JP3958765B2 - Toy gun magazine and toy gun with continuous firing function - Google Patents

Description

  The present invention relates to a toy gun having a function of continuously firing spherical bullets, a magazine used by being attached to the toy gun, and a structure of dedicated parts used for the toy gun and the magazine. The main feature is that a continuous bullet feeding mechanism that continuously sends out spherical bullets is provided inside the, and the continuous bullet feeding mechanism is operated using the continuous firing mechanism of the toy gun. Provided are a toy gun having a continuous firing function that can fire several hundred shots with a single trigger pull, a removable magazine, and a structure of dedicated parts related to them.

  The main subject of the present invention will be clarified by looking at the history of the development of a general magazine feed mechanism and automatic bullet feed mechanism in the toy gun industry.

When using a conventional spring-push-up magazine,
The bullets were loaded one by one so that the spring in the magazine was pressed and shrunk. In the case of a spring-loaded magazine, the shortest magazine has a limit of dozens, and the long magazine has a limit of storage even if it is devised by bending the spherical bullet conveyance path into a U-shape. However, the desire of toy gun users to shoot even more continuously was strong.

  The magazine that continuously sends out spherical bullets using sprockets is the first in the toy gun industry as seen in Japanese Patent Publication No. Hei 4-18237. It was an application about 20 years ago, and there was no gas gun or electric gun at that time. . According to the present invention, each time an operation member (a member generally called a hand guard) for compressing the firing spring is pulled down by hand, a protruding bar provided behind the operation member is inserted from the front portion of the magazine. The internal mechanism of the magazine works by being inserted into the magazine, and it sends out one bullet at a time, and it does not operate continuously using a spring, electric motor, gas pressure, or the like. The applicant is Marushin Kogyo Co., Ltd., and FIG. 1 is a basic structural diagram shown in the patent publication. The magazine body 1001 has a spherical bullet storage portion 1002, and a tapered guide wall 1004 for guiding the spherical bullet toward the spherical bullet feed sprocket 1003 is provided in a lower portion of the spherical bullet storage portion 1002. ing. A stopper member 1005 having elasticity is provided at the exit of the spherical bullet.

  According to the invention of Marushin Kogyo Co., Ltd., when the preparatory operation for pulling the operation member by hand is performed once, one spherical bullet is sent out from the magazine to the gun body side. An automatic bullet feeding mechanism having a structure in which a spherical bullet is always pushed up was invented regardless of whether or not there is a firing preparation operation in which a leaf spring spring for accumulating power is added to the utilized invention and the operation member is manually pulled.

  This is disclosed in Japanese Patent Publication No. Sho 62-1558997. A drum type that winds up a leaf spring spring by hand, accumulates power, continuously applies the force to the sprocket to rotate by the accumulated energy of the spring, and continuously sends out about 500 spherical bullets stored in the magazine It is a large magazine. The applicant is LS Co., Ltd. FIG. 2 is a basic structural diagram shown in the patent publication. The magazine body 1006 has a spherical bullet storage portion 1007, and the spherical bullet storage portion 1007 is provided with a tapered guide wall 1009 for guiding the spherical bullet toward the spherical bullet delivery sprocket 1008. At the outlet of the spherical bullet, a stopper member 1010 having a shape that prevents the spherical bullet from jumping out is provided. The sprocket 508 can always keep pushing up the spherical bullets strongly and powerfully even when shooting is not being performed, due to the action of the sufficiently stored mainspring drum.

  More than 18 years have passed since the filing of the spring-type magazine using this sprocket, but the spring-type magazine currently on the market is basically no different.

  The multi-magazine magazine using the mainspring was only a large magazine manufactured by L.S., but now a small magazine with almost the same basic feed structure has been released by Tokyo Marui. The compact and thinly designed mainspring storage part and sprocket part can accommodate about 200 to 600 shots even in a thin box magazine that is the same size as a real gun magazine, and is stored by a long leaf spring that is rolled up by hand. You can now push up all bullets that you want to continue. However, it takes more time than expected to wind the long spring spring by scrubbing the gear-shaped spring winding convex part slightly projecting on the bottom of the thin small box magazine with your fingertips. In addition, when the number of windings overlaps frequently, the fingertips become painful, and there are also problems of downsizing. Electric magazines that dislike this manual winding work and wind up the mainspring using a motor and battery eventually appear.

  An improved version of the above-described spring-type magazine manufactured by L.S. About seven years have passed since the first spring-style magazine was filed. The applicant is Yoshitomo (Yes). In magazines that continuously send out spherical bullets using sprockets, the sprocket's convex part and the tip of the wall of the storage part (in other words, the entrance to the sprocket transport part) at the moment when the spherical bullet tries to enter the concave part of the sprocket. Or a separation part from the sprocket), and there is a drawback that a phenomenon in which the sprocket is stopped, that is, a so-called biting phenomenon (also called a jam phenomenon) occurs. In order not to cause such a phenomenon, a member that rotates or swipes is provided near the entrance to the sprocket transport unit so that the biting phenomenon does not occur It is. FIG. 3 is a basic structural diagram shown in the published utility model gazette. It is a device that assists so that the tip portion 1012 of the arm member 1011 is struck and the rotating member 1013 is rotated so that the spherical bullet easily enters the recess of the sprocket. The spring-type magazine according to the present invention is produced by the applicant and is still sold as a product representative of the spring-type drum magazine. In the description of the embodiment of the application, “Driver A has a spring built in it, or has a motor built in it and uses the driving force (rotational force) of this motor. There is a description of ". No. 7-12793 has not been publicized or registered at this time, but this Yoshitomo product has been modified by a retailer to wind up the mainspring with a motor and is still sold as an electric drum magazine. ing. The power is turned on and off by operating a switch provided on the exterior of the magazine. Before using the magazine, the power switch is turned on to wind up the mainspring, and when the winding is completed, the power switch is turned off. As a result, various modified electric magazines were sold from many retail stores. There are types that incorporate batteries in the magazine and types that use external batteries. There are also types that switch the operation of electric magazines in conjunction with triggers.

  When many spherical bullets are stored in a narrow space like a small magazine, another troublesome phenomenon may occur. A magazine that stores multiple bullets. If the width of the storage section is narrow and the length of the storage section is long, even if the sprocket and other delivery sections are functioning normally, Due to the friction between the wall surface and the spherical bullet, a phenomenon may occur where the spherical bullets are accidentally stuck together in an arch shape. This is a so-called bridge phenomenon. Such a bridge phenomenon is caused by a plate-like member that is biased by a spring so that the magazine has a narrow width and the length of the magazine is long, or a spherical bullet does not violate and emit a jagged sound. May occur in the case of a magazine that presses down the entire spherical bullet, etc., but a drum magazine having a large space above the feed-out part (Japanese Patent Laid-Open Publication Nos. 62-158997 and 7-12793). The drum magazine as described above) and large box-type magazines, which are mostly open-type magazines that do not hold the entire spherical bullet with a spring-biased plate-like member, etc. Absent. Moreover, the idea that the tip 512 of the arm member 511 is knocked and the rotating member 513 rotates as shown in Japanese Utility Model Laid-Open No. 7-12793 also functions sufficiently to prevent the occurrence of the bridging phenomenon. It is.

  There is an invention that has been patented for obtaining the effect that the bridging phenomenon does not occur. This is an invention of Japanese Patent Laid-Open No. 6-74691, and is registered as Patent No. 2905649. The applicant is Ohira Giken Kogyo Co., Ltd. FIG. 5 is a basic structural diagram shown in the patent publication. This is an application for an electric magazine with a built-in motor. There are also shown an invention example of a game gun feeding apparatus using a conveying screw and a conventional example of a game gun feeding apparatus using a conveying belt. However, Ohira Giken Kogyo Co., Ltd. is a manufacturer of arcade game machines, etc., and the invention of Japanese Patent Laid-Open No. 6-74691 is also a large game machine that was considered for arcade games. It states that you have to push up the bullet. Moreover, it is a fixed large-sized magazine for arcade games, and is not a detachable electric magazine.

  The invention disclosed in Japanese Patent Laid-Open No. 6-74691 was the first to include a motor built in a magazine in the patent gazettes, but the predecessor of the electric magazine patent was a utility model gazette 5- This is indicated at 702. It is a bullet feeding device that pushes spherical bullets in a row by a motor and pushes them up continuously. The applicant is Teruichi Kawano. FIG. 4 is a basic structure diagram shown in the patent publication. In this device, a sensor member 1014 and a limit switch 1015 are provided in the vicinity of the exit of the spherical bullet to control ON / OFF of the motor. In addition, two kinds of methods for controlling the ON and OFF of the motor by utilizing the reaction that occurs simultaneously with the completion of the loading are described in detail and specifically presented together with the drawings. This device was commercialized and sold. It is a very good product and is a huge hit product that is still selling. However, since this device is only a bullet feeding device for a spring-type magazine, the device according to this device could not be used directly attached to a gun.

  I want to somehow attach this bullet feeder directly to the gun. Everyone in the toy gun industry wishes to do so. However, with the switch mechanism as shown in this device, it is not possible to turn the power on in accordance with the launch and automatically turn off the power after the shooting is completed. I couldn't do it.

  Approximately three years after the filing of this Japanese Utility Model 5-702, the invention of the above-mentioned game gun feeding device using a conveying screw, Japanese Patent Laid-Open No. 6-74691, has been filed as the first electric magazine. FIG. 5 is a basic structural diagram shown in the patent publication. The magazine is set on the electric toy gun, and the spherical bullet is drawn just before the firing nozzle. Both the cylinder and the air discharge pipe member are fixed to the gun body, and there is no idea that a bullet is pushed into the barrel packing one by one and fired one by one reliably. It is an invention of an era when the idea that spherical bullets sent by screw and air pressure could be continuously fired fully automatically anyway.

  A spherical bullet storage unit 1017 is provided inside the magazine body 1016, and a screw conveyor 1019 and a motor 1020 connected via a coupling 1018 are disposed below the storage unit 1017. The feature of the invention is that a screw conveyor is used as a means for conveying the spherical bullet.

  This game gun feeding device of Japanese Patent Laid-Open No. 6-74691 is shown to be used by setting it directly on a gun, but it is the most important technique when a small electric magazine is set on a toy gun and used. There is no figure about sensor technology or switch technology.

  Further, although there are sensor technology and switch technology, the basic structure of the bullet feeding device of actual fairness 5-702 shown in FIG. Although more than 15 years have passed since the application, it is still sold as a mere bullet feeder, and no one can make it into an electric magazine.

  The control technology that, when 10 bullets are fired on the toy gun side, the motor in the magazine is instantaneously activated and rotated by the amount of 10 bullets sent out, and then automatically stops. Until this does not exist in the toy gun industry. When the tip of the toy gun launching mechanism is two to three rounds away from the top of the removable magazine and the magazine is set on the toy gun and ready for firing, The first two or three bullets that were inside were gone out of the magazine. Moreover, since it is tightly surrounded by a pipe-shaped conveyance path, the biggest neck is that the movement of the tip of the inside of the toy gun cannot be read from the removable magazine side. Thus, there is still no effective means for confirming whether or not a spherical bullet has been fired from the detachable magazine side, and there is no means for counting the number of fired bullets.

  The current level of technology in the toy gun industry can be found in advertisements in specialized magazines. Monthly Combat Magazine magazine, February 2004 issue P153, published an advertisement for a large box magazine called “Perfect Magazine with a total of 3,000 bullets, which was further rolled up electrically, ¥ 17300”. A switch is attached to the exterior of the magazine. When the switch is turned on, the internal motor rotates to wind up the built-in spring. Instead of winding the mainspring by hand, the mainspring is wound up by the amount that the motor is sent out by pressing the exterior switch. Also, in the magazine P188, “If TA system, pulling a trigger 3000 shots continuously ... trigger interlock switch, electric bullet magazine ... main body switch machining, electric bullet magazine processing ... ¥ 29800” There is an advertisement for another large box magazine. For the same product, other specialized magazines Arms Magazine January 2004 issue P191, “Turn the trigger automatically when you pull the trigger. ・ TA3000. "There is no need to press the ammunition switch ..." This is an advertisement characterized in that an exterior switch is not provided in the magazine. Instead, it is necessary to modify the gun so that the magazine operates in conjunction with the trigger switch on the gun body, and to modify the magazine to match the gun. The remodeling is done by the store that advertised, and the price of ¥ 29800 includes a processing fee. Compared to the magazine that has a mainspring winding switch on the exterior of the magazine for ¥ 17300, the trigger-linked switch mechanism that turns the motor on the magazine side each time the trigger is pulled is simply considered. It will be up to ¥ 12500 just by remodeling. In any case, the price of ¥ 17300 and ¥ 29800 is very high compared to the suggested retail price of a genuine spring-type magazine sold by a toy gun manufacturer, which is about ¥ 3500 to ¥ 4500. Even if you spend that much money, the current toy is that the magazine has a switch on the exterior, or the gun body is remodeled and the motor on the magazine side is manually turned and stopped in conjunction with the trigger switch It is the technical level of the gun industry.

  In addition, in the professional magazine Monthly Arms Magazine January 2004 issue P153, there is an advertisement of an electric toy gun having an ultra-high speed continuous fire function capable of firing 40 or more shots per second. In order to cope with such a modified toy gun, bullets must be supplied at a rate of approximately one in 25/1000 seconds. At present, only a power-spring type magazine that constantly pushes up a spherical bullet even when shooting is stopped can supply a spherical bullet to such a toy gun without shortage.

The present applicant has invented a bullet feeding device having a screw structure as shown in FIG. It was an application about 17 years ago when the continuous-fire gas gun began to appear. However, the invention is a large special one that is incorporated in a large-capacity spherical bullet housing portion that is integrally provided in the toy gun body. Unlike the detachable magazine structure part of the actual gun that has become a model, the spherical bullet storage part is a structure that cannot be removed, but can be separated into a detachable magazine and gun body. I couldn't taste the atmosphere like this, for example, quickly removing a magazine that became empty and setting a new magazine on the gun.

FIG. 7 shows the screw structure of the above-mentioned application by the present applicant, Japanese Patent Laid-Open No. 1-163600. How the spherical bullets packed in the space of the magazine part are sucked into the screw part and how the screw is It shows how it will be separated in the department. Although this structure was able to deliver about 10 shots per second, it could not feed more than that.

  As described above, the magazine-side spherical bullet can be adjusted to match the gun-side firing operation just by setting a detachable small magazine on the gun, just like the current mainspring-type multiple bullet magazine. It automatically drives the delivery mechanism instantaneously, delivers only the number of fired spherical bullets, and automatically stops the magazine-side spherical bullet delivery mechanism as the firing operation stops. There is currently no small magazine that has the same outer shape as a real gun magazine. If possible, if the current number of bullets stored in the long spring magazine is 300, for example, 400 rounds of equivalent size, and if the number of bullets stored in the long spring type magazine is, for example, 500 rounds, 600 rounds of equivalent size are used. An increase in the number of bullets that can be fired is desired.

In conventional removable magazines used for gas-type air guns and electric air guns that can continuously fire 10 or more bullets per second (up to about 40 rounds per second), a maximum of 100 rounds (maximum) In the case of using a small detachable magazine that contains spherical bullets of about 1000 shots), the mechanism that sends out the spherical bullets contained in the magazine from the spherical bullet discharge port of the magazine to the chamber inside the gun body is a sprocket There was only one with a built-in driving force source, such as a built-in spring that uses a spring or a built-in motor that uses a sprocket or screw. And in fields such as large springs that can send out the limit ammo capacity of the storage capacity and detachable multi-magnet magazines that do not have a built-in motor, battery, etc., it has become a hot topic in magazines etc. There were no announcements in the past, and there was no hope from Airsoft enthusiasts that they wanted something like that. In other words, a detachable, high-magnification high-speed continuous-fire magazine of a type that does not incorporate a large driving force source has been an undeveloped field that no one has ever thought of.

Japanese Patent Publication No. Hei 4-18237 Published Patent Publication No. Sho 62-1558997 7-12793 JP-A-6-74691 Utility model gazette JP-A-1-163600 JP-A-1-163600 Monthly Combat Magazine February 2004 issue Monthly Arms Magazine January 2004 issue Monthly Arms Magazine June 2004 issue

  The present invention automatically sets the magazine-side spherical bullet feeding mechanism to instantly match the gun-side firing operation by simply setting a detachable magazine on the gun, and the number of shot spherical bullets is set. It is an object to provide a small-sized high-speed multi-shot magazine for high-speed continuous fire that performs spherical bullet feeding just as appropriate and automatically stops the spherical bullet feeding mechanism on the magazine side as the firing operation stops. . A main object of the present invention is to provide a detachable multi-bullet high-speed continuous firing magazine that does not incorporate a driving force source such as a motor, and a toy gun having a power transmission mechanism that continuously drives the magazine.

  The above-mentioned problem has been common sense in the past, and the long spring energy storage capacity to send out the number of bullets scheduled to be fired (or the limit number of bullets in the capacity of the spherical bullet storage part) is pre-rolled manually or with an electric motor. Complete the gun body side so that the trigger switch system can also control the motor drive system on the magazine side, and pull the trigger to drive the magazine side motor or feed the The spherical bullet feed mechanism that can follow the high-speed continuous shooting instantaneously is provided on the magazine side, and the spherical bullet feed mechanism is installed on the large toy gun side. By transmitting and utilizing the driving force of the magazine driving mechanism, the automatic forced bullet supply corresponding to high-speed continuous shooting is achieved.

  According to the combined use of a magazine having a continuous bullet feeding mechanism according to the present invention and a toy gun provided with a drive member for moving a spherical bullet feeding mechanism inside the magazine in the vicinity of the magazine attaching / detaching portion, Even during high-speed continuous firing, it is possible to reliably supply bullets immediately after firing. In the mainspring-type magazine, for example, a long and expensive leaf spring is required to store power for 600 shots, and the work of assembling and winding up the leaf spring having a large repulsive force has been difficult. However, according to the present invention, it is sufficient that the spring accumulating force is at least 2 to 3 shots, and at most about 10 shots, so that the spring may be an inexpensive winding spring and easy to incorporate. Alternatively, according to the embodiment in which the magazine is designed by using only one or two leaf springs or push springs, the product can be made simpler and cheaper. As described above, in the present invention, a power source such as a long mainspring that only sends out the total number of contained bullets or a power source such as a motor or a dry battery is not required on the magazine side. Since it is not necessary to accommodate a long spring or a motor, the internal volume of the magazine can be increased, and the number of accommodated ammunition can be increased accordingly. There is no need to manually roll up hundreds of springs that were painful to the point that the skin of the fingers would be torn. And there is no need to switch on an expensive electric hoisting device, and there is no need to modify the magazine drive device to be linked with the trigger of the toy gun body. You can use the magazine you have. A small magazine that can be used only with the simple attachment and detachment operation similar to conventional spring-lifted magazines and long spring-type magazines, and that starts and stops automatically when shooting starts and stops. A toy gun having a power transmission mechanism for continuously driving the magazine can be provided. Further, the magazine according to the present invention strongly eliminates the phenomenon that spherical bullets gather in a bridge shape in the magazine and do not fall.

  The subject of the present invention is that the magazine has a mechanism for carrying out an appropriate bullet feed capable of instantaneously following the start of high-speed continuous shooting in the magazine, and the magazine drive member for operating the bullet feed mechanism is attached to and detached from the magazine of the toy gun body. It is located near the part. When a magazine is set on a toy gun, the passive member on the magazine side for receiving the power to operate the mechanism in the magazine and the magazine driving member on the toy gun body side are arranged in a state where the driving force can be transmitted. Thus, the bullet feeding mechanism in the magazine can be operated by using the continuous operation mechanism on the toy gun body side. In a large toy gun, the driving force of a mechanism dedicated to driving a magazine arranged inside a hand guard or a stock is output. In a small toy gun, a magazine driving force for driving the magazine is obtained and output from the operation of the continuous shooting mechanism on the gun body side. There is no need to install a power source such as a motor, dry battery, or a large winding spring to send out all the hundreds of spherical bullets on the magazine side, allowing room for internal volume and increasing the magazine capacity. To do. As described above, according to the present invention, the function of reliably sending out a spherical bullet immediately after launching and the function of automatically stopping the operation of the bullet feeding mechanism immediately after the firing operation is stopped can be achieved even with a small magazine. This can be realized in the direction of increasing the number of accommodated ammunition.

