gun 1 puts his finger on the finger rest portion 7b and slides the latch 7 in the direction opposite to the muzzle 12, whereby the latch 7 itself and the bolt 17 connected and fixed to the latch 7 are provided. Is configured to be slidable in the opposite direction to the muzzle 12.

  Further, the latch 7 is provided with a contact portion 7a that is recessed in a portion corresponding to the “T” umbrella on the surface. In shifting from the state in which the cylinder 6 is located outside the main body 2 to the state in which the cylinder 6 is housed inside the main body 2, the ratchet 6 d of the cylinder 6 comes into contact with the contact portion 7 a of the latch 7, and the latch 7 And the bolt 17 to be connected and fixed automatically slides in the direction opposite to the muzzle.

  Above the bolt 17, an air outlet 15 is disposed at a position that can be opposed to the magazine 6 e of the surface 6 c opposite to the muzzle side of the cylinder 6. Compressed air is ejected from the air ejection port 15, and a simulated bullet temporarily fixed to the cartridge in the magazine 6 e is ejected from the cartridge, passes through the barrel 11, and is fired from the muzzle 12.

  A feeding claw 16 is disposed slightly below the side of the bolt 17. Further, another feed claw 16 is arranged below the feed claw 16. When these two feed claws 16 are interlocked with the trigger 5 and the trigger 5 is pulled, as shown by the arrow D2 in the enlarged portion of FIG. Then, it is configured to return to the original position.

  When the trigger 6 is pulled while the cylinder 6 is housed in the main body 2, the two feeding claws 16 move in the direction D <b> 2, so that the two feeding claws 16 support the rotation center of the cylinder 6. Since the two feed claws 16 are caught on each adjacent ratchet 6d of the cylinder 6 and the cylinder 6 is rotated, the next magazine 6e of the cylinder 6 is located in front of the air outlet 15. It will be rotated until it is located at.

  Moreover, the trigger 5 and the hammer 3 are connected inside the main body 2 (the connection structure is not shown), and when the hammer 3 is pulled down, the trigger 5 is also pulled halfway. When the user further pulls the trigger 5, the accumulated pressure of a spring (not shown) compressed by the hammer 3 is released, and a simulated bullet is fired. Thereafter, the hammer 3 returns to the original position in conjunction with the return of the spring to the original shape due to the release of the spring.

  If only the trigger 5 is pulled in a state where the hammer 3 is not pulled, the cylinder 6 rotates until the next magazine 6e is located in front of the air outlet 15, and the first force is naturally generated by the biasing force of a spring (not shown). It only returns to the position.

[Operation of simulated gun]
The operation of the simulated gun will be described. This will be described with reference to FIGS. FIG. 6 is a plan view of the simulated gun in the state of FIG. FIG. 7 is a side view of the simulated gun in the state of FIG.

  First, in the state of FIGS. 1 and 7, when there is no simulated bullet in the magazine 6 e of the cylinder 6 (when no cartridge in which the simulated bullet is temporarily fixed is not contained), the user can 7b is slid to the opposite side of the muzzle 12, and the latch 7 and the bolt 17 are slid to the opposite side of the muzzle 12, thereby releasing the pivotal support state in which the bolt 17 is inserted into the recess 6f of the cylinder 6. .

  At that time, the user pushes the side surface 6b of the cylinder 6 in the direction indicated by D3 in FIG. 1, so that the cylinder 6 moves in the direction D3 as shown in FIGS. 2 is located outside. In this case, since the latch 7 and the bolt 17 are retracted by sliding in the opposite direction to the muzzle 12 using the user's finger hooking portion 7 b, the recess 6 f flush with the ratchet 6 d of the cylinder 6 is the tip of the bolt 17. The cylinder 6 can move smoothly to the outside of the main body 2 without touching the portion 17a side and the latch 7.

  Next, in a state where the cylinder 6 is located outside the main body 2, a cartridge (not shown) in which a simulated bullet is temporarily fixed is packed in the magazine 6 e, and then the cylinder 6 is again moved into the opening 2 b of the main body 2. Return. In this case, it is possible to return the cylinder 6 to the inside of the main body 2 as shown in FIG. 3 by moving the cylinder 6 in the direction indicated by the arrow D4 in FIG.

  At this time, as shown in FIGS. 1, 5, 6, and 7, the ratchet 6 d and the recess 6 f of the cylinder 6 come into contact with a part of the latch 7. However, in the latch 7, the above-described contact portion 7 a is formed at a position where the ratchet 6 d and the recess 6 f come into contact with each other, and the contact portion 7 a is recessed in a concave shape. Thus, the latch 7 and the bolt 17 to be connected and fixed can be slid by being pushed against each other in the direction opposite to the muzzle 12, and the latch 7 and the bolt 17 are retracted, but the ratchet 6 d of the cylinder 6 is in contact with the cylinder 7. 6 is housed again in the opening 2b of the main body 2.