Hereinafter, the present invention will be specifically described by way of examples.
The present invention is based on the structure that the gun and the magazine can be separated. The effect of the present invention does not reach a gun having a structure in which a gun and a magazine are integrated. First, important terms are defined in the following description. The magazine drive member is a part belonging to the gun side when separated into the gun and the magazine, and is arranged to transmit the reciprocating motion and rotational motion obtained from the engine part inside the gun to the magazine side The final output component. A passive member is a part that belongs to the magazine when it is separated into a gun and a magazine, and is arranged to receive transmission of reciprocating motion and rotational motion output from the magazine driving member. A part that contacts a member. FIG. 8 is a schematic structural explanatory view of a first embodiment according to the present invention, which is drawn so that it is easy to understand how basic components according to the present invention are arranged as a toy gun. Yes. Since the magazine main body, the spherical bullet storage part, the spherical bullet conveyance path, the spherical bullet inlet, the spherical bullet outlet stopper, etc. are understood by conventional examples, some illustrations are omitted.

  The piston 2 provided with the uneven portion 1 corresponding to the rack gear is always pushed in the direction of the muzzle by the spring 3. A packing 4 is provided around the front portion of the piston 2 to maintain airtightness with the cylinder 5. The rotation drive member 7 having the concavo-convex portion 6 meshing with the concavo-convex portion 1 is rotated in the direction of the arrow 9 by the motor 8 and a series of reduction gear groups. As the rotary drive member 7 rotates, the concave and convex portion 1 of the piston 2 and the concave and convex portion 6 of the rotary drive member 7 start to engage with each other, and the piston 2 is pulled downward. FIG. 8 shows a state in which three ridges and recesses are engaged with each other, and the piston 2 is slightly retracted. A series of reduction gear groups and the rotation drive member 7 are accommodated in a gear box 10. The rotation drive member 7 is provided with a cam portion 11, and the cam contact member 13 is always pressed in the direction of the arrow 14 by the spring 12. FIG. 8 shows a state where the cam contact member 13 is most retracted. It can be seen that when the cam portion 11 further rotates in the direction of the arrow 9 by about 70 degrees, the cam contact member 13 starts to be pushed forward. An engaging portion projection 17 that fits into the recessed portion 16 of the nozzle unit 15 is provided around the most distal portion of the cam contact member 13. The nozzle unit 15 has a substantially cylindrical shape that can move back and forth while being inscribed in the cylinder 5, and the packing 18 keeps airtightness with the cylinder 5. The recess 16 is provided on the outer periphery of the nozzle unit 15. Of course, the same effect can be obtained by providing a pin-like convex portion instead of the concave portion 16 and providing a concave portion into which the pin-like convex portion is inserted instead of the convex portion 17. Alternatively, the nozzle unit 15 and the cam contact member 13 may be an integrally molded product. A nozzle member 19 is incorporated in the center of the nozzle unit 15. A cylinder head 20 is incorporated in front of the cylinder 5, and a nozzle member 19 is incorporated so as to penetrate the cylinder head 20. The main role of the cylinder head 20 is to catch the collision of the piston 2. However, if the inner side of the upper frame 21 is formed so as to hold the front part of the cylinder 5 deeply, the cylinder head 20 is not necessary. The nozzle unit 15 and the nozzle member 19 move integrally. In the figure, the nozzle unit 15 and the nozzle member 19 are drawn so as to have a complicated structure, but since details will be described later, it should be understood that the nozzle unit 15 and the nozzle member 19 move integrally until such explanation is given. I want. In the drawing, the nozzle member 19 is drawn in alignment with the center of the cylinder 5, but it may be more convenient not to position the nozzle member 19 at the center depending on the model of the toy gun. In such a case, the position of the nozzle member 19 may be offset at a position other than the central portion of the nozzle unit 15 in order to match the actual gun as a model.

  FIG. 8 is an explanatory view of the structure of an electric toy gun modeled on a US military officially adopted gun called the M16 series or M4 series. Recently, a model called M4 series is popular, and FIG. 8 shows only the vicinity of the main engine part of M4. The cylinder 5 is accommodated in the gun upper frame 21, and the gear box 10 is accommodated in the lower frame 22. A fixing base 23 is provided at the lower rear portion of the cylinder 5. The upper frame 21, the lower frame 22, the cylinder 5 having the fixing base 23, and the gear box 10 are integrally fixed by pins 24 penetrating all of them. The upper frame 21 and the lower frame 22 are integrally fixed by another pin 25 at the front. Note that the fixing base 23 provided at the lower rear portion of the cylinder 5 is a portion that can be reliably fixed if it is present, and may be omitted.

  A magazine driving member 26 is provided at the lower front portion of the cam contact member 13. On the other hand, a passive member 28 is provided inside the magazine 27 and is disposed so as to mesh with the magazine drive member 26. The magazine driving member 26 and the passive member 28 are the most important members of the present invention. If the cam contact member 13 is moved forward under the situation shown in FIG. 8, it can be seen that the magazine drive member 26 pushes the passive member 28 forward. That is, the power on the toy gun main body side is transmitted to the magazine side through the magazine driving member 26 and the passive member 28.

  The passive member 28 is fixed to the passive member base 29 so as to be rotatable about the shaft 30. The passive member base 29 is guided by the rail portion 31 and can move in the front-rear direction. In the initial state as shown in the figure, the passive member base portion 29 is pushed in the direction of the arrow 33 by the spring 32 and cannot be further retracted by the rail portion 31. The ratchet push bar 34 is connected at its upper end to the crank 35, and the tip of the lower end is pressed against the teeth of the driving ratchet 36. The spring 37 pushes the ratchet push bar 34 in the direction of the arrow 38. The spring 39 pushes up the passive member 28. The spring 40 pushes up the ratchet push bar 34 in the direction of the arrow 41, but the stopper 42 keeps the initial state as shown in the figure. The spring 43 is inserted into the stop ratchet 44 to make the stop position constant or prevent reverse rotation. A driving force ratchet 36 and a sprocket as shown in FIG. 17 are coaxially connected to the driving ratchet 36 to push up the spherical bullet in the direction of the arrow 45. The ratchet push bar 34 is provided with a rack portion 46, and the spur gear 47 is reciprocated by the vertical movement of the ratchet push bar 34. A plurality of protrusions 48 are provided on one surface of the spur gear 47 (on the side of the spherical bullet housing space). The projections 48 prevent a large number of spherical bullets from forming in the magazine, causing a so-called bridge phenomenon, and failing to smoothly enter the bullet sprocket. The projections 48 loosen the lump of spherical bullets in a bridged state. Conventionally, the spur gear 47 provided with a plurality of protrusions 48 is rotated in a certain direction via a gear arranged in the middle by the driving force from the spring of the animal power device as shown in FIG. However, in such a structure, in the second half when the spring power of the mainspring is lost, the driving force becomes ineffective, and if the height of the protrusion is too high, the spur gear 47 can stop the movement of the spherical bullet. Therefore, the height of the protrusion has to be kept extremely low, and therefore the effect of eliminating the bridging phenomenon is low. The current situation of the mainspring type magazine is that it is natural that the bullets are stopped with many stored spherical bullets remaining. While playing a serious game of winning or losing, the magazine sending function suddenly stops, and the sight of wrapping up the crunchy and springs is terrifying. According to the present invention, since the driving force on the main body side also drives the spur gear 47, the force is much stronger than that of the spring spring and the like, and even if the height of the protrusion is slightly increased, the bridge phenomenon is caused. There is no such thing as a losing stop, and the bridge phenomenon will always be resolved strongly from the beginning to the end. As described above, the idea of Japanese Utility Model Laid-Open No. 7-12793 and the invention of Japanese Patent Laid-Open No. 6-74691 are mainly concerned with how to eliminate the bridging phenomenon in the magazine. It shows how important it is for the bullet feeding mechanism in the toy gun magazine to reliably eliminate the bridging phenomenon. The present invention is also effective in eliminating the bridging phenomenon.

  The present invention can also be applied to conventional gas-type fired toy guns. A gas cylinder / piston mechanism may be used as a member for pushing the magazine drive member 26 in the main body. Pulling the trigger, releasing the valve and feeding gas into the gas cylinder advances the piston. If the piston and the magazine driving member 26 are integrally connected, the magazine driving member 26 can be pushed. If a system that discharges the gas in the gas cylinder after the spherical bullet is fired is adopted, the gas cylinder / piston mechanism quickly returns to the initial state by the action of the piston return spring set to be stronger. Alternatively, gas-fired toy guns always have parts that move back and forth along the axial direction of the barrel, so if a magazine drive member is connected to the parts, the back-and-forth movement is transmitted to the magazine to be inserted. can do. This is a so-called gas blowback toy gun, and a member called a bolt reciprocates. This method has been well known for over 15 years. Also, the same gas blow back type toy gun, but a type in which a slide as an exterior part reciprocates has been widely used for about 12 years. It is easier to integrate the magazine drive member into the slide that is the exterior part as compared with the case where the magazine drive member is integrated into the bolt that is the interior part. In addition, among conventional gas-type continuous-fire toy guns, there is a type in which the nozzle portion is moved back and forth strongly by the action of the supplied gas pressure. This is a type in which a nozzle is arranged at the tip of the piston, and the gas that has entered the cylinder pushes the piston forward. Although the nozzle is provided so as to penetrate the piston, a valve is provided in the through hole, and the valve always closes the through hole. (The nozzle unit 15 in FIG. 8 corresponds to a piston, and a valve mechanism is added to the central through-hole portion.) And when the piston is most advanced, the striker member is fed with livestock. The force that has been released is released, and the valve is opened at once. The piston is acted on by a return spring (the image can be considered that the spring 12 in FIG. 8 corresponds to the return spring of the piston), and the piston retracts at a high speed as the gas pressure rapidly decreases. The valve is automatically mechanically closed when retracted to the end. Since the gas pressure is constantly supplied, the piston starts to advance again at the moment when the valve is closed. When the piston moves forward most, the valve is opened at once. This series of movement is repeated. There are a type in which the striker member is incorporated inside the cylinder and a type in which the striker member is incorporated outside the cylinder. The striker member incorporated outside the cylinder can be easily linked to the magazine drive member. Since the range of movement of the nozzle back and forth, that is, the piston stroke, is about 10 mm, the continuous shooting speed is high. Since it is such a structure, as long as the trigger is pulled, the continuous firing does not stop until the gas runs out, and the nozzle portion also continues to move back and forth. Moreover, since the piston and the nozzle portion pushed out by the gas pressure are integrated, the forward force is very strong. If the magazine drive member is linked to the nozzle portion or formed integrally, the magazine drive member is powerfully moved by the gas pressure, and the drive force is transmitted to the passive member in the magazine.

  In the example of FIG. 8, the nozzle member (member that plays a role of pushing the spherical bullet into the barrel packing at the rear end of the barrel) is moved back and forth from the rotational movement of the rotary drive member arranged in the gun body. The movement of the back and forth is taken out and transmitted through. In the following embodiments as well, the present invention mainly uses the basic structure of the electric gun of the system that takes out and transmits the longitudinal movement through the cam from the rotational movement of the rotary drive member arranged in the gun body. Will be explained. However, the structure of an electric gun is not all that. At present, the mainstream method is to extract the longitudinal motion from the rotary motion via the cam and use it. Therefore, the mainstream method is used only for the purpose of explaining the present invention for the sake of simplicity and clarity. In addition to such a mainstream method, the nozzle member (the role of pushing the spherical bullet into the barrel packing at the rear end of the barrel) is taken directly from the longitudinal movement of the piston in the cylinder, directly on the coaxial line. There is also an electric gun of a type that moves the member) that moves forward and backward. In this method, the rear end portion of the nozzle member is sandwiched and pulled by a rubber packing provided at the front end portion of the piston, and is released when the nozzle member is retracted to a set value. Basically, there is no cam and it is a complicated system that makes it difficult to explain the timing of movement, so it is not suitable for use in explaining the present invention. Therefore, the structure of the system is not shown. However, even in such a new type of electric gun, there are members that move back and forth, and there are rotary drive members that rotate to move the piston back and forth. By extracting the driving force from such a member that moves back and forth or a member that rotates, the driving force is transmitted to the magazine driving member, the magazine driving member is moved, and the driving force is transmitted to the passive member on the magazine side. The present invention can be implemented. As a specific application method, there is a method in which a magazine driving member is attached to a nozzle member and moved integrally. Alternatively, the back-and-forth movement of the nozzle member is left to be linked with the piston, and the back-and-forth movement through the cam as represented by FIG. 8 or FIG. 12 from the rotational movement of the rotary drive member for moving the piston back and forth. There is a method of taking out and transmitting the back and forth motion only to the magazine. Thus, the present invention can also be applied to an electric gun that does not take out the back-and-forth movement of the nozzle member from the rotational movement of the rotary drive member. As another method, electric air guns and gas guns modeled on large machine guns equipped on tanks have room, so a dedicated motor for driving the magazine is separate from the piston drive. It can be installed in the hand guard or in the empty space of the engine department. If the wiring is arranged so that the dedicated motor starts when the trigger is pulled and stops when the trigger is released, the rotational force and reciprocating motion can be extracted from the dedicated motor. If the reciprocating motion can be taken out, for example, a system as shown in FIG. 8 may be constructed separately from the piston drive system. If the rotational motion can be taken out, for example, a system as shown in FIG. 67 or 68 may be constructed separately from the piston drive system. Since the dedicated motor only drives the magazine, a small powerless motor is sufficient. By so doing, the present invention can be applied to gas guns and the like.

  FIG. 9 shows a state in which the rotational drive member 7 has rotated to some extent in the direction of the arrow 64 and the cam portion 11 has pushed the cam receiving bar 13 forward. A stopper 49 for preventing the spherical bullet from excessively rising is jumped up in the direction of the arrow 50 by the nozzle member 19. The spherical bullet 51 is pushed by the tip of the nozzle member 19 and pushed into the barrel packing 52. In general, the rear end of the barrel 53 is inserted into the barrel packing 52. In the figure, only a part of the barrel 53 is drawn, and the front part is not shown. When the cam receiving bar 13 is pushed in the direction of arrow 54, the magazine drive member 26 pushes the passive member 28 in the direction of arrow 55, and the spring 12 pushing the cam contact member 13 rearward is compressed. A convex portion 56 is provided at the lower portion of the passive member base portion 29 holding the passive member 28, and pushes the upper portion of the crank 35 in the direction of the arrow 57. The ratchet push bar 34 whose upper end is connected to the crank 35 is pushed in the direction of the arrow 58A, and the drive ratchet 36 is rotated in the direction of the arrow 58B by one tooth. When the ratchet push bar 34 is pushed down, the rack portion 46 rotates the spar gear 47 in the direction of the arrow 65. (When the ratchet push bar 34 is pushed back in the direction of the arrow 41 by the spring 40, the rack portion 46 rotates the spur gear 47 in the direction opposite to the arrow 65.) The tip convex portion of the spring 43 is the stop ratchet 44. The recess is difficult to insert, the stop position is fixed, and reverse rotation is prevented. A driving force ratchet 36 and a sprocket as shown in FIG. 17 are connected to the driving ratchet 36 to push up the spherical bullet in the direction of the arrow 45. There is an important point to be noted here. The sprocket 59 for sending out a spherical bullet shown in FIG. 17 can take 20 bullets in the outer peripheral portion, whereas the driving ratchet 36 shown in FIG. 9 has only 16 teeth. Since the magazine driving member 26 performs one reciprocating motion for each firing, the ratchet push bar 34 interlocked with the passive member 28 also performs one reciprocating motion. Each time the driving ratchet 36 is rotated by one tooth, it rotates once by 16 firings. An inner end of a spring spring 60 as shown in FIG. 17 is attached to the central axis of the driving ratchet 36, and an outer end 61 of the spring spring 60 is formed in a substantially arc shape, and is formed on the inner peripheral portion of the sprocket 59. A plurality of recessed portions 62 are provided. (Although ten concave portions 62 are drawn, the number is not important.) In the feed mechanism configured as shown in FIG. 17, the rotational force of the central shaft 63 of the driving ratchet 36 is transmitted via the mainspring spring 60. It is transmitted to the inner periphery of the sprocket 59. With one rotation of the driving ratchet 36, the sprocket 59 also makes one revolution. Therefore, if there is no restriction on the outlet of the magazine, 20 bullets should be sent out with each revolution. However, when a magazine is set on a toy gun, the outlet is blocked by the stopper 49 as shown in FIG. 8, or the outlet is blocked by the nozzle member 19 as shown in FIG. Actually, only 16 bullets are sent out in 16 shots. Since only 16 bullets are sent out even though the driving force for delivering 20 bullets is given, the springs 60 absorb the 4 shots that are the difference. Assuming that the spring capacity of the mainspring 60 is, for example, only 20 bullets, if the driving force is absorbed by 4 shots per rotation, the limit of the power capacity is reached after 5 rotations. When a driving force exceeding the limit of the animal power capacity is further applied, the outer end 61 of the spring spring 60 formed in a substantially arc convex shape may be caught in a recess provided in the inner peripheral portion of the sprocket 59. It cannot be done and will eventually come off the recess. However, since a plurality of recesses are provided in the inner peripheral portion of the sprocket 59, the outer end 61 of the mainspring spring 60 can immediately fit into the next recess or a recess that has passed several recesses. That is, after a certain amount of force is accumulated, the outer end 61 of the spring spring 60 moves one after another so as to walk over the recess provided in the inner peripheral portion of the sprocket 59. The function as a kind of sliding clutch is exhibited. If it is desired to reduce the limit of the animal power capacity to 200 shots, a large sprocket and a large spring spring as shown in FIG. 17 are required. In the present invention, the limit of the animal power capacity is 10 shots or less. Therefore, it is sufficient to use a small sprocket and a short and small spring as shown in FIG. The smaller the sprocket, the greater the magazine capacity.

  A sprocket type bullet feeding device has a drawback that when a sprocket rotates at high speed, a situation where a spherical bullet does not normally enter the spherical bullet receiving portion on the outer periphery of the sprocket sometimes occurs. Therefore, in a sprocket type bullet feeding device that is not equipped with a livestock power device, shots often occur during continuous shooting. Even if it is about 2 to 3 shots, if it is equipped with a livestock power device, even if color feed occurs at the sprocket, the livestock is released at the next moment it occurs and the sprocket is instantaneous It rotates and replenishes the color feed. If the bullet feed device in the magazine on the passive side mechanically sends out only one shot in a one-to-one manner by transmitting the driving force once by the magazine drive member, 5 shots per second The problem is unlikely to occur during low-speed continuous fire of about 6 shots, but there is a risk that many shots will occur during high-speed continuous fire. A clutch that works when a livestock device reaches the limit of livestock power, provided with a livestock power device between a passive member in the magazine and a bullet feed device using, for example, a sprocket (or a bullet feed device using a screw or propeller). Providing a mechanism is effective from the viewpoint of preventing shots. If it was designed so that a force of one or more shots could be transmitted to the bullet feeding device in the magazine by one transmission of the driving force by the magazine driving member, it was not consumed by actual bullet feeding Part of the driving force is stored in the animal power device, and the excess driving force supplied in excess of the animal power capacity is consumed by the clutch mechanism.

  The bullet feeding device can be configured by using a sprocket, a screw, a propeller, etc., which will be described in detail later. In addition, there is a method of feeding an endless belt with protrusions over two pulleys, but since it has substantially the same effect as using a sprocket, illustration and explanation are omitted.

  FIG. 10 shows a state when the magazine is about to be inserted when the gun-side firing mechanism stops in a state other than the initial state in the first embodiment. The cam part 11 has shown the state which has pushed the cam contact member 13 to the front. If the trigger is released while fully automatic shooting (continuous shooting) with an electric gun, it may stop in the state shown in FIG. Sometimes it stops. Or sometimes it stops in the middle state. When the magazine 27 is inserted in the direction of the arrow 66 when stopped in such a state other than the initial state, the upper portion of the passive member 28 inside the magazine 27 is connected to the magazine drive member 26 on the gun body side. Pushed by the tip and pushed down in the direction of arrow 67. The magazine 27 is fixed at a fixed position of the gun body by a magazine lock member (not shown).

  For example, when the magazine is set so as to be in the state shown in FIG. 10 and the trigger is pulled, the rotation drive member 7 rotates in the direction of the arrow 68, and the nozzle unit 15 and the nozzle as shown in FIG. The member 19 is in the most retracted state. And the magazine drive member 26 which moves integrally with the nozzle unit 15 is also most retracted. When the magazine driving member 26 is most retracted, the rear upper end of the passive member 28 is disengaged from the front end of the magazine driving member 26, and the passive member 28 is pushed by the spring 39 and rotates about the shaft 30, as shown in FIG. Return to the initial position as shown. When the rotary drive member 7 further rotates in the direction of the arrow 68, the state shown in FIG. 9 is obtained and the bullet feeding mechanism in the magazine works normally.

   As described above, in the present invention in which the bullet feeding device in the magazine functions by moving the passive member 28 back and forth, the magazine 27 does not matter where the magazine driving member 26 is stopped. When the passive member 28 is pushed by the tip of the magazine drive member 26, the passive member 28 rotates around the shaft 30 as shown in FIG. 10 or escapes, or as shown in FIG. In addition, it is better to have an escape mechanism such as to escape so as to translate downward. Alternatively, as shown in FIGS. 37, 38, and 70, it is better to provide a relief mechanism on the magazine drive member side.

  FIG. 11 shows that in the embodiment of FIG. 9 and the like, the magazine drive member 26 has completed the forward movement without being normally fed, and the nozzle member 19 has caught the abnormal spherical bullet 69 so that it can move forward. The state of not being drawn is drawn. The piston 2 moves forward at a high speed and collides with a cushion member 70 bonded to the rear end portion of the nozzle unit 15. If the nozzle member 19 is configured integrally with the nozzle unit 15, if the magazine drive member 26 continues to move forward with the nozzle member 19 sandwiching an abnormal spherical bullet 69, the nozzle tip may be broken, A situation may occur in which the engaging portion projection 71 at the upper front portion of the magazine driving member 26 is broken. Assuming that the engaging projection 71 at the upper front of the magazine drive member 26 is broken, the nozzle unit 15 configured integrally with the nozzle member 19 cannot move forward and is separated from the rear end of the cylinder head 20. It stops at the position. In such a state, if the piston 2 moves forward at a high speed and collides with the cushion member 70, the nozzle tip portion crushed the abnormal spherical bullet 69. Naturally, the nozzle tip portion and the barrel packing 52 are crushed. It will fall into the worst situation that the rear end part of the car breaks. It is the spring 72 for preventing nozzle destruction that prevents such a situation from occurring. Even when the nozzle member 19 enters the state shown in FIG. 11 such that the abnormal spherical bullet 69 is sandwiched by the action of the spring 72, only the nozzle member 19 is retracted, and the other members repeat normal operations. Will be able to. In the next cycle, the abnormal spherical bullet 69 is pushed up, moved forward, and fired. Even if an abnormal situation occurs in which a damaged spherical bullet or stone is caught by the bullet feeding nozzle portion mainly composed of the nozzle member 19, the nozzle unit 15, and the spring 72 for preventing the nozzle destruction. The various members can be prevented from being broken. It should be noted that the nozzle member 19 is precisely a unit that is manufactured by press-fitting and integrating a front part and a rear part. A spring 72 is incorporated before press-fitting. For the purpose of preventing air leakage at each part, a rubber packing 18 is disposed on the outer periphery of the nozzle unit 15, a packing 73 is disposed on the outer periphery of the nozzle member 19, and a packing 4 is disposed on the outer periphery of the tip of the piston 2. Yes.

  In the first embodiment described with reference to FIGS. 8 to 11, the magazine drive member 26 is driven by taking out the linear motion in the front-rear direction from the continuous firing mechanism inside the gun body, and the drive force is transmitted to the passive member 28 in the magazine. In this embodiment, the passive member 28 is also linearly moved in the front-rear direction. In this embodiment, the linear motion of the passive member 28 in the front-rear direction is converted into the linear motion in the vertical direction in the magazine, and then converted into a rotational motion to function the bullet feeding mechanism. 8 to 11, the basic structure of the electric gun that converts the rotational motion into a linear motion is depicted as the continuous fire mechanism inside the gun body, but the continuous fire mechanism inside the gun body may be a gas type. Good. A generally known gas-type continuous firing mechanism has a cylinder part and a piston part, and either the cylinder part or the piston part moves linearly, so a magazine drive member is attached to either the cylinder part or the piston part. By linking them, the same mechanism as that of the first embodiment can be easily made.

  In the first embodiment described with reference to FIGS. 8 to 11, the passive member is pushed forward when the magazine driving member moves forward, and the bullet feeding device in the magazine functions. Another embodiment of the present invention of the type in which the passive member is pushed backward when the member is retracted and the bullet feeding device in the magazine functions is shown.

  FIG. 12 is a schematic structural explanatory view of a second embodiment according to the present invention. The piston 74 provided with the concavo-convex portion 1 corresponding to the rack gear is always pushed in the direction of the muzzle by the spring 75. A packing 76 is provided around the front portion of the piston 74 to maintain airtightness with the cylinder 77. The rotation driving member 80 having the concavo-convex portion 79 meshing with the concavo-convex portion 78 of the piston 74 is rotated in the direction of the arrow 82 by the motor 81 and a series of reduction gear groups. As the rotary drive member 80 rotates, the concave and convex portion 78 of the piston 74 and the concave and convex portion 79 of the rotary drive member 80 begin to engage with each other, and the piston 74 is pulled downward. The rotation drive member 80 is provided with a cam pin 83. The cam contact member 85 is constantly pressed in the direction of the arrow 86 by the spring 84. FIG. 12 shows a state immediately before the cam pin 83 starts to push the cam contact member 85, and shows a state where the cam contact member 85 is most advanced.

  The cam contact member 85 is formed integrally with the arm member 87, and the front upper portion of the arm member 87 is formed integrally with the bullet feeding nozzle member 88, or the arm member 87 and the bullet feeding nozzle member 88 are integrally formed. It is connected so that it can move. The front lower portion of the arm member 87 is formed integrally with the magazine drive member 89, or is connected so that the arm member 87 and the magazine drive member 89 can move integrally. A cam contact member 85, an arm member 87, and a magazine drive member 89 are integrally formed at the bottom of FIG. 12, and a concave portion for engagement is formed in the bullet feeding nozzle member 88. The figure in which the joint convex part was formed is arranged. Although all the members may be integrated, the cam contact member 85, the arm member 87, and the magazine drive member 89 are integrally formed, and an engaging convex portion is formed at the upper front end of the arm member 87. Then, the new magazine according to the present invention can be used by processing only a part of the gear box of an old type electric air gun that has been purchased by a consumer in the past and re-installing the parts. This is for the benefit of the consumer, and the cam contact member 85, the arm member 87, and the magazine drive member 89 are integrally formed, and the convex portion for engagement is formed at the upper front end of the arm member 87. Part of the invention. However, if the rights of the present invention are written in the claims, the claims become too complex, so no claims are made in this application.

A passive member 91 is disposed inside the magazine 90 and is disposed so as to mesh with the magazine drive member 89. If the cam contact member 85 and the arm member 87 are moved rearward under the situation as shown in FIG. 12, it can be seen that the magazine drive member 89 pushes the passive member 91 rearward. That is, the power on the toy gun body side is transmitted to the magazine side via the magazine drive member 89 and the passive member 91.

  The passive member 91 is fixed to the passive member base 92 so as to be rotatable about a shaft 93. The passive member base 92 is guided by the rail portion 94 and can move in the front-rear direction. In the initial state as shown in the figure, the passive member base 92 is pushed in the direction of the arrow 96 by the spring 95 and cannot be further retracted by the rail portion 94. The ratchet push bar 97 has an upper end connected to the crank 98 and a tip end portion of the lower end pressed against a tooth portion of the driving ratchet 99. The spring 100 pushes the ratchet push bar 97 in the direction of the arrow 101. The spring 102 pushes up the passive member 91. The spring 103 pushes up the ratchet push bar base portion 105 in the direction of the arrow 104, but the initial state as shown in the figure is maintained by the stopper 106. The tip of the spring 107 is hard to ratchet 99 to make the stop position constant or prevent reverse rotation. A driving force ratchet 99 and a sprocket as shown in FIG. 17 are coaxially connected to the driving ratchet 99 to push up the spherical bullet in the direction of the arrow 108. The ratchet push bar 97 is provided with a plurality of protrusions 109. As the ratchet push bar 97 moves up and down, the projection 109 also moves up and down. The projection 109 prevents a large number of spherical bullets from forming in the magazine, causing a so-called bridge phenomenon, and being unable to smoothly enter the bullet sprocket. The lump and the projections 109 loosen up the spherical bullets in a bridged state. According to the present invention, since the projection 109 is driven by the driving force on the main body side, the force is very strong. There is nothing wrong, and from the beginning to the end, it will always continue to solve the bridging phenomenon powerfully.

  The first point is that the upper end portion of the ratchet push bar 97 is inserted into the lower end portion of the ratchet push bar base portion 105 so that the ratchet push bar 97 does not come out, and the spring 110 is disposed between the ratchet push bar 97 and the ratchet push bar base portion 105. This is a slightly different point from the embodiment. Such a configuration eliminates the need for an animal power device as shown in FIG. The need for an expensive and long plate-shaped spring spring also reduces the material cost and eliminates the need for a difficult plate-shaped spring spring assembly process, greatly contributing to cost reduction.

  FIG. 13 shows a state in which, in the second embodiment, the rotation drive member 80 is rotated to some extent in the direction of the arrow 82, and the cam pin 83 pushes the cam contact member 85 in the direction of the arrow 111 and is retracted most. In the following drawings including FIG. 13, illustrations of the outer shape of the gun, the motor, the gear group for deceleration, and the like are omitted unless particularly necessary.

  As the cam contact member 85 is retracted, the arm member 87, the bullet feeding nozzle member 88, and the magazine driving member 89 are integrally retracted in the direction of the arrow 111. When the bullet feeding nozzle member 88 moves backward, a space is formed, and the spherical bullet 112 is pushed up to the tip of the bullet feeding nozzle member 88. The magazine drive member 89 pushes the passive member 91 in the direction of the arrow 111, and the spring 84 applied to the arm member 87 is extended. A convex portion 113 is provided at the lower portion of the passive member base portion 92 holding the passive member 91, and pushes the upper portion of the crank 98 in the direction of the arrow 114. The ratchet push bar base portion 105 whose upper end is connected to the crank 98 is pushed in the direction of the arrow 115, and the ratchet push bar 97 rotates the drive ratchet 99 by one tooth in the direction of the arrow 116. When the 16-tooth ratchet 99 is rotated by one tooth, the sprocket 117 that sends out 20 rounds of spherical bullets in one rotation tries to send out 1.25 rounds of spherical bullets. The spring 110 absorbs the movement of the extra 0.25 shots.

  In the first embodiment, when the magazine driving member 26 moves forward, that is, when the nozzle member 19 moves forward, the ratchet is rotated to feed bullets. The sprocket could not be rotated even if the ratchet was closed and the ratchet was rotated. Accordingly, the ratchet and the sprocket are separate parts, and it is necessary to incorporate a livestock mechanism between the ratchet and the sprocket.

  However, in the second embodiment, when the magazine drive member 89 moves backward, that is, when the bullet feed nozzle member 88 moves backward, the ratchet is rotated so that the bullet is fed. The bullet nozzle member 88 opens the spherical bullet outlet, and the ratchet and sprocket can be rotated simultaneously. Therefore, the ratchet and the sprocket can be integrated, and it is not necessary to incorporate a livestock mechanism between the ratchet and the sprocket. If the rate of fire is about 10 to 15 shots per second, it can be adequately handled without shooting, which is effective when providing an inexpensive product for children. However, in a high-class machine for adults that shoots 30 or 40 shots per second, a situation where spherical bullets cannot enter between the sprocket teeth inevitably occurs, so as in the first embodiment, If the ratchet and the sprocket are separate parts and the system that incorporates the animal power mechanism between the ratchet and the sprocket is adopted, there is no doubt that the occurrence of bombardment can be prevented. The stock raising mechanism may be incorporated depending on the purpose of the product to be provided.

  FIG. 14 shows a state when the magazine is to be inserted when the gun-side firing mechanism stops in a state other than the initial state in the second embodiment. It can be clearly seen that the escape mechanism substantially similar to the content described in FIG. 10 is functioning.

  FIG. 15 is an explanatory diagram of a structure of a general magazine, viewed from the front, for explaining a stopper of a spherical bullet discharge port portion. The spherical bullet 118 is pushed up in the direction of arrow 119 by the bullet feeding mechanism in the magazine. The stopper 120 is pressed in the direction of the arrow 122 by the action of the spring 121, and the spherical bullet 118 cannot come out of the discharge port. In FIG. 15, two sets of the stopper 120 and the spring 121 are depicted, but one set may be used.

  FIG. 16 is a structural explanatory view seen from the front direction for explaining a stopper opening state when the magazine of FIG. 15 is set on the gun body side. A pipe portion 123 is provided at a lower portion of the chamber on the gun body side, and a tip end portion 124 thereof is slightly narrowed, and an outer peripheral portion is tapered. When the tip end portion 124 enters the inner tapered portion of the stopper 120, the stopper 120 is pushed and expanded in the direction of the arrow 125. The passage is opened, and the spherical bullet 118 is pushed up by the bullet feeding mechanism in the magazine and pushed up in the direction of the arrow 126.

  FIG. 17 is an explanatory diagram of the structure for explaining the stock raising mechanism and the bullet feeding mechanism of a conventional general spring-type magazine. An inner end of a mainspring spring 60 is attached to a central shaft 63 of a driving ratchet (not shown), and an outer end 61 of the mainspring spring 60 is formed in a substantially circular arc shape. It fits in one of the recessed parts 62 provided individually. (Although ten concave portions 62 are drawn, the number is not important.) In the feeding mechanism configured as shown in FIG. 17, the rotational force of the central shaft 63 of the driving ratchet is transmitted through the mainspring spring 60 to the sprocket. 59 is transmitted to the inner periphery of 59. The situation that has reached the limit of animal power has already been explained. The biting prevention member 127 is always pushed in the direction of the arrow 128 by a spring or the like. And it always moves with rattling, preventing the biting of spherical bullets. When the sprocket 59 rotates in the direction of the arrow 129, the spherical bullet is pushed out in the direction of the arrow 130. The smaller the sprocket, the greater the magazine capacity.

  FIG. 18 is an explanatory diagram of a structure for explaining a livestock knob of a magazine having the same mechanism as that of FIG. The inner end of the mainspring 60 is attached to the central shaft 63 of the driving ratchet 131, and the outer end 61 of the mainspring spring 60 is formed in a substantially arc shape, and a plurality of concave portions provided on the inner peripheral portion of the sprocket 59. One of 62 is stuck. A part of the driving ratchet 131 shown in FIG. 18 protrudes slightly from the lower part of the magazine, and the spring spring 60 is wound up and squeezed by rotating it by rubbing with a finger in the direction of the arrow 132. A spring 133 for preventing reverse rotation acts on the driving ratchet 131. Compare Figure 18 with Figure 12. The conventional driving ratchet 131 in FIG. 18 is large and is rubbed with a finger about 150 to 200 times and rotated to produce enough power to feed all the contained bullets, whereas the ratchet in FIG. No. 99 is an automatic hoisting system in which the driving force on the gun body side is transmitted, and only one ratchet tooth is sent by one rotation of the rotary drive member 80, and bullet feeding or stock raising is performed. As shown in Fig.18, if you prepare three magazines that require a finger roll-up as a spare in a survival game, etc., add one for the main body set and add a total of four magazines. , It is necessary to roll up everything before the game starts. The finger scrubbing operation at that time is about 600 to 800 times. This is not a task that even adults can withstand. The work is accompanied by severe pain that causes bleeding on soft children's fingers. According to the present invention, a part of the ratchet is not exposed to the outside of the magazine to destroy the real image, and the finger is not hurt by rubbing the ratchet ratchet hundreds of times.

  FIG. 19 is a structural explanatory diagram for explaining a magazine when the present invention is adopted. In the conventional magazine shown in FIG. 18, a long mainspring having a capacity capable of discharging all of the accommodated bullets is basically used. Therefore, a large space is required on the inner peripheral side of the sprocket 59, and the sprocket 59 becomes large. In general, in a magazine of an M16 type gun, the sprocket 59 is sized so that 20 shots can be placed on the outer periphery, and in FIGS. Compared to that, the magazine in the case of employing the present invention in FIG. 19 is drawn in such a size that 10 shots can be arranged on the outer periphery. The spring spring used is small, and about 10 shots are sufficient. Compare Figure 17 with Figure 19. It can be clearly seen that if the sprocket can be made smaller, the number of ammunition is increased. According to the present invention, the number of accommodated ammunition can be increased.

  In the first and second embodiments described with reference to FIGS. 8 to 14, when the magazine drive member moves back and forth, the passive member also moves back and forth, and the bullet feeding device in the magazine functions. However, another embodiment of the present invention of the type in which the passive member moves up and down when the magazine driving member moves back and forth and the bullet feeding device in the magazine functions will be described.

  FIG. 20 is a schematic structural explanatory view of a third embodiment according to the present invention. The mechanism on the gun body side is basically the same as in the second embodiment shown in FIG. In addition, the mechanism in the magazine shown in FIG. 12 is converted from a linear motion in the front-rear direction to a linear motion in the vertical direction using a crank, and is converted into a linear motion in the vertical direction using a component having a tapered portion. Only the conversion is performed, and the mechanism beyond the ratchet push bar is drawn in the same manner as in the second embodiment shown in FIG.

  A magazine driving member 135 is provided at the lower front portion of the arm member 134. A passive member 137 is disposed inside the magazine 136. The taper portion below the magazine drive member 135 and the taper portion above the passive member 137 are disposed so as to contact each other. If you look at the mechanical space, you may be somewhat separated. In FIG. 20, the taper portion below the magazine drive member 135 and the taper portion above the passive member 137 are drawn with an inclination of approximately 45 degrees, but the angle is not limited to 45 degrees. Further, the tapered portion may have a curved portion instead of a linear shape. Since the passive member 137 is guided by the guide members 138 and 139, it can move only in the vertical direction. The passive member 137 is pushed in the direction of the arrow 141 by the spring 140. The upper end of the ratchet push bar 142 is fitted in the A guide groove 143 of the passive member 137 and is pushed downward by the spring 144.

  FIG. 20 shows an initial state after firing in which the piston 145 has completed the forward movement. The magazine driving member 135 and the bullet feeding nozzle member 146 are in the most advanced state. The magazine drive member 135 has no effect on the passive member 137. From this state, when the rotational drive member 147 rotates in the direction of the arrow 148, the state as shown in FIG. 21 is reached. 20, the cam contact member 134B, the arm member 134A, and the magazine drive member 135 are integrally formed, and the engaging nozzle recess 146 is formed on the upper end of the front portion of the arm member 134A. The figure in which the joint convex part was formed is arranged. Although all the members may be integrated, the arm member 134A, the cam contact member 134B, and the magazine drive member 135 are integrally formed, and an engaging convex portion is formed at the upper front end of the arm member 134A. Then, the new magazine according to the present invention can be used by processing only a part of the gear box of an old type electric air gun that has been purchased by a consumer in the past and re-installing the parts. This is for the benefit of the consumer, and the arm member 134A, the cam contact member 134B, and the magazine drive member 135 are integrally formed, and the engagement convex portion is formed at the upper front end of the arm member 134A. It is a part of the invention, but is not described in the claims.

  FIG. 21 shows a state in which the rotation drive member 147 rotates to some extent in the direction of the arrow 148, the cam pin 149 pushes the cam contact member 134B in the direction of the arrow 151, and the arm member 134A is retracted most in the third embodiment. Indicates. The magazine driving member 135 and the bullet feeding nozzle member 146 are also most retracted in the direction of the arrow 152. The taper portion below the magazine driving member 135 and the taper portion above the passive member 137 come into contact with each other, and the passive member 137 is pushed by the magazine driving member 135 and falls in the direction of the arrow 153. The ratchet push bar 142 is pushed down in the direction of the arrow 153 by the passive member 137 via the spring 144.