  When the cylinder 6 is housed in the opening 2b of the main body 2 again, when the rotation center axis of the cylinder 6 moves to a position opposite to the center of the axis of the bolt 17, there is no object that conflicts with the ratchet 6d and the recess 6f. Therefore, since the ratchet 6d and the recess 6f are not in contact with the latch 7 (the contact portion 7a) and the bolt 17, the latch 7 and the bolt 17 are biased in the direction of the muzzle 12 by the spring to the latch 7 and the bolt 17. Then, the bolt 17 moves forward, and the bolt 17 is again inserted into the recess f of the cylinder 6 and pivotally supported, so that the cylinder 6 is rotatably fixed.

  Thereafter, as shown in FIG. 3, the user pulls down the hammer 3 to introduce air into the pump (not shown) of the main body 2 (FIG. 4) of the simulated gun 1 and a spring (not shown). Compress.

  The trigger 5 and the hammer 3 are connected inside the main body 2 (the connection structure is not shown), and when the hammer 3 is pulled down, the trigger 5 is also pulled halfway, and further triggers in that state. When the user pulls 5 with the index finger of one hand 30, the accumulated pressure of a spring (not shown) compressed by the hammer 3 is released, a simulated bullet is fired, and the simulated gun 1 passes through the barrel 11 and the muzzle 12. Fired from.

  At this time, the trigger 3 is pulled by the hammer 3 in conjunction with the lowering of the hammer 3, so that the two feed claws 16 move in the direction D <b> 2 of FIG. The cylinder 6 is rotated by being caught in each adjacent ratchet 6d, and the next magazine 6e of the cylinder 6 is rotated until it is located in front of the air outlet 15. The simulated bullet is fired at that position. It becomes.

  When the hammer 3 is pulled down again after the simulated bullet is fired, the trigger 5 is interlocked, so that the cylinder 6 is rotated via the ratchet 6d by the operation of the feed claw 16, and the next magazine 6e is moved to the air ejection hole 15. It moves to the opposite position, and it becomes possible to fire the simulated bullet again. This simulated bullet firing operation can be repeated until there are no simulated bullets in the magazine.

[Composition and action of hammer]
The configuration and operation of the hammer will be described with reference to FIGS. 1 and 2.

As shown in FIGS. 1 and 2, the hammer 3 is arranged in the frame 2 a of the main body 2 on the opposite side of the muzzle 12 with respect to the barrel 11 in the simulated gun 1. A spring (not shown) inside the grip 18 of the gun 1 is compressed.

  A flat finger rest 3 a on which the user places his thumb is formed at the tip of the hammer 3. The finger placement portion 3a is configured to be very large with the width of the widest portion in the direction perpendicular to the barrel direction being 14 mm or more. The finger placement portion 3a indicates the width of the widest portion in the direction perpendicular to the barrel direction as W in FIG.

  Further, the finger placement portion 3a is configured to be vertically long along the direction of the barrel 11, and is configured to easily fit the thumb that is placed and pulls down the hammer 3. Moreover, in order to make it easy to put a thumb on the surface of the finger placement portion 3a, a fine unevenness (a hatched portion of the finger placement portion 3a in FIG. 1) and anti-slip processing such as embossing are performed.

  As shown in FIG. 3, the finger placement unit 3a holds the grip 18 of the simulated gun 1 with one hand 30, and in that state, places the thumb on the finger placement unit 3a like the thumb 30a indicated by a broken line, and directly with one hand The hammer 3 can be easily pulled down.

  That is, as a result of trial and error, the inventor of the present invention is able to pull down the hammer 3 as much as possible with the thumb 30a of the one hand 30 holding the grip 18 as a result of trial and error. It has been found that 3a can be realized by configuring it in a very large size in which the width of the widest portion perpendicular to the barrel direction is 14 mm or more.

  Furthermore, by configuring the finger placement portion 3a to be vertically long along the direction of the barrel 11, the thumb that pulls down the hammer 3 can be easily fitted, and the hammer 3 can be easily pulled down with the twill finger of one hand 30 as it is. I found.

  This is because the simulated gun usually follows the form of a real gun, and the hammer in the real gun has the function of detonating the gunpowder filled in the cartridge. Therefore, the hammer mounting portion is configured to have a narrow width in the direction perpendicular to the barrel direction.