  When the taper portion below the magazine driving member 135 and the taper portion above the passive member 137 are both 45 degrees, if the movement distance of the magazine driving member 135 is 8 mm, a little clearance is obtained. Even if it sees, the moving distance of the passive member 137 is also about 8 mm. Naturally, the ratchet push bar 142 is also pushed down by about 8 mm. However, in practice, the tip of the ratchet push bar 142 can push only one tooth of the ratchet 154. The movement width is about 4 mm. There is a difference of about 4 mm between 8 mm, which is the approximate movement distance of the passive member 137, and 4 mm, which is the approximate movement distance of the tip of the ratchet push bar 142. If the ratchet 154 is not equipped with a stock raising mechanism, the difference of 4 mm is absorbed by the spring 144. If the ratchet 154 is equipped with a livestock mechanism, the difference of 4 mm is stored in the livestock mechanism as a surplus. When the limit of the livestock mechanism is reached, the remaining power is released by the clutch mechanism in the livestock mechanism. If the driving ratchet 154 is equipped with a livestock force mechanism, the sprocket will momentarily rotate even if the spherical bullets are not well inserted between the sprocket teeth as in the spaces 155 and 156. Therefore, no space is generated in the spherical bullets 157 above the sprocket teeth and the upper row of the spherical bullets, and the shooting is prevented.

  In the third embodiment, even if the magazine is set with the magazine drive member 135 and the bullet feed nozzle member 146 being most advanced, there is no problem as shown in FIG. Even if the magazine is set with the nozzle member 146 in the most retracted state, there is no problem as shown in FIG. According to the present invention using a taper (straight line or curved slope) for transmission of driving force, the passive member 137 is in a state where it can be lowered at any time. A magazine can be set even in a difficult situation.

  FIG. 22 is an external view of a magazine in the third embodiment. When the magazine is empty and a spherical bullet is inserted into the magazine with an insertion image as shown in FIG. 17, the sprocket has not yet rotated. Therefore, a new spherical bullet is placed at the position of the spherical bullet 158 shown in FIG. I can't enter. Then, about 35 shots from the position of the spherical bullet 158 to the spherical bullet 159 in the vicinity of the outlet of the magazine do not exist. If you set the magazine on the gun and start shooting in such a situation, the first 35 shots (actually about 28 shots because there is a difference in the number of sprocket teeth and ratchet teeth) will be shot End up. If the magazine has been used even once, there will always be at least 14 bullets from the position of the spherical bullet 157 to the position of the spherical bullet 159. That itself is unpleasant. However, according to the third embodiment in which a part of the passive member 137 is exposed above the magazine, as shown in FIG. 22, the manual push operation in the direction of the arrow 160 is performed about 28 times. It is easy to fill approximately 35 spherical bullets from the position of the spherical bullet 158 shown in FIG. In addition, the numerical value of about 28 times is a numerical value for the first use, and according to the embodiment provided with the animal power mechanism, from the second time, the manual operation of about 11 to 12 times can be performed for the space portion. Filling is complete. The area of the upper surface portion of the passive member 137, which is a portion pushed by hand, is also sufficiently large and does not hurt. This is a significant effect compared to the conventional magazine requiring a ratchet winding operation with nearly 200 pains each time it is used. Next, another embodiment of the present invention in which the passive member moves up and down when the magazine drive member moves back and forth and the bullet feeding device in the magazine functions will be described.

  FIG. 23 is a schematic structural view of a fourth embodiment according to the present invention. The mechanism on the gun body side is basically the same as in the first embodiment shown in FIG. Also, the mechanism in the magazine is drawn as if the passive member 137 in FIG. The mechanism beyond the ratchet push bar is basically the same as that of the third embodiment shown in FIG.

  The feature of the fourth embodiment is that a rotating body is used for the magazine driving member 161. A rotating body is used with respect to a mating member having a taper so that a large friction is generated between the tapers and the force is not lost. In FIG. 23, a rotating body is used for the magazine driving member 161. On the contrary, the same effect can be obtained by providing the magazine drive member 161 with a taper portion and arranging a rotating body above the passive member, but the embodiment can be easily understood from FIG. Since it is an example, illustration is omitted.

  The cam portion 163 provided on the rotation drive member 162 is not yet in a position to push the cam contact member 164 forward. The piston 165 is slightly retracted by meshing with the concavo-convex portion on the outer periphery of the rotation drive member 162. The nozzle unit 166, the nozzle member 167, and the magazine drive member 161 move integrally and are in the most retracted position. The rotary drive member 162 has not yet performed any action on the passive member 168 in the magazine. Eventually, the rotation drive member 162 rotates in the direction of the arrow 169, resulting in a state as shown in FIG.

  FIG. 24 is a schematic structural explanatory diagram of a fourth embodiment according to the present invention. When the rotation driving member 162 rotates in the direction of the arrow 169, the cam portion 163 pushes the cam contact member 164 in the direction of the arrow 170. Accordingly, the magazine driving member 161 also moves in the direction of the arrow 171. Since the B guide groove 172 of the passive member 168 in the magazine is guided by the guide members 173 and 174 fixed to the magazine, it can only move in the vertical direction and is pushed down in the direction of the arrow 175. The subsequent related operations are basically the same as those of the third embodiment of FIG. However, in the fourth embodiment, as described in the first embodiment of FIG. 9, the drive ratchet 176 is rotated in the direction of the arrow 177 at the timing when the nozzle member 167 is blocking the outlet of the spherical bullet. Since a bullet is used, it is necessary to provide a livestock mechanism between the driving ratchet 176 and the sprocket 178.

  FIG. 25 is an external view of a magazine in the fourth embodiment. Similar to the magazine in the third embodiment shown in FIG. 22, the initial filling of the spherical bullet can be easily performed by performing the manual pushing operation in the direction indicated by the arrow 179 about 28 times. Compared to the magazine in the third embodiment of FIG. 22, it can be seen that the positional relationship of the inclined portions is reversed.

  Next, another embodiment of the present invention of a type in which the passive member is pushed down when the magazine driving member using the rotating body moves back to function the bullet feeding device in the magazine will be described.

  FIG. 26 is a schematic structural explanatory view of a fifth embodiment according to the present invention. The mechanism on the gun body side is basically drawn substantially the same as in the fourth embodiment shown in FIG. The only difference is the location of the magazine drive member. Compared to FIG. 23, it is arranged slightly forward. The basic mechanism in the magazine is almost the same as that of the third embodiment shown in FIG. There is a slight difference in the position and shape of the protruding part that protrudes from the magazine.

  The feature of the fifth embodiment is that a curve is used for the inclined portion of the passive member 180, and an impact is generated when the passive member 180 starts to move by being pushed by the magazine drive member 181 using a rotating body. Therefore, a smooth movement can be expected as compared with the fourth embodiment.

  In the fourth embodiment described in FIGS. 23 to 24, the passive member is lowered when the magazine driving member moves forward, and the bullet feeding device in the magazine functions. In FIG. 27, conversely, when the magazine driving member 181 moves backward, the passive member 180 is drawn down. A force for moving the magazine driving member 181 rearward is obtained from the spring 182. When the cam contact member 183 is pushed by the cam portion 184 and moves in the direction of the arrow 185, the spring 182 is contracted and the force is stored. 27, the magazine driving member 181 that moves integrally with the cam contact member 183 moves rearward, and the passive member 180 is lowered. As described in the third and fourth embodiments, the bullet feeding mechanism functions by lowering the passive member. Various arrows depicted in FIGS. 26 to 27 indicate the direction of movement of each component and the direction in which the spring force is applied. Various arrows have already been described in the first to fourth embodiments and can be fully understood.

  Next, in the electric air gun of the type in which the cylinder moves back and forth, when the magazine drive member moves backward integrally with the cylinder, the passive member is pushed down to make the bullet feeding device in the magazine function. An example is shown.

  FIG. 28 is a schematic structural explanatory view of a sixth embodiment according to the present invention. The convex portion 187 provided at the upper rear end portion of the piston 186 cannot be further advanced by the stopper 188 provided on the gear box or the gun body. A cylinder head 190 is fixed to the front portion of the cylinder 189, and a nozzle member 191 is provided on the cylinder head 190. A magazine driving member 192 is provided at the lower front portion of the cylinder 189, and a cam contact member 194 is provided at the rear portion of the arm member 193. A spring 195 acts on the arm member 193, and the arm member 193 is always pulled forward. A push spring may be used in place of the tension spring in order to always apply a resilient force forward. The use of the push spring has already been described with reference to FIG.

  The front portion of the cylinder 189 cannot be further advanced by a stopper 196 provided on the gear box or the gun body. This type in which the cylinder moves back and forth is suitable for a small electric air gun. Since it is small in size, the cylinder 189, the cylinder head 190, the nozzle member 191, the magazine drive member 192, the arm member 193, and the cam contact member 194 can be made into one cylinder unit molded product. In FIG. 28, the convex portion 187 is provided at the upper portion of the piston, but may be provided at the left and right side portions. The strength of the cam pin 198 provided on the rotation drive member 197 is improved by the rib 199.

  As a means for retracting the cylinder unit, a combination of a rack gear and a pinion gear without some teeth can be used. FIG. 73 shows the means.

  The passive member 200 is exposed in a convex shape from the end face of the magazine facing the cylinder or barrel (in this case, the upper end face of the magazine). The passive member 200 is fixed to the magazine 202 by a shaft 201 so as to be rotatable. The upper portion of the ratchet push bar 203 is fixed to the passive member 200 by a shaft 204 so as to be rotatable. The spring 205 always pushes the passive member 200 and the ratchet push bar 203 in the direction of the arrow 206. Since the nozzle member 191 exists, the spherical bullet 207 cannot rise further. FIG. 28 depicts the most typical initial state that stops immediately after launch.

  FIG. 29 is a schematic structural explanatory view of a sixth embodiment according to the present invention. FIG. 29 shows a state where the rotation driving member 197 is rotated in the direction of the arrow 208 and the cam contact member 194 is most retracted. The magazine drive member 192 is also most retracted in the direction of the arrow 209 and pushes down the passive member 200. Then, the ratchet push bar 203 is also lowered, and the driving ratchet 210 is rotated in the direction of the arrow 211. As the sprocket 212 rotates, the spherical bullet 207 is pushed up to the front of the nozzle member 191.

  The sixth embodiment is characterized in that the number of parts in the magazine is small compared to the first embodiment and the second embodiment. Further, since the cylinder 189, the cylinder head 190, the nozzle member 191, the magazine driving member 192, the arm member 193, and the cam contact member 194 can be formed as one cylinder unit molded product, an inexpensive gun can be provided. is there.

  In the sixth embodiment, the passive member is pushed down when the magazine driving member moves backward. Next, when the magazine driving member moves forward, the passive member is pushed down to function the bullet feeding device in the magazine. Another embodiment of the present invention is shown.

  FIG. 30 is a schematic structural explanatory view of a seventh embodiment according to the present invention. The cylinder unit relationship and piston drive system are almost the same as in the first embodiment. The only difference is the shape of the magazine drive member and its location. In the first embodiment, the front portion of the magazine driving member is formed in a substantially vertical shape, whereas in the seventh embodiment, the front portion of the magazine driving member is formed to have an inclined portion. ing.

  The seventh embodiment differs from the sixth embodiment in the shape and function of the passive member that is exposed in a convex shape from the upper end surface of the magazine. The passive member 213 in the seventh embodiment is a rotating body. According to the combination with the magazine driving member having the inclined portion (straight or curved inclined portion), the passive member 213 can be lowered even if the magazine driving member 214 is operated from the rear as in the seventh embodiment. As in the sixth embodiment, the passive member 213 can be lowered even if the magazine driving member is operated from the front.

  FIG. 30 shows a standard initial state of the seventh embodiment. In FIG. 31, the drive system on the gun side moved, the magazine drive member 214 moved forward most, the passive member 213 was lowered, and the drive ratchet 215 was rotated in the direction of the arrow 216 to generate the power of one ratchet tooth. Indicates the state.

  The sixth embodiment is a type in which the passive member is pushed down when the magazine drive member is retracted, and the passive member performs a circular motion around the shaft 201. Next, there are two passive members. Another embodiment of the present invention of a type in which a bullet feeding device in a magazine is made to function by performing a vertical movement supported by a parallel arm and not causing an arc movement is shown.

  FIG. 32 is a schematic structural explanatory view of an eighth embodiment according to the present invention. 28 is different from the example of FIG. 28 in that the rear side of the convex portion exposed from the magazine of the passive member 217 is formed substantially vertically. In the example of FIG. 28 (sixth embodiment), the passive member 200 performs a relatively small circular arc motion around the shaft 201, so the rear side of the convex portion of the passive member 200 exposed from the magazine is the shaft 201. It is formed by the circular arc centering on. When the convex portion exposed from the magazine is pressed with a finger, a relatively small arc motion is felt in the example of FIG. 28 (sixth example), whereas in the example of FIG. 32 (eighth example). By the action of the two arms 218 and 219 arranged substantially in parallel, the movement is almost similar to the vertical movement. Therefore, there is almost no arc motion, and when pressing the exposed convex part with a finger, it is comfortable to press. The appearance of the magazine has many straight lines in terms of design, so it is more comfortable to handle the visible parts in a straight line. In other parts, there is no difference between the example of FIG. 28 (sixth example) and the example of FIG. 32 (eighth example), and thus a duplicate description is omitted.

  In the first to eighth embodiments, the magazine driving member is formed integrally with the arm member (including the arm member formed integrally with the cylinder). The drive member is arranged separately from the arm member (including the arm member formed integrally with the cylinder), moves while being linked to the arm member, transmits the driving force to the passive member, and reciprocates the passive member. Thus, another embodiment of the present invention of the type that allows the bullet feeding device in the magazine to function will be described.

  FIG. 33 is a schematic structural explanatory view of a ninth embodiment according to the present invention. The engine part of the gun is basically the same as that of the second embodiment (method in which the cam contact member is pushed backward by the rotation of the rotation drive member). Two convex portions 221 and 222 are provided at the lower front portion of the arm member 220. A rotating body 225 is disposed at the tip of the crank-shaped magazine driving member 224 supported by the shaft 223 to reduce friction with the passive member 226. The basic structure of the magazine is the same as that of the fourth embodiment of FIG. The difference is that the passive member 226 has no inclined portion and the vertical length of the entire magazine is slightly different. The arm member 220 is pulled in the direction of the arrow 228 by the spring 227. When the engine part of the gun is stopped in such a state, no force is applied to the passive member 226 even if the magazine is set. If the engine part of the gun is stopped in the state shown in FIG. 34, when the magazine is set, a force acts on the passive member 226, and the passive member 226 is pushed into the magazine.

  FIG. 34 shows a situation in which the rotation drive member 229 rotates in the direction of the arrow 230 and pushes the arm member 220 in the direction of the arrow 231. The crank-shaped magazine driving member 224 is rotated in the direction of the arrow 232 by the convex portion 222 and pushes down the passive member 226 in the direction of the arrow 233. It has already been mentioned that the bullet feeder in the magazine functions when the passive member is pushed down.

  In the ninth embodiment, the magazine driving member 224 and the two convex portions 221 and 222 are arranged at positions symmetrical to the reference center line 234 on which the passive member 226 is arranged, and the spring 227 and the spring 227 are supported. By repositioning the portion 235 forward, the arm member 220 is moved to the arrow 231 by using the pulling force of the spring 227 from the method of pushing down the passive member 226 when the arm member 220 is pushed in the direction of the arrow 231. Obviously, the passive member 226 can be pushed down when pulled in the opposite direction.

  The ninth embodiment is basically the same as the second embodiment in terms of the engine part of the gun. Next, the engine part of the gun is basically the same as that of the first embodiment (of the rotary drive member). The magazine drive member is arranged separately from the arm member and moves while being linked to the arm member, and transmits the driving force to the passive member. Another embodiment of the present invention of a type in which a bullet feeding device in a magazine is made to function by reciprocating is shown.

  FIG. 35 is a schematic structural explanatory diagram of a tenth embodiment according to the present invention. The cam contact member 236 is pushed in the direction of the arrow 238 by the spring 237 and is in the most retracted state. The crank-shaped magazine driving member 241 supported by the shaft 240 is pushed up by the passive member 239. Since no spring or the like is applied to the magazine drive member 241, it can be seen that when the magazine is pulled out, the magazine drive member 241 is naturally rotated by gravity.

  When the rotary drive member 242 rotates in the direction of the arrow 243 from the state of FIG. Eventually, the cam contact member 236 is most advanced, and the state shown in FIG. 36 is reached. It has already been mentioned that the bullet feeding device in the magazine functions when the passive member 239 is pushed down in the direction of the arrow 246. The magazine used in FIG. 36 is exactly the same as the magazine used in the fourth embodiment of FIG. Thus, if the convex part exposed from the magazine has an inclined part, the same magazine can be used for the gun of a different system, and it is convenient.

  Next, when the magazine is set, the magazine driving member is basically the same as in the second embodiment (method in which the cam contact member is pushed backward by the rotation of the rotation driving member). Another embodiment of the present invention of the type in which is pushed by the passive member and retracted is shown.

  FIG. 37 is a schematic structural explanatory view of an eleventh embodiment according to the present invention. The passive member 247 has a structure in which the convex portion exposed from the magazine cannot be retracted inside the magazine. The base portion of the passive member 247 is guided by the rail portion 248 so as to be only movable in the front-rear direction. A convex portion 249 is provided below the base portion of the passive member 247 so as to push the crank 250. The magazine structure ahead of the crank 250 is basically the same as in the second embodiment. The magazine driving member 251 is pushed by the spring 252 but does not fall off due to the action of the retaining portion 254 provided near the tip of the arm member 253.

  FIG. 38 shows a situation when the magazine 255 is set in the direction of the arrow 256A after stopping the gun when the arm member 253 is retracted most. Since the positions where the magazine driving member 251 and the passive member 247 should be engaged do not match, the magazine driving member 251 is pushed up by the passive member 247. When shooting is started from this state, the concave portion of the magazine drive member 251 starts to advance and immediately gets into the convex portion of the passive member 247. Then, the normal meshing state as shown in FIG. 37 is maintained, so that the horizontal reciprocating motion of the magazine driving member 251 is directly transmitted to the passive member 247 as the horizontal reciprocating motion, and the crank 250 in the magazine It is converted into a vertical reciprocating motion by the function, and a bullet feeding device using a ratchet and a sprocket functions. FIG. 39 is an external view of a magazine according to the eleventh embodiment of the present invention. The exposed convex portion moves only in the direction of the arrow 256B, and returns to the initial position by the action of the spring inside the magazine. The second embodiment is an invention that satisfies the design requirement of not allowing the passive member to jump out of the upper surface of the magazine. However, in the eleventh embodiment, the convex portion exposed from the magazine is in the horizontal direction. It is an invention that satisfies the requirement that only the reciprocating motion of the lens is performed and the exposed convex portion cannot be retracted inside the magazine. There is no exposed convex part, and there is a person who requires a realistic appearance as close as possible to the real thing, and there may be an exposed convex part, but the way of movement is exposed with a person who requires only a one-way movement. There are various demands from consumers, such as people who may have a convex part, and that they may move back and forth or retract. It is necessary to respond to this, and the result is the second embodiment, the eleventh embodiment, and the following twelfth embodiment.

  FIG. 40 is a schematic structural explanatory view of a twelfth embodiment according to the present invention. It is suitable for people who think that they may have exposed convex parts, and they can move back and forth or retract. The engine part of the gun is basically the same as that of the second embodiment (method in which the cam contact member is pushed backward by the rotation of the rotation drive member). When the magazine drive member 257 moves backward, the passive member 258 also moves backward. Since the passive member base portion 259 is guided by the rail portions 260 and 261, it can only reciprocate in the horizontal direction. The passive member base 259 is always pushed in the direction of the arrow 263 by the spring 262. The ratchet hook 264 disposed below the passive member base 259 is always pushed in the direction of the arrow 265 by a spring (not shown). By one reciprocation of the magazine drive member 257, the ratchet hook 264 feeds the ratchet 266 by one tooth, and the bullet feeding device functions. When the rotary drive member 267 rotates in the direction of the arrow 268 and the shooting is stopped at the position where the magazine drive member 257 is retracted even a little, the next time the magazine is set again, it does not become as shown in FIG. The set is in a state close to FIG. Passive member 258 can be retracted to rotate about axis 269. The spring 270 always pushes the passive member 258 in the direction of the arrow 271.

  The passive member body 272 is a member obtained by integrally molding a plurality of parts such as a passive member 258, a shaft 269, a spring 270, a passive member base 259, a spring 262, a ratchet hook 264, etc., with an elastic plastic. Expensive products for adults require a high level of durability, so metal springs and metal shafts are used, but inexpensive products for children that do not require that much durability. Suitable for making.

  Next, the engine part of the gun is basically the same as the eleventh embodiment of FIG. 37 (method in which the cam contact member is pushed backward by the rotation of the rotation drive member), and the internal mechanism of the magazine is different. Another embodiment of the present invention will be described.

  FIG. 41 is a schematic structural explanatory diagram of a thirteenth embodiment according to the present invention. In the magazine of FIG. 37, the reciprocating motion in the horizontal direction (front-rear direction) received by the passive member 247 is once converted into the reciprocating motion in the vertical direction (up-down direction) and further converted into the rotational motion. The magazine shown in FIG. 41 converts the reciprocating motion in the horizontal direction (front-rear direction) received by the passive member 273 into a rotational motion immediately. It is obvious that only the vicinity of the passive member 273 is slightly different, and the rest is the same as the magazine of FIG. 40 and performs the same function. Therefore, detailed description is omitted. Also in the embodiment of FIG. 41, it goes without saying that a simplified part such as the passive member 272 shown in FIG. 40 can be made.

  Next, when the magazine is set, the magazine drive member is basically the same as in the first embodiment (method in which the cam contact member is pushed forward by the rotation of the rotation drive member). Another embodiment of the present invention of the type in which the passive member is retracted by being pushed by is shown.

  FIG. 42 is a schematic structural view of a fourteenth embodiment according to the present invention. The magazine drive member 274 is disposed slightly rearward compared to the magazine drive member 26 of the first embodiment of FIG. 8, and the width of the lower portion is wide. This is useful for pushing down the passive member when setting the magazine as shown in FIG. The passive member 275 is set as shown in the passive member base 276 and is pushed up by a spring 277. The passive member 275 and the passive member base 276 are supported by a shaft 278 and have an overall “E” shape. The passive member base 276 is pushed up by the spring 279 in the direction of the arrow 280 and is stopped by the stopper 281. With such an arrangement, as shown in FIG. 43, the forward movement of the magazine drive member 274 is immediately converted into the downward movement, which is efficient. Compared to the first embodiment of FIG. 8, the structure is also simplified. FIG. 44 is an external view of a magazine according to the fourteenth embodiment. If the convex part (passive member) exposed from the magazine is pushed in the direction of the arrow 282, the bullet feeding mechanism works, and if it is pushed in the direction of the arrow 283, the convex part (passive member) is retracted.

  FIG. 45 shows the situation when the magazine 284 is set in the direction of arrow 285 after stopping the gun when the magazine drive member 274 is most advanced. The wide lower part of the magazine drive member 274 shows the situation where the convex part (passive member 275) exposed from the magazine is pushed down. Thereafter, when the gun is restarted and the rotation driving member 285 is further rotated, the initial state shown in FIG. 42 is restored, and thereafter normal bullet feeding is performed. The mechanism beyond the passive member base 276 is substantially the same as that of the magazine of the second embodiment. Since it is fully described in FIG. 12 and FIG. 13, detailed description is omitted.

  Next, the engine part of the gun is basically the same as in the first embodiment (the method in which the cam contact member is pushed forward by the rotation of the rotation drive member), and when the magazine is set, Another embodiment of the present invention in which the passive member is retracted by being pushed by the inner wall of the introduced portion of the magazine provided or the outer wall of the gear box is shown.

  FIG. 46 is a schematic structural explanatory view of a fifteenth embodiment according to the present invention. The magazine driving member 286 is arranged further rearward than the magazine driving member 274 of the fourteenth embodiment shown in FIG. There are no other differences. The passive member 287 is rotatably supported by a shaft 288 and is pushed up in the direction of arrow 290 by a spring 289. And it stops at the stopper 291. When the engine part of the gun starts to move and the magazine driving member 274 moves in the direction of the arrow 292, the front end of the magazine driving member 274 eventually pushes the passive member 287, and the passive member 287 rotates around the shaft 288 to be passive. The arm portion 293 of the member 287 is lowered, and the ratchet push bar 296 is pushed down via the parallel moving member 294 and the spring 295. Since the subsequent functions have already been described, they are omitted. The translation member 294, the spring 295, and the ratchet push bar 296 may be a single component. In the fourteenth embodiment, the passive member is exposed in a convex shape from the end surface portion of the magazine facing the cylinder or the barrel (in the case of the fourteenth embodiment, the upper end surface portion of the magazine). In the fifteenth embodiment, the passive member is exposed in a convex shape from the end surface portion of the magazine (in the fifteenth embodiment, the rear end surface portion of the magazine) facing the central axis of the cylinder or barrel. Is. Since the exposed passive member is automatically retracted when the magazine is set, there is no obstacle.

  Although the embodiment in which the passive member 287 is supported so that it can be rotated by the shaft 288 is described in detail, it has been previously shown that the passive member can be changed to a structure that is supported so that it can move in parallel, Can be easily understood from what has been described. One modified example is shown in the lower left part of FIG. Replacement with the passive member 297, the spring 298, and the crank 299 performs the same function. The appearance of the magazine does not change.

  Next, the engine part of the gun is basically the same as the second embodiment of FIG. 12 (method in which the cam contact member is pushed backward by the rotation of the rotation drive member), and the magazine drive member changes the direction of movement. Another embodiment of the present invention of the type having the function to convert is shown.

  FIG. 47 is a schematic structural explanatory view of a sixteenth embodiment according to the present invention. The magazine driving member 300 is supported by the shaft 301 and can freely rotate within a certain range. When the spring supporting hook rear end portion 303 provided at the lower portion of the arm member 302 is retracted, the upper end portion 304 of the magazine driving member 300 is pushed down in the direction of the arrow 305. The direction of movement is changed and the magazine drive member 300 moves in the direction of arrow 306 and pushes in the passive member 307. The magazine shown in FIG. 47 is exactly the same as the magazine shown in FIG. Naturally, the replacement with the passive member 297, the spring 298, and the crank 299 as shown in the lower left part of FIG.

  Next, the engine part of the gun is basically the same as in the second embodiment of FIG. 12 (method in which the cam contact member is pushed backward by the rotation of the rotation drive member), and the magazine drive member is used as the arm member. Another embodiment of the present invention of the type that functions by the restoring force of the acting spring is shown.

  FIG. 48 is a schematic structural explanatory view of a seventeenth embodiment according to the present invention. The magazine drive member 308 is disposed below the arm member 309. When the rotation driving member 310 rotates in the direction of the arrow 311, the magazine driving member 308 eventually starts moving in the direction of the arrow 312 and pushes in the passive member 313. The magazine shown in FIG. 47 is exactly the same as the magazine shown in FIG. Naturally, the replacement with the passive member 297, the spring 298, and the crank 299 as shown in the lower left part of FIG. The magazine drive member 308 is always pulled forward by a spring 314 acting on the arm member. The spring 314 is depicted as a tension spring, but can be easily changed to a push spring.

  Next, another embodiment of the present invention, in which the engine part of the gun is basically of the same type as the fourteenth embodiment of FIG. Indicates.

  FIG. 49 is a schematic structural explanatory view of an eighteenth embodiment according to the present invention. The magazine drive member 315 is disposed slightly forward compared to the fourteenth embodiment of FIG. The passive member 316 is supported on the passive member base 317 by a shaft 318 and is pushed up by a spring 319. With a similar structure, the ratchet hook 320 is supported on the passive member base 317 by the shaft 321 and pushed down by the spring 322. The passive member base 317 is supported by the shaft 323 and is always pushed backward by the spring 324. In such a situation, when the rotary drive member 325 rotates in the direction of the arrow 326, the magazine drive member 315 eventually starts to move in the direction of the arrow 327 and pushes the passive member 316 forward. Passive member base 317 rotates about axis 323 in the direction of arrow 328. Ratchet hook 320 rotates ratchet 329 by one tooth in the direction of arrow 330. Thus, the movement of the arrow 327 toward the front can be directly converted into the movement toward the rear opposite to the arrow 327 using the shaft 323, and the ratchet 329 can be rotated by one tooth. Note that the number of parts can be significantly reduced as in the twelfth embodiment of FIG. The passive member body 331 depicted on the right side of the magazine is composed of a passive member 316, a passive member base 317, a shaft 318, a spring 319, a ratchet hook 320, a shaft 321, a spring 322, a spring 324, and the like, which are integrally made of elastic plastic. Shows what was molded. Suitable for inexpensive children's toy guns that do not require high durability.

  FIG. 50 depicts a case where the passive member body 331 is used, and shows the situation when the magazine 332 is set in the direction of the arrow 333 after the gun is stopped when the magazine drive member 315 is most advanced. Show. The wide lower portion of the magazine drive member 315 shows a situation where the convex portion (passive member 316) exposed from the magazine is pushed down in the direction of the arrow 334. If the gun is then restarted and the rotary drive member 325 is rotated, the magazine drive member 315 returns to the initial state as shown in FIG. 49, and the passive member 316 returns to the initial state. Will be sent.

  Up to this point, the reciprocating motion of the magazine driving member is received as the reciprocating motion (reciprocating motion including the arc motion) by the passive member, and is converted into a rotational motion by using a motion converting mechanism in the magazine and is sent out. Several examples have been presented. Next, another embodiment of the present invention in which a rack gear is used as the magazine driving member and a pinion gear (or spur gear) is used as the passive member will be described.

  FIG. 51 is a schematic structural explanatory diagram of a nineteenth embodiment according to the present invention. The magazine drive member 335 is a rack gear, and the passive member 336 is a spur gear. When the rotation driving member 337 rotates in the direction of the arrow 338, the magazine driving member 335 performs a reciprocating motion in the X-axis direction. Along with the movement, the passive member 336 performs a rotational motion that reciprocates around an axis 339 (an axis perpendicular to the XZ plane). The reciprocating rotational motion is transmitted to the pulley 342 having the internal ratchet by the pulley 340 and the belt 341. There is a through hole in the center of the pulley 342, and the central axis 344 of the ratchet arm 343 passes through. A spur gear 345 is fixed to the central shaft 344. With this configuration, the movement of the belt 341 in the direction of the arrow 346 is not transmitted because the tip of the ratchet arm 343 slips. On the other hand, the movement of the belt 341 in the direction of the arrow 347 is transmitted by the tip of the ratchet arm 343 being caught by the internal tooth ratchet of the pulley 342. That is, a four-way clutch is constituted by four parts including a pulley 342 having an internal tooth ratchet, a ratchet arm 343, a central shaft 344, and a spur gear 345. Thereby, the reciprocating motion of the rotation drive member 337 is converted into the rotational motion in the direction of the arrow 348. In the rotational movement in the direction of the arrow 348, the spur gear 349 is rotated in the direction of the arrow 350, and bullet feeding is performed. Alternatively, as shown in the partial view arranged on the right side of FIG. 51, if the pinion gear 351 is engaged with the passive member 336, the bevel gear 352 is fixed to the same axis as the pinion gear 351, and the bevel gear 353 engaged with the bevel gear 352 is disposed, Z A rotational movement can be made to reciprocate on the shaft 354 oriented in the axial direction. If a one-way clutch similar to that described above is incorporated in the shaft 354, an axis that rotates in one direction and faces the Z-axis direction can be arranged. If a propeller is attached to an axis that rotates in one direction and faces the Z-axis direction as shown in FIG. 70, a vertical screw as shown in FIG. 71, or a horizontal screw as shown in FIG. Can do bullets. If the tooth tips of the magazine drive member 335 (rack gear) and the passive member 336 (spar gear) are formed in an extremely small R shape, when the magazine is attached / detached, there is almost no situation where the tooth tip collides and the magazine cannot be set.

  Next, another embodiment of the present invention in which a spur gear is used as a magazine driving member and a spur gear is also used as a passive member will be described.

  FIG. 52 is a schematic structural explanatory view of a twentieth embodiment according to the present invention. In FIG. 51, the passive member is arranged on the upper end surface portion of the magazine (the end surface portion of the magazine facing the same direction as the discharge direction of the spherical bullets). It was arranged on the end face (side face of the magazine facing a direction different from the discharge direction of the spherical bullet).

  The magazine drive member 355 is a spur gear provided with a pinion gear, and the passive member 356 is also a spur gear. When the rotation driving member 357 rotates in the direction of the arrow 358, the arm member 359 performs a reciprocating motion in the X axis direction. A rack gear 360 is provided below the arm member 359, and a reciprocating rotational motion is given to the spur gear which is the magazine drive member 355 via the pinion spur gear 361. When the arm member 359 moves in the direction of the arrow 362 (−X direction), the passive member 356 rotates in the direction of the arrow 363, and the sprocket 364 serving as a bullet feeding mechanism rotates in the direction of the arrow 365. When the arm member 359 moves in the direction opposite to the arrow 362 (X direction), as described in detail in the nineteenth embodiment of FIG. 51, the force is transmitted by the action of the one-way clutch mechanism arranged in the middle. Not. 52, when the pinion gear 366 is meshed with the passive member 356, the bevel gear 367 is fixed to the same axis as the pinion gear 366, and the bevel gear 368 meshing with the bevel gear 367 is disposed, as shown in the partial view arranged on the right side of FIG. A rotational movement can be made to reciprocate on the shaft 369 facing the axial direction. If a one-way clutch similar to that described above is incorporated in the shaft 369, an axis that rotates in one direction and faces the Z-axis direction can be disposed. The application method has already been described.

  Next, another embodiment of the present invention in which a bevel gear is used as a magazine driving member and a bevel gear is also used as a passive member will be described.

  FIG. 53 is a schematic structural explanatory diagram of a twenty-first embodiment according to the present invention. The passive member was disposed on the upper end surface portion of the magazine (the end surface portion of the magazine facing the same direction as the discharge direction of the spherical bullet). The magazine drive member 370 is a bevel gear, and the passive member 371 is also a bevel gear. When the rotation drive member 372 rotates in the direction of the arrow 373, the arm member 374 reciprocates in the X-axis direction. A rack gear 375 is provided below the arm member 374, and a reciprocating rotational motion is given to the bevel gear that is the magazine drive member 370 via the pinion gear 376, the pinion bevel gear 377, and the bevel gear 378. The axial direction of the bevel gear, which is the magazine drive member 370, is the same as the X-axis direction, but when the force is transmitted to the passive member 371, the direction of the rotation axis is the same as the Z-axis direction. Since the bevel gear that is the passive member 371 merely performs a reciprocating rotational motion, the bullet feeding device does not function as it is. A one-way clutch mechanism that rotates in a certain direction is required, and a livestock mechanism as described in FIG. 17 is also required.

  The one-way clutch mechanism has been described in detail in the nineteenth embodiment of FIG. A similar mechanism may be arranged in the Z-axis direction. A ratchet arm 380 is attached to the shaft 379 of the passive member 371. A coupling 381 having an internal tooth ratchet is attached to the shaft 382, and the shaft 379 and the shaft 382 are arranged coaxially. This functions as a one-way clutch mechanism. Next, the mainspring spring shaft member 383 is attached to the shaft 382, and the mainspring spring 384 is set. A drive shaft 386 is attached to a coupling 385 having a plurality of recesses on the inner wall. When the outer end portion of the spring spring 384 is assembled so as to fit into the recess in the inner wall of the coupling 385, the same animal power device as that described with reference to FIG. 17 is obtained. The bullet feeding mechanism is a mechanism in which a propeller 387 is attached to the vicinity of the tip of the drive shaft 386 to stir spherical bullets, and the bullets are separated one by one by a separation claw 388 and fed into the conveyance path 389. In rare cases, a spherical bullet may be sandwiched between the propeller 387 and the separation claw 388. In such a case, if the release knob 390 is pushed in the direction of the arrow 391, the tip of the release knob 390 slightly rotates the pinion gear 392 attached to the tip of the drive shaft 386, and the spherical bullet He / she releases the pinching. The spring 393 is a return spring for the release knob 390.

  In FIG. 53, a general thin box-shaped small magazine is drawn, and the number of blades of the propeller 387 is about three. However, if a large box magazine is used, the number of propeller blades can be increased to 20 or the like. Or the axis | shaft of the sprocket which was used with the axis | shaft (Y axis | shaft) perpendicular | vertical to XZ plane until now can be used for a Z-axis direction. To put it simply, the magazine's bullet feed sprocket, which is the conventional common sense in the air gun industry, is stopped vertically, and the bullet sprocket is placed horizontally at the bottom of the box magazine. In a large box magazine, the number of bullets increases at the level of several thousand shots by arranging the vertically arranged sprockets horizontally. As for the vertical arrangement of the bullet sprocket, nearly half of the volume of the large box magazine was dead space, and the waste was large. Of course, as with the sprocket system, a propeller system can also be adopted.

  FIG. 53 shows an embodiment in which a bevel gear is used as a magazine driving member and a bevel gear is used as a passive member. Next, another embodiment of the present invention will be described in which the mechanism in the gear box is exactly the same as that of the twenty-first embodiment of FIG. In this embodiment, a pinion gear is used as the magazine driving member and a spur gear is used as the passive member. The magazine is an embodiment having a completely different structure from the twenty-first embodiment of FIG.

  FIG. 54 is a schematic structural explanatory diagram of a twenty-second embodiment according to the present invention. It depicts a situation where you are trying to set a magazine on a gun. The magazine drive member 394 is a pinion gear, and the passive member 395 is a spur gear. When magazine 396 is set in the direction of arrow 397, the two gears mesh. A one-way clutch mechanism 398 having the same structure as that shown in the twenty-first embodiment of FIG. 53 is arranged on the shaft of the pinion gear which is the magazine driving member 394, and the magazine driving member 394 rotates only in the necessary direction. To do. Further, a livestock power mechanism 400 having the same structure as that shown in the twenty-first embodiment of FIG. 53 is arranged coaxially with the second spur gear 399 in the magazine. The outer peripheral portion of the animal power mechanism 400 is a pulley and transmits force to the pulley 402 via the belt 401. A screw 404 and a pinion gear 405 are attached to the shaft 403 of the pulley 402. Although the spherical bullet is sent into the conveyance path 406 by the rotation of the screw 404, it is also conceivable that biting occurs. When biting occurs, biting is eliminated by slightly moving the pinion gear 405 with a finger. The feature of the twenty-second embodiment shown in FIG. 54 is that the magazine driving force is output as the rotational force in the X-axis direction and is passively driven by the rotational force in the X-axis direction.

  FIG. 53 shows an embodiment in which a bevel gear is used as a magazine driving member and a bevel gear is used as a passive member. Next, another embodiment of the present invention will be described in which the basic mechanism on the gun side is very similar to that of the twenty-first embodiment of FIG. 53, and there is a great difference in the output direction of the magazine drive member. In this embodiment, a bevel gear is used for the magazine drive member and a bevel gear is used for the passive member. The magazine is an embodiment having almost the same structure as the twenty-first embodiment of FIG.

  FIG. 55 is a schematic structural explanatory view of a twenty-third embodiment according to the present invention. The magazine drive member 407 is a bevel gear, and the passive member 408 is also a bevel gear. When the rotation driving member 409 rotates in the direction of the arrow 410, the arm member 411 performs a reciprocating motion in the X-axis direction. A rack gear 412 is provided below the arm member 411, and a rotational movement is given to the passive member 408 so as to reciprocate via the intermediate gear 413. The bevel gear which is the magazine drive member 370 is given a reciprocating rotational motion. The axial direction of the bevel gear that is the magazine drive member 407 is the same as the Y-axis direction, but when the force is transmitted to the passive member 408, the direction of the rotation axis is the same as the Z-axis direction. The magazine is an embodiment having almost the same structure as the twenty-first embodiment of FIG. 53 except that the size of the bevel gear which is the passive member 408 is different, and the description thereof will be omitted. The feature of the twenty-third embodiment shown in FIG. 55 is that the magazine driving force is output as a rotational force in the Y-axis direction and is passively driven as a rotational force in the Z-axis direction. Compared to the twenty-first embodiment, since the number of gears used on the gun side is two fewer, it is cheaper.

  Next, another embodiment of the present invention in which the magazine driving force is output by the rotational force in the Y-axis direction and passively driven by the rotational force in the Z-axis direction, which is the same as the feature of the 23rd embodiment of FIG. 55, will be described. .

  FIG. 56 is a schematic structural explanatory view of a twenty-fourth embodiment according to the present invention. Basically, the structure is almost the same as that of the 23rd embodiment of FIG. 55, the shaft 414 is cut into two parts, the crown gear as the magazine drive member 415 is provided on the gun side, and the crown gear as the passive member 416 is provided. This is a structure provided on the magazine side. When the magazine 417 is set in the direction of the arrow 418, the two crown gears mesh with each other, and the driving force is transmitted. In this embodiment, the magazine driving force is output as a rotational force in the Z-axis direction and passively driven by the rotational force in the Z-axis direction. The other parts have already been described and will be omitted.