  However, when the finger mount 3a of the hammer 3 of the simulated gun 1 is configured as a real gun, the young person pulls down the hammer 3 as it is with the thumb 30a of the one hand 30 holding the grip 18 of the simulated gun 1 and compresses the spring. It is difficult to do.

  Here, the inventor pays attention to the fact that the minimum age of a young person who uses the simulated gun 1 is often 10 years old, and even if it is a 10-year-old child, trial and error is performed on a configuration in which the hammer 3 can be pulled down as much as possible. It was.

  As a result, “2008 construction of a physical property database for children to improve the safety of machine products and visualization simulation technology for human injury situation” issued by the Japan Machinery Federation and the Human Life Engineering Research Center In the “Survey Report”, the result of the investigation that the first fingernail base width (width of the base of the thumb nail) of a 10-year-old child is about 16 mm is disclosed.

  As a result of the trial and error, the inventor was a 10-year-old child by increasing the width in the direction perpendicular to the direction of the barrel 11 of the finger rest portion 3a to 14 mm or more. However, it has been found that the hammer 3 can be easily pulled down by applying force to the thumb 30a.

  That is, as shown in the vertically elongated oval extracted portion of FIG. 1, the inventor has shown that the thumb 30 a is placed on the finger placement portion 3 a, and the inventor has a width perpendicular to the direction of the barrel 11 of the finger placement portion 3 a ( Even if it is a 10-year-old child, the width of the base of the claw 30a1 of the thumb 30a (the thumb base claw width is indicated by WS) is ensured such that W) is 14 mm or more. It has been found that it is easy to pull down the hammer 3 by applying a force through the belly, and as a result of trial and error, it is relatively easy to pull down the hammer 3 by ensuring that W is at least about 14 mm. It came to the conclusion that it becomes.

  As a result, even a young person can grasp the grip 18 of the simulated gun 1 with one hand 30 and place the thumb 30a on the finger rest 3a in that state, and can easily pull down the hammer 3 with one hand 30 as much as possible. Is done.

  Further, by making the width in the direction perpendicular to the direction of the barrel 11 of the finger placement portion 3a to be 14 mm or more and 22 mm or less, the appearance of the finger placement portion 3a is kept as smart as an actual gun, and the entire simulated gun 1 It is possible to maintain the same atmosphere as an actual gun.

[Cylinder swing-in operation with one hand]
A swing-in operation of the cylinder with one hand will be described with reference to FIGS.

  As shown in FIG. 2, the swing-in operation means that the cylinder 6 is positioned outside the main body 2 and the main body 2 is moved by snapping using the wrist 30b of the one hand 30 holding the grip 18. Swinging in the direction of the arrow indicated by D4 in FIG. 2 (swinging) means that the cylinder 6 returns to the main body 2 of the simulated gun 1 only by the movement of one hand 30.

  In this case, the latch 7 and the bolt 17 of the simulated gun 1 are coupled and fixed to each other and are urged together by a spring (not shown) with respect to the direction of the muzzle 12.

  As shown in FIG. 2, the urging force of the spring is obtained by holding the grip 18 of the simulated gun 1 with one hand 30 in a state where the cylinder 6 is located outside the main body 2, and the cylinder 6 is in the opening 2 b inside the main body 2. When the wrist 30b is swung (swinged) by applying a snap in the direction of the pivotally supported position (direction D4 in FIG. 2), the cylinder 6 moves toward the pivotally supported position inside the main body 2 (swing). However, the ratchet 6d, which is a part of the cylinder 6, comes into contact with the contact portion 7a of the latch 7, and the latch 7 and the bolt 17 are pushed away in the direction opposite to the muzzle 12, and the cylinder 6 is pivotally supported. In the position where the ratchet 6d and the recess 6f, the latch 7 and the bolt 17 are not in contact with each other, the latch 7 and the bolt 17 slide in the direction of the muzzle 12, and the bolt 17 And it has a biasing force which is capable of supporting the over 6.

  That is, the urging force of the spring (not shown) is such that when the grip 18 of the simulated gun 1 is gripped with one hand 30, and the cylinder 6 is snapped in the direction of D4 in FIG. As the cylinder 6 moves (swings) toward the position where it is pivotally supported inside the main body 2, the cylinder 6 comes into contact with the latch 7 and the bolt 17, but is finally accommodated in the opening 2 b of the main body 2. The desired value is set in consideration of the weight of the cylinder 6 so as to be supported by the shaft 17.