  Next, another embodiment of the present invention, which outputs the magazine driving force by the reciprocating movement of the rack gear and is passively driven by the pinion gear as the rotational force in the Z-axis direction, which is the same as the feature of the nineteenth embodiment of FIG. Show.

  FIG. 57 is a schematic structural explanatory diagram of a twenty-fifth embodiment according to the present invention, viewed from the Y-axis direction perpendicular to the XZ plane. FIG. 58 is a partial explanatory view of a twenty-fifth embodiment according to the present invention, viewed from the Z-axis direction perpendicular to the XY plane. The structure on the gun side is basically the same as that of the nineteenth embodiment of FIG. 51, except that the direction of the rack gear which is the magazine drive member 419 is different by 90 degrees. The spur gear, which is the passive member 420, is disposed on the upper end surface of the magazine. The structure on the magazine side is basically the same as that of the 21st embodiment of FIG. 53 and the 23rd embodiment of FIG. 55, and only the point that the passive member is a crown gear or a spur gear. Is different. Since the other parts have already been described, the description regarding the magazine is omitted.

  FIG. 58 is a partial view as seen from the Z-axis direction perpendicular to the XY plane. The arrangement relationship among the rack gear as the magazine drive member 419, the spur gear as the passive member 420, the arm member 421, the discharge port 422 of the spherical bullet, etc. Understandable. When the arm member 421 is pulled in the direction of the arrow 423, the spur gear which is the passive member 420 rotates in the direction of the arrow 424. However, since this rotation is a reciprocating rotational motion, it is necessary to adjust the rotation in one direction by the one-way clutch mechanism 425 shown in FIG. The one-way clutch mechanism has already been described.

  Next, another embodiment of the present invention will be described in which a reciprocating motion of an arm member gives a spur gear that is a passive member to reciprocate.

  FIG. 59 is a partial explanatory view of a twenty-sixth embodiment according to the present invention, seen from the Z-axis direction perpendicular to the XY plane. The sector gear which is the magazine drive member 426 is attached to the lower side of the gear box of the gun by a shaft 427. The fan-shaped gear that is the magazine drive member 426 is provided with a pin 428 and enters a long hole 430 provided at the tip of the arm member 429. In this state, when the arm member 429 is pushed in the direction of the arrow 431, the sector gear as the magazine driving member 426 rotates in the direction of the arrow 432, and the spur gear as the passive member 433 is in the direction of the arrow 434. Rotate to.

  FIG. 60 shows a state in which the arm member 429 is pulled in the direction of the arrow 435 in the twenty-sixth embodiment. The sector gear that is the magazine drive member 426 rotates in the direction of arrow 436, and the spur gear that is the passive member 433 rotates in the direction of arrow 437. 59 and 60 are repeated, it is possible to impart a reciprocating rotational motion to the spur gear, which is the passive member 433. The subsequent operation of each mechanism in the magazine has already been described.

  The embodiment shown in FIGS. 58 to 60 is an embodiment related to a general gun in which the magazine is inserted from the lower side of the gun. However, the method of inserting the magazine from the upper side of the gun, which will be described later in FIGS. It can also be applied to special guns.

  Next, another embodiment of the present invention in which the basic mechanism on the magazine side is very similar to the twenty-fifth embodiment of FIG. 58 and the magazine driving member is a ratchet hook having a relief function will be described.

  FIG. 61 is a partial explanatory view of a twenty-seventh embodiment according to the present invention, viewed from the Z-axis direction perpendicular to the XY plane. The arrangement relationship of the ratchet hook that is the magazine drive member 438, the ratchet that is the passive member 439, the arm member 440, the spherical bullet discharge port 441, the spring 442 that prevents the ratchet from rotating in reverse can be understood. When the arm member 440 is pulled in the direction of the arrow 443, the ratchet that is the passive member 439 rotates in the direction of the arrow 444. When the arm member 440 is pushed in the direction opposite to the arrow 443, the escape function (the escape function by the elasticity of the material in FIG. 61. In the system like the embodiment of FIG. 98, the escape function by the elasticity of the spring is used. ) And the ratchet hook moves forward over the ratchet teeth, and the ratchet is stopped by the action of a spring 442 that prevents reverse rotation. In other words, the arm member 440 (the arm member integrated with the cylinder in the system as in the embodiment of FIG. 28 or the system as in the embodiment of FIG. 98) reciprocates in the X-axis direction, thereby passively moving. The ratchet that is the member 439 rotates only in the direction of the arrow 444. Therefore, a mechanism such as the one-way clutch mechanism 425 shown in FIG. 57 is not necessary. Since the one-way clutch mechanism is composed of a plurality of small parts, there is a great merit that it can be omitted.

  Next, another embodiment of the present invention in which the magazine is exactly the same as the twenty-seventh embodiment of FIG. 61 and the magazine driving member is a ratchet hook having an escape function different from the twenty-seventh embodiment will be described. .

The arrangement relationship of the ratchet hook that is the magazine driving member 445, the ratchet that is the passive member 446, the arm member 447, the discharge port 448 of the spherical bullet, the spring 449 that prevents the ratchet from rotating in reverse can be understood. When the arm member 447 is pushed in the direction of the arrow 450, the ratchet that is the passive member 446 rotates in the direction of the arrow 451. When the arm member 447 is pulled in the direction opposite to the arrow 450, the escape function (the escape function by the elasticity of the material in FIG. 62. In the system as in the embodiment of FIG. 95, the escape function by the elasticity of the spring is used. The ratchet hook having) moves over the ratchet teeth and retracts, and the ratchet is stopped by the action of a spring 449 that prevents reverse rotation. That is, the arm member 447 (the arm member integrated with the cylinder in the system as in the embodiment of FIG. 28 or the system as in the embodiment of FIG. 98) reciprocates in the X-axis direction, so that The ratchet that is the member 446 rotates only in the direction of the arrow 451. Therefore, a mechanism such as the one-way clutch mechanism 425 shown in FIG. 57 is not necessary.

  Next, another embodiment of the present invention will be described in which the reciprocating motion of the magazine driving member is received by the passive member as the reciprocating motion, and is converted into a rotational motion and sent by using a motion converting mechanism in the magazine.

  FIG. 63 is a schematic structural explanatory view of a twenty-ninth embodiment according to the present invention. The structure relating to the engine part of the gun is basically the same as that of the second embodiment shown in FIG. Only the shape and arrangement position of the convex part, which is a magazine drive member, is slightly different. However, if the shape and arrangement position of the passive member 452 are slightly changed, the structure relating to the engine part of the gun can be made exactly the same as that of the second embodiment of FIG.

  The convex portion of the magazine driving member 453 enters the concave portion of the passive member 452. The passive member 452 is supported by the passive member base 454 and is always pushed by the action of the spring 455. With this configuration, the passive member can be retracted as in the second embodiment of FIG. 14, so that the magazine can be set on the gun regardless of the stop position of the magazine drive member 453. The passive member base 454 is guided by the rail portion 456 and performs reciprocating motion in the X-axis direction. A rack gear 457 is provided under the passive member base 454 and meshes with the spur gear 458. When the rotation drive member 459 rotates in the direction of the arrow 460, the magazine drive member 453 moves in the direction of the arrow 461. As a result, the rack gear 457 also moves in the direction of the arrow 462, and the spur gear 458 rotates in the direction of the arrow 463. Since the spur gear 458 corresponds to the spur gear 336 in the nineteenth embodiment of FIG. 51, the subsequent magazine mechanism functions similarly to the nineteenth embodiment of FIG.

  Next, another embodiment of the present invention will be described in which the reciprocating motion of the magazine driving member is received by the passive member as the reciprocating motion, and is converted into a rotational motion and sent by using a motion converting mechanism in the magazine.

  FIG. 64 is a schematic structural explanatory view of a 30th embodiment according to the present invention. The structure relating to the engine part of the gun is basically the same as that of the eleventh embodiment shown in FIG. Contrary to the previous example, FIG. 63, the 29th embodiment, the magazine drive member side is a concave portion and the passive member side is a convex portion. The concave portion of the magazine driving member 464 enters the convex portion of the passive member 465. The magazine drive member 464 is pushed by the spring 466, but does not fall off due to the action of the retaining portion 468 provided near the tip of the arm member 467. With this configuration, the magazine drive member 464 can be retracted in the same manner as in the eleventh embodiment of FIG. 38. Therefore, the magazine drive member 453 can be retracted regardless of the stop position of the magazine drive member 453 or the stop position of the passive member 465. Can be set on the gun. No spring or the like is applied to the passive member base 469. In the eleventh embodiment shown in FIG. 38, the spring is applied to the passive member base, but it may be omitted. The spring is just that the user feels better when handling it. A rack gear 470 is provided below the passive member base 469 and meshes with the spur gear 458. Since the subsequent mechanism is the same as the previous example, FIG. 63, Example 29, the description thereof is omitted.

  Next, the reciprocating motion in the X-axis direction of the magazine driving member is received as the reciprocating motion in the Z-axis direction by the passive member, and is converted into a rotational motion by using a motion conversion mechanism in the magazine to perform bullet feeding. Another embodiment is shown.

  FIG. 65 is a schematic structural explanatory diagram of a thirty-first embodiment according to the present invention. The structure relating to the engine part of the gun is the same as that of the third embodiment shown in FIG. The passive method of driving force is the same, but there is a difference in the subsequent motion conversion mechanism in the magazine. The configuration of the passive member 471 and the passive member base 472 and how the passive member base 472 functions are described sufficiently in the third embodiment of FIGS. . Below the passive member base 472, there is an arm portion 473, and a rack gear 474 is provided. A spar gear 475 having an internal tooth ratchet meshes with the rack gear 474, and a ratchet arm 476 acts on the internal tooth ratchet. It has already been described in the nineteenth embodiment in FIG. 51 that the one-way clutch function is achieved by such a configuration. The intermediate gear 477 adjusts the direction of rotation.

  When the rack gear 474 moves in the direction of the arrow 478, the spur gear 475 having the internal ratchet rotates in the direction of the arrow 479, and the ratchet arm 476 also rotates in the same direction. Since the axis of the ratchet arm 476 is fixed to the spur gear 480, the rotational force rotates the sprocket 481 in the direction of the arrow 482 via the intermediate gear 477. When the rack gear 474 moves in the direction opposite to the arrow 478, the spur gear 475 having the internal tooth ratchet is rotated, but the tip of the ratchet arm 476 slips, and the rotational force is not transmitted to the spur gear 480. With the above configuration, the reciprocating motion of the magazine drive member in the X-axis direction is received by the passive member as the reciprocating motion in the Z-axis direction, and converted into a unidirectional rotational motion using the motion conversion mechanism in the magazine. It is intended to send bullets.

  Next, the reciprocating motion in the X-axis direction of the magazine driving member is received as the reciprocating motion in the Z-axis direction by the passive member, and is converted into a rotational motion by using a motion conversion mechanism in the magazine to perform bullet feeding. Another embodiment is shown.

  FIG. 66 is a schematic structural view of a thirty-second embodiment according to the present invention. In the 31st embodiment shown in FIG. 65 which is the immediately preceding embodiment, the spar gear having the internal ratchet is rotated using the rack gear which performs linear reciprocating motion in the Z-axis direction. In this method, a spur gear having an internal ratchet is rotated using a fan-shaped rack gear having a rotation axis in the Y-axis direction perpendicular to the XZ plane and performing an arc-shaped reciprocating motion. A pin 484 is provided below the passive member base 483. The fan-shaped rack gear 485 is provided with a long hole 486 and a pin 484 is inserted therein. With this configuration, when the magazine driving member 487 moves in the X-axis direction indicated by the arrow 488, the passive member 489 moves in the Z-axis direction indicated by the arrow 490. Then, the pin 484 pushes down the elongated hole 486, and the sector rack gear 485 rotates about the shaft 491 in the direction of the arrow 492. The subsequent mechanism is the same as the previous example, FIG. 65, and the description thereof will be omitted. With the above configuration, the reciprocating motion of the magazine drive member in the X-axis direction is received by the passive member as the reciprocating motion in the Z-axis direction, and converted into a unidirectional rotational motion using the motion conversion mechanism in the magazine. It is intended to send bullets.

  Next, the reciprocating motion of the magazine driving member in the X-axis direction is received as the reciprocating rotational motion having the Z-axis direction of the sector rack gear having the Y-axis rotating shaft perpendicular to the XZ plane. Another embodiment of the present invention will be described in which a bullet is sent after being converted into a rotational motion in one direction.

  FIG. 67 is a schematic structural explanatory view of a thirty-third embodiment according to the present invention. The structure relating to the engine part of the gun is basically the same as that of the sixth embodiment of FIG. However, the only difference is that a rack gear 493 is provided instead of the cam contact member 194, and a missing tooth gear 494 is used instead of the cam pin 198. However, there is no difference in function. The passive method of driving force is the same, but there is a difference in the subsequent motion conversion mechanism in the magazine. The rotation drive member 495 is rotated in the direction of the arrow 496 and the rack gear 493 is most retracted. The magazine drive member 497 is also most retracted in the direction of the arrow 498 and pushes the passive member 499 in the direction of the arrow 500. The movement of the magazine driving member and the passive member so far is the same as that of the sixth embodiment in FIG.

  The passive member base 501 is provided with an arc-shaped arm portion 502, and a sector rack gear 503 is provided near the tip of the arm portion 502. A pinion gear 504 meshes with the sector rack gear 503, and a pulley 505 is attached coaxially with the pinion gear 504, and a rotational force is transmitted to the pulley 507 having an internal ratchet via the belt 506. Since the mechanism after the pinion gear 504 is the same as that of the nineteenth embodiment in FIG. With the above configuration, the reciprocating motion in the X-axis direction of the magazine driving member is received as the reciprocating rotational motion in the Z-axis direction of the sector rack gear having the Y-axis rotating shaft perpendicular to the XZ plane. Using a motion conversion mechanism, it is converted into a unidirectional rotational motion and is sent.

  FIGS. 51 to 67 show an embodiment of the present invention in which linear reciprocating motion is converted into unidirectional rotational motion mainly using a rack gear, pinion gear (or spur gear), and a one-way clutch mechanism. Has been shown. Here are some other embodiments of the present invention that use other methods to convert linear reciprocating motion into unidirectional rotational motion.

  FIG. 68 is a schematic structural explanatory view of a thirty-fourth embodiment according to the present invention. The output method of the driving force from the engine part of the gun and the passive method on the magazine side are almost the same as those in the 21st embodiment of FIG. 53, but there is a slight difference. 53 In the twenty-first embodiment, a combination of a rack gear, a pinion gear, and a bevel gear is used to convert linear reciprocating motion into rotational motion. Therefore, since the rotational motion obtained in the engine part of the gun is a reciprocating rotational motion, a one-way clutch mechanism is arranged in the magazine. The point that the output is a reciprocating rotary motion and the point that a one-way clutch mechanism is arranged in the magazine are different from the embodiment of FIG.

  68. The magazine shown in the thirty-fourth embodiment does not have a one-way clutch mechanism. The rest of the basic structure is the same as the magazine shown in FIG. 68. A mechanism for converting linear reciprocating motion into unidirectional rotational motion is disposed in the engine section of the gun shown in the thirty-fourth embodiment. The magazine drive member 508 is a bevel gear, and the passive member 509 is also a bevel gear. A cam member 510 that rotates only in one direction is attached to the same axis as the bevel gear that is the magazine drive member 508. A cam pin base member 512 is attached to a lower portion of the arm member 511, and a cam pin 514 that fits into a cam groove 513 of the cam member 510 is provided on the cam pin base member 512. When the rotation driving member 515 rotates in the direction of the arrow 516, the arm member 511, the cam pin base member 512, and the cam pin 514 integrally perform a linear reciprocating motion in the X-axis direction. When the cam pin 514 keeps a fixed position (position in the Z-axis direction) and performs a linear reciprocating motion in the X-axis direction, the cam member 510 performs a rotational motion in one direction. This mechanism is similar to the mechanism used inside a push-type ballpoint pen. A partial explanatory view in which the cam groove formed on the circumference is developed in a plan view is attached to the right side. A state in which the cam pin 514 moves along the cam groove 513 as indicated by an arrow 517 is depicted. Actually, since the cam pin 514 performs a linear reciprocating motion in the X-axis direction while maintaining a certain position (position in the Z-axis direction), the cam groove 513 relatively moves in the direction of the arrow 518. Become. That is, the cam member 510 performs a unidirectional rotational movement in the direction of the arrow 518.

  The one-way rotational motion of the bevel gear that is the magazine drive member 508 is passively passed by the bevel gear that is the passive member 509. A livestock mechanism 519 having a relief clutch mechanism similar to that shown in the twenty-first embodiment of FIG. 53 is arranged on the shaft of the passive member 509, and rotates the shaft 520 by a necessary amount. The following bullet feeding mechanism from the shaft 520 has already been described in FIG. If the magazine driving member 508 is changed from the bevel gear to the pinion gear, the magazine of the system described in the twenty-second embodiment of FIG. 54 can be used. The feature of the 34th embodiment in FIG. 68 is that a mechanism for converting linear reciprocating motion into rotational motion in one direction is arranged in the engine part of the gun.

  Next, the reciprocating motion in the X-axis direction of the magazine driving member is received as the reciprocating motion in the Z-axis direction by the passive member, and is converted into a rotational motion by using a motion conversion mechanism in the magazine to perform bullet feeding. Another embodiment is shown.

  FIG. 69 is a schematic structural explanatory view of a thirty-fifth embodiment according to the present invention. The structure relating to the engine part of the gun is basically the same as that of the sixth embodiment in FIG. This is a method in which the cylinder feeds by reciprocating in the X-axis direction. The passive method of the driving force is almost the same as that of the third embodiment of FIG. 20 except that the cam pin base member 522 is arranged such that the ratchet push bar 142 is cut halfway. As a bullet feeding mechanism, a propeller having a rotation axis parallel to the Z axis is used instead of a sprocket that rotates on a plane parallel to the XZ plane. The cam pin base member 522 is provided with a cam pin 525 that fits into the cam groove 524 of the cam member 523. When the rotation drive member 526 rotates in the direction of the arrow 527, the magazine drive member 521 performs linear reciprocation in the X-axis direction. The direction of movement is changed by the passive member 528, and the cam pin 525 performs linear reciprocation in the Z-axis direction. The relationship between the movement of the cam member 523 and the cam groove 524 and the cam pin 525 has already been described in the previous example, FIG. On the shaft of the cam member 523, a livestock force mechanism 529 having a relief clutch mechanism similar to that shown in FIG. The following bullet feeding mechanism from the shaft 530 has already been described in FIG. By configuring as described above, the reciprocating motion of the magazine drive member in the X-axis direction is received by the passive member as the reciprocating motion in the Z-axis direction, and converted into a unidirectional rotational motion using the motion conversion mechanism in the magazine. Can be sent.

  Next, the cam member 523, the cam groove 524, and the cam pin 525 function to convert the reciprocating motion into a reciprocating rotational motion with a screw and a screw pin that meshes with the screw groove instead of converting the reciprocating motion into a one-way rotational motion. Another embodiment of the present invention is shown in which it is converted, and a one-way clutch mechanism is added to convert it into a one-way rotational movement to feed bullets.

  FIG. 70 is a schematic structural explanatory view of a thirty-sixth embodiment according to the present invention. The structure relating to the engine part of the gun is the same as that of the third embodiment of FIG. The structure of the magazine is the same as the previous example, FIG. 69, and the 35th embodiment except that only the mechanism for converting the reciprocating motion into a unidirectional rotational motion is different. The portion that was the cam pin base member 512 is referred to as a screw pin base member 531 in FIG. The screw pin base member 531 is provided with a screw pin 534 that fits into the screw groove 533 of the screw member 532. A one-way clutch mechanism 535 is arranged coaxially with the screw member 532, and a livestock mechanism 536 having an escape clutch mechanism is arranged at the tip. The one-way clutch mechanism 535 and the animal power mechanism 536 are the same as those shown in FIG. The mechanism for converting the reciprocating motion into the unidirectional rotational motion is difficult to explain because it is small in size, and will be described in detail in the next embodiment.

  FIG. 71 is a schematic structural explanatory view of a thirty-seventh embodiment according to the present invention. Since the mechanism for converting the reciprocating motion into a unidirectional rotational motion is the same as the previous example, FIG. 70, FIG. 36, the same parts will be described using the same symbols. The magazine lid 537 is opened and a spherical bullet is inserted. A vertical screw 538 is used for bullet feeding. The tip of the shaft 539 of the vertical screw 538 is slightly exposed from the bottom surface of the magazine. When a spherical bullet is bitten inside the magazine, the tip of the shaft 539 may be pushed with a finger. The vertical screw 538 moves slightly in the Z-axis direction, and the bite is eliminated. The screw pin base member 531 and the screw pin 534 are integrated. And although it performs a reciprocating motion in the Z-axis direction, it does not rotate. Since the screw pin 534 is fitted in the screw groove 533, when the screw pin 534 performs the reciprocating motion in the Z-axis direction, the screw member 532 does not move in the Z-axis direction, so that the reciprocating rotational motion is performed. The screw groove 533 should have a large inclination like a double thread. The reciprocating rotational motion of the screw member 532 is converted into a unidirectional rotational motion by the one-way clutch mechanism 535. Then, the rotational motion is transmitted to the animal power mechanism 536 having a relief clutch mechanism, and only a force necessary for bullet feeding is used. Since the momentum transmitted from the magazine driving member is larger than the momentum necessary for bullet feeding, a part of the momentum is consumed and a part is consumed by the escape clutch mechanism. Due to this animal power, the spherical bullet is always pushed in the direction of the arrow 540. However, since the mechanism as shown in FIG. 15 and FIG. 16 is arranged at the discharge part of the spherical bullet, the spherical bullet will not jump out unless it is set on the gun. The description of the thirty-seventh embodiment relates to claims 1, 2, 4, 5, 6, 10, and 17.

  Next, another embodiment of the present invention in which bullet feeding is performed using a horizontal screw will be described.

  FIG. 72 is a schematic structural explanatory view of a thirty-eighth embodiment according to the present invention. In the previous example, FIG. 71, FIG. 37, bullet feed was performed using a vertical screw, but here, a horizontal screw 541 is used instead. The mechanism for converting the reciprocating motion into a unidirectional rotational motion is the same as that in FIG. A bevel gear 543 is attached to the tip of the shaft 542. A bevel gear 545 is also attached to the tip of the shaft 544 of the horizontal screw 541 and meshes with the bevel gear 543. Further, a pinion gear 546 is also attached to the shaft 544 and can be rotated a little by touching with a finger from the direction of the arrow 547. This eliminates the biting of spherical bullets.

  The passive member base 548 and the screw pin base member 549 can be integrated into one component. The same applies to the embodiments shown in FIGS. 69, 70, and 71. The same applies to the embodiments from FIG. 20 to FIG. For example, the reciprocating motion of the gun side magazine driving member is designed as a reciprocating motion of 8 mm. On the other hand, the reciprocating motion of the screw pin base member 549 on the passive magazine side may be designed as a reciprocating motion of 6 mm. Alternatively, in the third embodiment of FIG. 20 and the like, it is sufficient to feed only one ratchet tooth, so that the stroke required by the ratchet push bar 142 is sufficient even at 4 mm. The spring 144, the spring 550, etc. absorb the difference between the design value of the reciprocating motion of the magazine drive member and the design value of the reciprocating motion that the magazine side finally needs. If all parts are made with high accuracy and assembled with high accuracy, the design value of the reciprocating motion of the magazine drive member may be the same as the design value of the reciprocating motion that the magazine side finally needs. Alternatively, as shown in the ninth embodiment of FIG. 33, a clearance may be provided between the magazine driving member and the passive member for adjustment. By doing so, the passive member base 548 and the screw pin base member 549 can be integrated into one component.

  So far, several embodiments of the present invention have been shown in which the reciprocating motion of the magazine driving member is converted into rotational motion using various motion converting mechanisms to perform bullet feeding. Next, another embodiment of the present invention will be described in which the rotational force of the gun-side motor is transmitted to the passive member while the rotational force is maintained, and the bullet is sent.

  FIG. 73 is a schematic structural explanatory view of a 39th embodiment according to the present invention. The thirty-ninth embodiment of FIG. 73 is very similar to the twenty-first embodiment of FIG. 53 In the 21st embodiment, first, the rack gear 375 and the pinion gear 376 are removed from the gun side, and then the ratchet arm 380 and the coupling 381 serving as a one-way clutch mechanism are removed from the magazine side. FIG. 73 is the 39th embodiment in which a spur gear 551 is added to the gun side. There are no other differences. 53 In the twenty-first embodiment, since the rotational force of the motor is converted into a reciprocating motion in the X-axis direction via a reduction gear group and a cam mechanism, the rack gear and pinion gear are used again thereafter. Thus, it is converted into a reciprocating rotational motion having a rotational axis in the X-axis direction, and finally converted into a unidirectional rotational motion using a one-way clutch mechanism to function the bullet feeding mechanism. 73, in the thirty-ninth embodiment, the rotational force of the motor is branched out from an arbitrary gear in the group of reduction gears (in this example, a spur gear 553 provided coaxially with the rotation drive member 552), and the spur gear 551 is taken out. The pinion bevel gear 554, the bevel gear 555, and the shaft 556 are transmitted to rotate the bevel gear as the magazine drive member 557 in one direction. Since the transmitted driving force is already rotational movement in one direction, the bevel gear which is the passive member 558 also rotates in one direction. Therefore, on the magazine side, the animal power mechanism 559 having the same structure as that shown in FIG. The description after the shaft 560 is omitted in the twenty-first embodiment of FIG.

  FIG. 73 shows an embodiment in which a bevel gear is used as a magazine driving member to output a rotational motion in the X-axis direction and the passive member is also passively used as a rotational motion in the Z-axis direction using a bevel gear. Next, another embodiment of the present invention will be described in which the mechanism in the gear box is exactly the same as that of the 39th embodiment of FIG. In this embodiment, a pinion gear is used as the magazine driving member and a spur gear is used as the passive member.

  FIG. 74 is a schematic structural explanatory diagram of a 40th embodiment according to the present invention. The magazine drive member 561 is a pinion gear, and the passive member 562 is a spur gear. The magazine is an embodiment having exactly the same structure as the twenty-second embodiment of FIG. The magazine drive member 561 that is the output unit has already been rotated in one direction. The description after the passive member 562 is exactly the same as that of the twenty-second embodiment of FIG.

  FIG. 74 shows an embodiment in which a rotary motion having a rotation axis in the X-axis direction is output from the gun side, and the magazine side is also passively driven as a rotary motion having a rotation axis in the X-axis direction. Next, a rotational motion having a rotational axis in the same direction (Y-axis direction) as the rotational axis of the rotational drive member is output from the gun side, and the magazine side is also passively driven as a rotational motion having a rotational axis in the Y-axis direction. Another embodiment of the invention is shown. In this embodiment, a spur gear is used for the magazine drive member and a spur gear is used for the passive member.

  FIG. 75 is a schematic structural explanatory view of a forty-first embodiment according to the present invention. 75. The forty-first embodiment is very similar to the twentieth embodiment of FIG. 52, the rack gear 360 is first removed from the gun side, then the pinion gear is removed from the magazine drive member 355, and a pinion / spar gear 563 is added instead, as shown in FIG. It is an example. The arrangement position of the pinion spur gear 565 is slightly moved. There are no other differences. The magazine is an embodiment having exactly the same structure as the twentieth embodiment of FIG. The magazine drive member 564, which is the output unit, has already rotated in one direction. The description after the passive member 566 is exactly the same as that of the twentieth embodiment of FIG. Although the one-way clutch mechanism arranged inside the pulley 567 is not necessary, it does not become an obstacle.

  FIG. 73 shows an embodiment in which a bevel gear is used as a magazine driving member to output a rotational motion in the X-axis direction and the passive member is also passively used as a rotational motion in the Z-axis direction using a bevel gear. FIG. 74 shows an embodiment in which a rotation motion in the X-axis direction is output using a pinion gear as a magazine driving member, and passive movement is also performed as a rotational motion in the X-axis direction using a spur gear as a passive member. FIG. 75 shows an embodiment in which a spur gear is used as a magazine drive member to output a rotational motion in the Y-axis direction, and a passive member is also passively used as a rotational motion in the Y-axis direction using a spur gear. Next, another embodiment of the present invention in which the mechanism in the gear box is very similar to that of the twenty-fourth embodiment of FIG. 56 and the magazine driving member as the output unit is the same will be described. In this embodiment, a crown gear is used as the magazine driving member and a crown gear is used as the passive member.

  FIG. 76 is a schematic structural explanatory view of a forty-second embodiment according to the present invention. The magazine drive member 568 outputs a rotary motion in the Z-axis direction using a crown gear, and the passive member 569 is also passively driven as a rotary motion in the Z-axis direction using a crown gear. 56 In the twenty-fourth embodiment, a rack drive and a pinion gear are used to give a reciprocating rotational motion to the magazine drive member. In contrast to this, in the forty-second embodiment shown in FIG. 76, the magazine drive member is given a unidirectional rotational motion by using a spur gear 570 with pulley and a bevel gear 571 with pulley. The two pulleys are provided with a belt 572 to transmit a driving force. The description of the passive member 569 and later is omitted in the twenty-first embodiment of FIG. 53 and the twenty-fourth embodiment of FIG.

  Next, another embodiment of the present invention will be described in which an inertial force is applied to the magazine driving member, and the leading end portion of the magazine driving member pops out from the gear box or gun main body side for a moment.

  FIG. 77 is a schematic structural explanatory view of a forty-third embodiment according to the present invention. 77. The forty-third embodiment is similar to the fourteenth embodiment of FIG. In the fourteenth embodiment shown in FIG. 42, the magazine driving member 274 is fixed to the arm member and only performs a simple reciprocating motion in the X-axis direction. However, in the thirty-fourth embodiment shown in FIG. Is not fixed to the arm member and does not perform simple reciprocation in the X-axis direction.

  A support member 575 is provided below the arm member 574, and the hook member 577 is disposed on the shaft 576 so as to be rotatable. A spring 578 is disposed between the hook member 577 and the arm member 574, and the rear end of the hook member 577 pushed by the spring 578 is positioned by a stopper 579. There is an inclined portion 580 at the tip of the hook member 577, and when the hook member 577 advances in the X-axis direction, the hook member 577 eventually hits the stopper 581 provided in the gear box as shown in FIG. Will rotate. The striker 582 is guided by the pin 583 and the pin 584 and can move only in the X-axis direction. The striker 582 is pushed in the direction of the arrow 586 by a spring 585. The magazine drive member 573 is pulled in the direction of arrow 588 by a spring 587. The magazine drive member 573 is provided with an elongated hole 589, and a pin 591 at the tip of the direction changing member 590 enters. The direction changing member 590 is supported by the shaft 592 and is rotatable. Since the force of the spring 585 that pushes the striker 582 is set to be stronger than the force of the spring 587 that pulls the magazine driving member 573, the rear end portion 593 of the striker 582 is connected to the upper end portion of the direction changing member 590 by the arrow 586. Pushing in the direction. The magazine drive member 573 is pushed forward by a pin 591 at the tip of the direction changing member 590. The spring 587 is pulled in a direction opposite to the direction of the arrow 588 and slightly extends. In such an initial state, the front end portion 594 of the magazine drive member 573 does not protrude from the end surface portion 595 of the gear box. Therefore, the magazine 596 can be inserted in the direction of the arrow 597.

  The basic structure of the magazine 596 is similar to the fourteenth embodiment of FIG. The passive member 275 in the fourteenth embodiment shown in FIG. 42 is set on the passive member base 276 and is pushed up by the spring 277. The three parts are formed in a key shape and move integrally around the shaft 278. The passive member 275 can be retracted when pushed from above. The passive member 275 is exposed so as to protrude from the upper end surface of the magazine. In contrast, in the magazine 596 in the 43rd embodiment of FIG. 77, the passive member 598 is a single key-shaped part and is supported by the shaft 600. The upper end portion of the passive member 598 is not exposed so as to protrude from the upper end surface portion of the magazine. The upper end portion of the passive member 598 is at the back of the window portion 599 provided on the rear end surface portion of the magazine. Since there are no exposed parts on the outside of the magazine, there is a feature that makes the appearance of the magazine more realistic. Further, the front end 594 of the magazine drive member 573 does not protrude from the end surface 595 of the gear box, so that there is no obstacle when the magazine 596 is attached or detached. The feature of this example is that the appearance of the magazine is real, and that the magazine is smoothly attached and detached.

  In FIG. 78, when the rotation drive member 601 rotates in the direction of the arrow 602, it is pushed by the cam portion 603 and the arm member 574 advances in the X-axis direction. The inclined portion 580 at the tip of the hook member 577 hits the stopper 581, and the hook member 577 rotates in the direction of the arrow 604. Meanwhile, the striker 582 is pushed forward by the hook member 577 and advances together in the direction of the arrow 605, and the spring 585 is contracted to generate power. The direction changing member 590 is not affected by the striker 582 and rotates in the direction of the arrow 606. The magazine drive member 573 is pulled by the spring 587 and moves in the direction of the arrow 607. However, the magazine drive member 573 abuts on the stopper 608 provided on the gear box and cannot move back further. The catch between the hook member 577 and the striker 582 is in a limit state where the hook member 577 and the striker 582 are separated.

  FIG. 79 shows a state where the rotation driving member 601 further rotates in the direction of the arrow 602 and the hook member 577 and the striker 582 are not caught. The animal power of the spring 585 is released, and the striker 582 moves backward in the direction of the arrow 609. The rear end portion 593 of the striker 582 collides with the upper portion of the direction changing member 590, and the magazine driving member 573 moves forward in the direction of the arrow 610. The magazine driving member 573 is made of a metal having a large specific gravity and has a large inertia. Since the spring 587 is a very weak spring, it extends against the inertia of the magazine drive member 573 that moves forward vigorously. As a result, the front end 594 of the magazine drive member 573 jumps out of the end surface portion of the gear box and enters the window portion 599 provided on the rear end surface portion of the magazine, and the upper end portion of the passive member 598 is urged in the direction of the arrow 611. Press well. The arm portion of the passive member 598 moves in the direction of the arrow 612 and pushes down the intermediate member 613. In conjunction with this, the ratchet hook 614 moves in the direction of the arrow 615 and rotates the ratchet 616 in the direction of the arrow 617. The bullet feed mechanism works now.

  Immediately thereafter, the magazine drive member 573 is pulled back by the action of the spring 587 by the amount of space of the long hole 589, and returns to the initial state as shown in FIG. The passive member 598 is also pushed by the spring 618 and returns to the initial state. Eventually, when the rotation driving member 601 further rotates in the direction of the arrow 602, the arm member 574 retracts and returns to the initial state as shown in FIG. The hook member 577 is also pushed by the spring 578 and returns to the initial state as shown in FIG. This completes one basic cycle. Thereafter, the rotation driving member 601 continues to rotate, and this basic cycle is repeated.

  The feature of the forty-third embodiment is that the magazine driving member 573 is operated vigorously by performing the animal power operation in the engine part of the gun and releasing the animal power, and the magazine driving member 573 is operated by the inertia of the magazine driving member 573. The point is that the tip portion 594 of 573 is projected from the end surface portion 595 of the gearbox (or gun body) for a moment. The tip 594 of the magazine drive member 573 jumps out for a moment and then retracts instantaneously.

  In the forty-third embodiment, the same gun engine portion as in the first embodiment is used, in which the arm member is pushed forward by the cam portion provided in the rotation drive member, but the same as in the second embodiment. It is also possible to use a gun engine part of That is, the same gun engine unit as in the second embodiment is used, in which the arm member is pushed backward by a cam pin provided on the rotation drive member. In that case, the support member 575, the shaft 576, the hook member 577, the spring 578, the stopper 579, the stopper 581, the striker 582, the pin 583, the pin 584, the spring 585, etc. are arranged on the lower part of the arm member with respect to the Z axis. May be arranged symmetrically. By doing so, when the arm member is pushed rearward, the spring for the striker can be pushed and shrunk and the animal can be fed. The striker away from the catch with the hook member moves forward vigorously by releasing the stock of the spring. The movement is transmitted to the magazine drive member with the same directionality. In the method of pushing the arm member backward, the direction changing member is not necessary. The magazine driving member that has received the striking force from the striker causes the tip of the magazine driving member to jump out of the end face of the gear box (or gun body) for a moment due to the inertia of the magazine driving member. The tip of the magazine drive member jumps out for a moment and then retracts instantly. As described above, both the first embodiment in which the arm member is pushed forward and the second embodiment in which the arm member is pushed backward can perform the animal power operation for the striker in the engine part of the gun.

  An example similar to the 43rd embodiment will be described with reference to FIGS. 103 and 104. Other implementations of the present invention in which the magazine drive member is operated vigorously and the tip of the magazine drive member jumps out of the end face of the gear box (or gun body) for a moment due to the inertia of the magazine drive member It is an example. In order to give inertia to the magazine drive member, there is a feature in that the striking force of the piston is used.

  Next, another embodiment of the present invention in which a magazine is set from above the gun will be described.

  FIG. 80 is a schematic structural explanatory diagram of a forty-fourth embodiment according to the present invention. Since it is a system that is greatly different from conventional guns, the overall configuration will be described first.

  The gun shown is a gun called P90. The front is depicted as the X-axis direction and the top as the Z-axis direction. From the magazine 620 set in the gun body 619, the spherical bullet 621 is supplied to the gun side as indicated by an arrow 622. The magazine 623 is a diagram drawn from the direction of viewing the XY plane (Z-axis direction). When removing the magazine from the gun, the magazine 620 is lifted and tilted in the direction of arrow 624 and then pulled out in the direction of arrow 625. When setting, the reverse procedure is performed. The detailed structure is shown in FIG.

  In order to transmit the magazine driving force from the gun side to the magazine 620 set on the gun body 619, there are restrictions on the direction and position of transmission. First, there is a method of transmitting from the direction of the arrow 627 to the lower end surface 626 of the magazine 620 that is a surface from which the spherical bullet 621 is discharged, that is, a surface perpendicular to the Z axis. Next, there is a method of transmitting from the direction of the arrow 629 to the rear end face 628 of the magazine 620. There are transmission methods from the direction of arrow 630 and the direction of arrow 631, which are different from these two transmission methods, but transmission from the direction of arrow 630 is substantially the same as the transmission method from the direction of arrow 627. But it was just a detour. Similarly, the transmission from the direction of the arrow 631 is substantially the same as the transmission method from the direction of the arrow 629, and is merely detoured to a distant place. Therefore, in the future, a method of transmitting from the direction of the arrow 627 and a method of transmitting from the direction of the arrow 629 will be described.

  FIG. 81 is an explanatory diagram of a schematic structure relating to the magazine of the forty-fourth embodiment. The magazine 623 in FIG. 80 is a view drawn from the direction of viewing the XY plane (Z-axis direction), but does not show the internal structure. FIG. 81 depicts the approximate structure of magazine 623. The plurality of spherical bullets placed in the magazine 623 are pushed in the direction of the arrow 634 by the push plate 633 pushed by the spring 632. The spherical bullet is sent out by the sprocket 636 rotating in the direction of the arrow 635 and discharged from the discharge port 637. The direction of discharge is the Z-axis direction. As shown in FIG. 18, the structure of the sprocket portion is a power spring that uses a spring spring, and an escape clutch mechanism is formed by an R convex portion formed on the outer end portion of the main spring and a plurality of concave portions provided on the inner wall of the sprocket. It is a structured structure.

  FIG. 82 is a schematic structural explanatory view of the sprocket portion of the forty-fourth embodiment. In FIG. 81, since it is difficult to understand, only the sprocket portion is extracted and drawn. The spring spring 638 has one end fixed to the central shaft 639. In the past, a long spring spring was used to send out about 300 spherical bullets. However, according to the present invention, the spring spring 638 only needs to be capable of delivering about 3 to 10 shots. It can be short. Conventionally, a knob for manually winding the mainspring is provided so as to be exposed to the outside of the magazine. However, according to the present invention, a magazine-side bullet feeding mechanism using a driving force from the gun side is provided. This function is not necessary. Of course, there is no need to roll up 300 shots. The central shaft 639 and the ratchet 640 are integrally fixed and rotate together. The sprocket 636 and the central shaft 639 are not integrated, and the sprocket 636 rotates in the direction of the arrow 635 around the central shaft 639. The spring 641 prevents the ratchet 640 from reversing.