  When the biasing force of the spring is too strong, the latch 7 and the bolt 17 strongly come into contact with the ratchet 6d of the cylinder 6, and the cylinder 6 is held inside the main body 2 with the other hand other than the one holding the grip 18 of the simulated gun 1. Because it must be pushed into

  Further, the bolt 17 has a chamfered portion 17b formed by chamfering the tip 17a side of the side surface of the cylindrical protrusion. Accordingly, when the grip 18 of the simulated gun 1 is grasped with one hand 30 and the cylinder 6 is snapped in the direction of D4 in FIG. 2 and the wrist 30b is shaken (swinged), the cylinder 6 is pivotally supported inside the main body 2. While moving (swing) toward the position where the cylinder 6 is in contact with the latch 7 and the bolt 17, the cylinder 6 is finally housed in the opening 2 b of the main body 2, and the bolt 17 slides in the direction of the muzzle 12. (Advance. During this advancement, even if the bolt is in contact with the recess 6f due to the presence of the chamfered portion 17b, the bolt 17 can be guided and inserted into the recess 6f of the cylinder 6 smoothly and without difficulty. Is possible.

  Accordingly, as shown in FIGS. 2 and 3, the main body 2 is attached to the body 2 shown in FIG. 2 by using the wrist 30 b of the one hand 30 holding the grip 18 while the cylinder 6 is positioned outside the main body 2. When swinging (swinging) in the direction of the arrow indicated by D4, a swing-in operation is performed in which the cylinder 6 returns to the main body 2 of the simulated gun 1 only by the operation of one hand 30.

  As a result, as shown in FIG. 2 and FIG. 3, even a young person can perform a series of operations from swinging in the cylinder 6 to pulling down the hammer 3 and pulling the trigger 5 with only one hand 30 with only one hand 30. This makes it easier for even young people, such as characters in movies, to operate the simulated gun 1 with one hand and fire the simulated bullets. Cheap.

  The invention can be embodied in many forms without departing from its essential characteristics. Therefore, it is needless to say that the above-described embodiments are exclusively explanatory and do not limit the present invention.

DESCRIPTION OF SYMBOLS 1 Simulated gun 2 Main body 2a Frame 2b Opening part 3 Hammer 3a Finger mounting part 5 Trigger 6 Cylinder 6a Muzzle side surface 6b Side surface 6c Opposite side to muzzle side 6d Ratchet 6e Magazine 6f Recess 7 Latch 7a Contact part 7b Finger hook part 8 9 Rod 11 Barrel 12 Muzzle 15 Air outlet 16 Feeding claw 17 Bolt (projection)
17a Tip 17b Chamfer 18 Grip 30 One hand 30a Thumb 30a1 Nail 30b Wrist W Finger rest width WS Thumb nail base width

Claims (4)

This is a simulated gun that introduces air into the pump by pulling down the hammer, compresses the spring, pulls the trigger, releases the compression of the spring, compresses the air, and fires a bullet with the compressed air. And
The hammer has a finger placement portion on which a user places a thumb, and the finger placement portion has a width in a direction perpendicular to the barrel direction of 14 mm or more.   2. The simulated gun according to claim 1, wherein the finger placement unit is configured to be vertically long along a direction of the barrel, and the hammer can be pulled down by placing the belly of the thumb. The simulated gun has a cylinder for storing the bullet,
The cylinder is pivotally supported inside the simulated gun body via a yoke arranged on the muzzle side of the cylinder and a bolt fixed to a latch arranged on the hammer side of the cylinder, and the latch is connected to the muzzle. By sliding in the opposite direction, the bolt is retracted in the opposite direction to release the axial support of the cylinder by the bolt and can be moved to the outside of the simulated gun body via the yoke. ,
The latch and the bolt are biased together by a spring against the direction of the muzzle,
The biasing force of the spring is such that the cylinder is positioned outside the simulated gun body, the grip of the simulated gun is held with one hand, and the direction of the position where the cylinder is pivotally supported inside the simulated gun body When the wrist is swung and the wrist is shaken, the cylinder swings toward the pivotally supported position, a part of the cylinder comes into contact with the latch, and the latch and the bolt are separated from the muzzle. The latch and the bolt slide in the muzzle direction by eliminating the conflict with the bolt and the latch in a part of the cylinder at the position where the cylinder is supported and pushed away in the opposite direction. The simulated gun according to claim 1, wherein the cylinder has an urging force capable of pivotally supporting the bolt.   The cylinder has a recess that is rotatably supported by being inserted into the rotation center portion of the surface opposite to the muzzle direction, and the bolt is formed in a cylindrical shape. The simulation gun according to claim 3, wherein a tip end side of a side surface of the projection is chamfered.

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