  FIG. 83 is a schematic structural explanatory view of the ratchet portion of the forty-fourth embodiment. In FIG. 82, since it is difficult to understand, only the ratchet portion is extracted and drawn. The ratchet 640 rotates around the central axis 639 in the direction of the arrow 642. The spring 641 prevents the ratchet 640 from reversing.

  The basic structure of the magazine of an electric air gun modeled after a gun called P90 is as described above. After that, if the center shaft 639 is rotated in the direction of the arrow 642 using the driving force from the gun side, the magazine-side bullet feeding mechanism functions.

  FIG. 84 is a schematic structural explanatory view of a forty-fourth embodiment according to the present invention. From the magazine 644 set in the gun body 643, spherical bullets 645 are supplied to the gun side as indicated by arrows 646. The magazine 647 is a diagram drawn from the direction (Z-axis direction) in which the XY plane is viewed. The basic structure of the gun engine section is almost the same as that of the first embodiment shown in FIG. There is a difference in the arrangement method of the motor and the reduction gear group, and there is a difference in the arrangement method of the magazine drive member. In the first embodiment shown in FIG. 8, the magazine drive member 26 is disposed below the cylinder 5, but in the 44th embodiment shown in FIG. 84, the magazine drive member 648 is disposed above the cylinder 649. The engaging portion protrusion 651 at the tip of the arm member 650 is fitted in the lower recess of the nozzle unit 652, and the engaging portion protrusion 653 at the lower portion of the magazine drive member 648 is in the upper recess of the nozzle unit 652. I'm stuck. With this configuration, the arm member 650, the nozzle unit 652, and the magazine drive member 648 can move together. The rotation drive member 654 starts to rotate in the direction of the arrow 655, but the influence of the cam portion 656 has not yet reached the cam contact member 657. Accordingly, the arm member 650 is pushed by the spring 658 and is in the most retracted state in the direction of the arrow 659. Similarly, the magazine driving member 648 is in the most retracted state in the X-axis direction.

  The passive member 660 is arranged so as to be able to rotate around the shaft 661 and is pressed by a spring 662. The shaft 661 is set in the shaft hole of the passive member base 663, and the passive member 660, the shaft 661, the spring 662, and the passive member base 663 move integrally. Since the magazine 644 is provided with a rail portion 664 and the passive member base portion 663 is provided with a guide groove 665 and is fitted to each other, the passive member base portion 663 can move only in the X-axis direction. The passive member base 663 is always pushed in the direction of the arrow 667 by the spring 666. A ratchet hook base 668 is attached to the passive member base 663, and the ratchet hook 669 is attached so as to be able to rotate about the shaft 670. A spring 671 acts on the ratchet hook 669 and is always pushed. With this configuration, when the ratchet hook base 668 moves in the direction of the arrow 672, the ratchet 673 rotates in the direction of the arrow 674 by one tooth. The spring 675 prevents the ratchet 673 from reversing.

  Another set of feeding mechanisms is added to such a configuration. A ratchet hook base 676 is attached to the passive member base 663, and the ratchet hook 677 is attached so as to be able to rotate about the shaft 678. A spring 679 acts on the ratchet hook 677 and is always pushed. With such a configuration, when the ratchet hook base 676 moves forward in the direction of the arrow 672 and then moves backward in the direction of the arrow 680, the ratchet 673 rotates in the direction of the arrow 674 by one tooth. The spring 675 prevents the ratchet 673 from reversing.

  The state is shown in FIG.

  FIG. 85 is a schematic structural explanatory diagram of a forty-fourth embodiment according to the present invention. FIG. 84 shows an initial state in which the magazine driving member 648 is retracted most. The magazine drive member 648 and the passive member 660 were not yet in contact. When the rotation driving member 654 further rotates in the direction of the arrow 655, the cam portion 656 starts to push the cam contact member 657 forward, and the magazine driving member 648 also advances in the direction of the arrow 681 to start pushing the passive member 660. Eventually, the magazine drive member 648 advances most, pushes the passive member 660 all the way, the ratchet hook 669 also advances most in the direction of the arrow 672, and the ratchet 673 rotates in the direction of the arrow 674 by one tooth. The spherical bullet 645 is pushed by the nozzle member 682, set on the barrel packing 683, and fired.

  The ratchet hook 677 is also most advanced and is ready to rotate the ratchet 673 in the direction of arrow 674 by one tooth. Thereafter, when the magazine driving member 648 is retracted, the ratchet hook 677 is pushed by the spring 666 and moves in the direction of the arrow 680 to rotate the ratchet 673 by one tooth.

  84 and 85, the two feeding mechanisms of the ratchet hook 669 and the ratchet hook 677 are arranged, but basically any one of them may be provided. It can be selected whether to rotate the ratchet by one tooth when the passive member moves forward or to rotate the ratchet by one tooth when the passive member moves backward. 84 and 85 show the two methods together. In FIG. 84, the passive member 660 is inside the magazine 644 and is not exposed to the outside in a convex shape. The magazine driving member 648 is depicted as a member that protrudes greatly from the gun body 643. You may reverse the state of these two members. That is, the passive member 660 can be exposed to the outside of the magazine 644 so that the magazine driving member 648 can hardly protrude from the gun body 643. By doing so, the passive member 660 exposed in a convex shape outside the magazine 644 can be operated by pushing it with the hand. Similar contents have already been described in the third embodiment of FIG. 22, the eleventh embodiment of FIG.

  FIG. 86 is a schematic structural explanatory view of a forty-fourth embodiment according to the present invention. FIG. 11 is a view when shooting is finished with the magazine drive member 648 moving forward, the magazine 647 is removed, the bullets are replenished, and then the magazine 647 is set in the direction of the arrow 684 again. The passive member 660 is slightly rotated in the direction of the arrow 685 about the shaft 661. When shooting is started again from such a state, the magazine drive member 648 moves backward to return to a normal state as shown in FIG. The passive member 660 is also pushed by the spring 662 and returns to the state shown in FIG. If the magazine drive member has no inclined part and no retracting mechanism, a mechanism for retracting to the passive member side is necessary. Similar contents have already been described in the first embodiment, the second embodiment, the twelfth embodiment, the fourteenth embodiment, the 63rd embodiment, and the like. Conversely, when the passive member has no inclined portion and no retracting mechanism, a mechanism for retracting to the magazine drive member side is necessary. Similar contents have already been described in the eleventh embodiment, the thirteenth embodiment, the 64th embodiment, and the like. The forty-fourth embodiment is an embodiment in which the magazine functions when pressed when simply expressed.

  In the forty-fourth embodiment of FIG. 84, the embodiment of the present invention is shown using the same basic structure as that of the first embodiment of FIG. Next, another embodiment of the present invention will be described using the same basic structure as that of the second embodiment of FIG.

  FIG. 87 is a schematic structural explanatory view of a forty-fifth embodiment according to the present invention. The basic structure of the gun engine section is almost the same as that of the second embodiment of FIG. There is a slight difference in the arrangement method of the motor and the reduction gear group, and there is a slight difference in the shape and arrangement method of the magazine drive member. In the second embodiment shown in FIG. 12, the magazine driving member 89 is disposed below the bullet feeding nozzle member 88. However, in the 45th embodiment shown in FIG. 87, the magazine driving member 686 is formed by the bullet feeding nozzle member 687. It is arranged above. The magazine driving member 686 has an inclined portion. The arm member 688 is pulled by the spring 689 and is in the most advanced state in the direction of the arrow 690. Similarly, the magazine driving member 686 is in the most advanced state in the X-axis direction.

  The passive member 691 is disposed so as to be rotatable about the shaft 692 and is pressed by a spring 693. The magazine 694 is a diagram drawn from the direction (Z-axis direction) in which the XY plane is viewed. Since the structure shown in FIG. 84 is basically the same as the structure shown in FIG. The major difference is that the spring 666 in FIG. 84 is a push spring and always pushes the passive member base 663 in the direction of the arrow 680, whereas in the 45th embodiment in FIG. 87, the spring 695 is a tension spring. The passive member base 696 is always pulled in the direction of the arrow 697. 87, when the magazine driving member 686 is retracted and the passive member 691 is pulled in the direction of the arrow 698, the ratchet hook 699 moves in the direction of the arrow 700, and the ratchet 701 is one tooth in the direction of the arrow 702. Only rotate. Since the spring 695 is pulled and extended, the next time the magazine drive member 686 advances in the direction of the arrow 690, the parts group such as the passive member base 696, the ratchet hook 699, and the passive member 691 are moved in the direction of the arrow 697. Pull back. This completes one basic cycle. Thereafter, the rotation driving member 703 continues to rotate, and this basic cycle is repeated.

  84 In the forty-fourth embodiment, the passive member 660 is drawn so as not to jump out of the magazine 644. However, in the forty-fifth embodiment in FIG. 87, the leading end 704 of the passive member 691 extends from the lower end surface of the magazine 694. A little popping out.

  FIG. 88 is a schematic structural explanatory view of a forty-fifth embodiment according to the present invention. A state in which a magazine 705 drawn with diagonal lines is set on the gun body 707 in the direction of an arrow 706 is depicted. It can be seen that the front end portion 704 of the passive member 691 slightly protrudes from the lower end surface portion 708 of the magazine 694. If there is a convex portion that protrudes a little like this, it can be operated with a finger. The magazine 709 depicts a state where it is set on the gun body 707. FIG. 11 is a view when the magazine drive member 686 has advanced to the middle, finishes shooting, removes the magazine 705, replenishes bullets, and then sets the magazine 705 in the direction of the arrow 706 again. The leading end portion 704 of the passive member 691 is pushed by the leading end portion of the magazine driving member 686, and the passive member 691 is slightly rotated in the direction of the arrow 710 about the shaft 692. When shooting is started again from such a state, the magazine driving member 686 moves forward in the direction of the arrow 711 and returns to the normal meshing state as shown in FIG. The 45th embodiment in FIG. 87 is an example similar to the twelfth embodiment in FIG. It is characterized in that the tip of the passive member slightly protrudes from the end surface of the magazine toward the cylinder axis. The forty-fifth embodiment is an embodiment in which the magazine functions when pulled if simply expressed.

  FIG. 89 is a schematic structural explanatory view of a forty-sixth embodiment according to the present invention. The passive member 712 is provided with a rack gear 713 and a spur gear 714 is engaged therewith. This structure is similar to the twenty-fifth embodiment of FIG. 58, so the mechanism is already in an understandable range. A spur gear 715 having an internal ratchet is engaged with the spur gear 714. This structure is similar to the structure of the parts group related to the pulley 342 having the internal ratchet in the nineteenth embodiment of FIG. There is a through hole at the center of the spur gear 715, and the central shaft 717 of the ratchet arm 716 passes therethrough. The central shaft 717 is the same as the central shaft 639 in the 44th embodiment of FIG. The sprocket 636 is rotated in the direction of the arrow 635 via the mainspring 638. An arrow 718 depicts the direction in which the magazine driving member transmits force to the passive member 712. The structural view of the XZ plane is almost the same as that of the forty-fourth embodiment of FIG. Since the description is duplicated, details are omitted. When the passive member 712 is pushed in the direction of the arrow 718, the rack gear 713 moves forward in the direction of the arrow 719, the spur gear 714 rotates in the direction of the arrow 720, and the spur gear 715 having an internal ratchet rotates in the direction of the arrow 721. To do. Since a return spring (not shown) is disposed on the passive member 712, when the magazine driving member is retracted, the passive member 712 is also retracted. At that time, the center shaft 717 does not rotate by the action of the spur gear 715 having the internal tooth ratchet and the ratchet arm 716. This part is a one-way clutch mechanism. Accordingly, the reciprocating motion of the passive member 712 in the X-axis direction rotates the central shaft 717 only in the direction of the arrow 721. The 46th embodiment is an embodiment in which the magazine functions when pressed when simply expressed.

  FIG. 90 is a schematic structural explanatory diagram of a 47th embodiment according to the present invention. The passive member 722 is provided with a rack gear 723 and a spur gear 724 is engaged. This structure is similar to the 46th embodiment of FIG. There is only a difference in rack gear arrangement. In this way, when the passive member 724 is pulled in the direction of the arrow 725, the rack gear 723 moves backward in the direction of the arrow 726, the spar gear 724 rotates in the direction of the arrow 727, and the spar gear 728 having the internal tooth ratchet is Rotate in the direction of arrow 729. This part is a one-way clutch mechanism. Therefore, the reciprocating motion of the passive member 722 in the X-axis direction rotates the central shaft 730 only in the direction of the arrow 729. Since a return spring (not shown) is disposed on the passive member 722, when the magazine driving member advances, the passive member 722 also advances. The structural view of the XZ plane is almost the same as that of the 45th embodiment shown in FIG. Since the description is duplicated, details are omitted. The 47th embodiment is an embodiment in which the magazine functions when pulled in a simple manner. 89 In the 46th embodiment and the 90th embodiment in FIG. 90, the rack gear arranged on a straight line is reciprocated linearly in the X-axis direction to reciprocately rotate the spur gear arranged in the magazine. I exercised. By changing the rack gear arranged on the straight line to the rack gear arranged on the arc, the spur gear arranged in the magazine can be reciprocally rotated. 67 may be referred to with reference to the 33rd embodiment. 67 In the thirty-third embodiment, the magazine drive member 497 having an inclined portion is pulled in the direction of the arrow 498, that is, in the direction of the X axis, thereby pushing down the passive member 499 in the arc shape in the direction of the Z axis. It was. However, it is obvious that the passive member 499 may be pushed down linearly in the Z-axis direction. 67 In the thirty-third embodiment, the drawing is drawn so as to see the XZ plane, but the passive member 499, the passive member base 501, the fan-shaped rack gear 503 and the like drawn there are drawn so as to see the XY plane. What is necessary is just to apply to a magazine, such as the 46th Example and FIG. 90 47th Example. Alternatively, if the vicinity of the front end of the sector rack gear 503 in the thirty-seventh embodiment of FIG. 67 is shaped similar to the front hook portion of the ratchet hook 759 of the magazine 753B in the fifty-first embodiment of FIG. The ratchet that acts on the sprocket can also be rotated in one direction. Such a drawing is drawn in the 59th embodiment of FIGS. 109 and 110 and will not be described here.

  FIG. 91 is a schematic structural explanatory view of a forty-eighth embodiment according to the present invention. A long hole 732 is provided at the tip of the passive member 731, and a pin 734 provided in the sector gear 733 is fitted therein. Since this structure is similar to that of the twenty-sixth embodiment of FIG. When the passive member 731 is pushed in the direction of the arrow 735, the sector gear 733 rotates in the direction of the arrow 736, and the spar gear 737 having the internal tooth ratchet rotates in the direction of the arrow 738. Since a return spring (not shown) is disposed on the passive member 731, the passive member 731 is also retracted when the magazine drive member is retracted. The 48th embodiment is an embodiment in which the magazine functions when pressed when simply expressed.

  FIG. 92 is a schematic structural explanatory diagram of a 49th embodiment according to the present invention. This structure is in a range where the mechanism can already be understood by the embodiments of FIGS. 89, 90, and 91. When the passive member 739 is pulled in the direction of the arrow 740, the sector gear 741 rotates in the direction of the arrow 742, and the spar gear 743 having the internal ratchet rotates in the direction of the arrow 744. Since a return spring (not shown) is disposed on the passive member 739, when the magazine drive member advances, the passive member 739 also advances. The 49th embodiment is an embodiment in which a magazine functions when pulled in a simple manner.

  Next, another embodiment of the present invention in which the magazine driving member is a gear and the passive member is also a gear will be described.

FIG. 93 is a schematic structural explanatory diagram of a 50th embodiment according to the present invention. This structure is in a range where the mechanism can already be understood by the embodiment of FIG. In the embodiment of FIG. 91, the sector gear is arranged on the magazine side, but in FIG. 93, the sector gear 745 is arranged on the gun body side. The sector gear 745 has a gear group for adjustment arranged in the middle by the distance from the central axis of the spur gear 746 having an internal tooth ratchet. By doing so, the reciprocating motion in the X-axis direction created by the engine unit on the gun body side can be converted into a reciprocating rotational motion centered on the Z-axis and output for transmission to the magazine side. Become. Since the spur gear 747, which is a passive member, is exposed from the magazine, it can be operated with a finger. The reciprocating motion in the X-axis direction created by the engine section on the gun body side is the reciprocating motion of the cylinder, arm member, bullet feeding nozzle member, etc., which has already been described. These members and the translation member 748 are linked. When the translation member 748 is pushed in the direction of the arrow 749, each gear rotates in the direction of the arrow shown. When the translation member 748 is pulled back in the direction opposite to the direction of the arrow 749, each gear rotates in the direction opposite to the direction of the arrow shown. However, the central shaft 750 rotates only in the direction of the arrow 752 by the action of the ratchet arm 751, and does not reverse. The 50th embodiment is an embodiment in which the magazine functions when the passive member is reciprocally rotated.

  The 50th embodiment of FIG. 93 performs output and passive similar to the twentieth embodiment of FIG. That is, the magazine drive member is reciprocally rotated and output, the passive member is reciprocally rotated to be passive, and then a one-way clutch is used on the magazine side to obtain a one-way rotational motion. However, if a one-way clutch is used on the gun body side to obtain a rotational movement in one direction, the magazine drive member is rotated and output in a fixed direction, and the passive member is also rotated and moved in a fixed direction. Can be made. Such an application example is shown in the embodiment of FIG. 54 and will not be described.

  FIG. 94 is a schematic structural explanatory diagram of a fifty-first embodiment according to the present invention. The state in which the magazine 753 is set on the gun body 754 is drawn as seen from the direction of viewing the XZ plane (Y-axis direction). Magazines 753A and 753B are partial views illustrating the structure of the magazine viewed from the direction of viewing the XY plane (Z-axis direction). The magazine 753A is an example that employs a method of rotating the ratchet 757 by one tooth in the direction of the arrow 758 when the ratchet hook 755 moves in the direction of the arrow 756. The magazine 753B is an example that employs a method of rotating the ratchet 761 by one tooth in the direction of the arrow 762 when the ratchet hook 759 moves in the direction of the arrow 760. The spring 763 is a spring that pushes back the ratchet hook base 764 in the direction of the arrow 756. The spring 765 is also a spring that pushes back the ratchet hook base 766 in the direction of the arrow 760.

  The passive member base 767 is attached to a support member 769 provided in the magazine by a shaft 768. The passive member 770 is provided at the lower portion of the passive member base 767 and is exposed in a convex shape from the lower end surface portion of the magazine 753. Therefore, when the magazine is removed from the gun body, the passive member 770 exposed in a convex shape can be operated with a finger. The passive member base 767 is provided with an arm portion 771 extending in the Z-axis direction. When the passive member 770 is pushed up, the passive member base 767 moves so as to rotate in the direction of the arrow 772 around the shaft 768.

  When the arm portion 771 moves in the direction of the arrow 772, in the magazine 753A, the ratchet hook base portion 764 is pushed in the direction of the arrow 773, and the ratchet hook 755 also moves in the direction of the arrow 773. The state is a state where one tooth is ready for rotation. When the passive member 770 is pushed back by the action of the spring 774, the ratchet hook 755 is pushed back in the direction of the arrow 756 by the action of the spring 763, and the ratchet 757 is rotated by one tooth in the direction of the arrow 758. Return to the initial state.

  When the arm portion 771 moves in the direction of the arrow 772, in the magazine 753B, the ratchet hook base 766 is pushed in the direction of the arrow 760, and the ratchet hook 759 also moves in the direction of the arrow 760. In this state, the ratchet 761 is rotated by one tooth in the direction of the arrow 762. When the passive member 770 is pushed back by the action of the spring 774, the ratchet hook base 766 is pushed back in the direction of the arrow 775 by the action of the spring 765 and returns to the initial state as shown.

  The magazine driving member 776 is provided integrally with the bullet feeding nozzle member 777 and is in the most advanced state in the direction of the arrow 778. When the rotational drive member 779 rotates in the direction of the arrow 780, the magazine drive member 776 starts to retract and eventually reaches the most retracted state. This is the state shown in FIG.

  FIG. 95 is a schematic structural explanatory diagram of a fifty-first embodiment according to the present invention. The magazine drive member 776 is in the most retracted state in the direction of arrow 781. The bullet feeding nozzle member 777 is also in the most retracted state, and the spherical bullet 782 falls to the illustrated position.

  The positioning member 783 receives the spherical bullet 782 that has fallen, and makes the positional relationship of the next spherical bullet 784 in the Z-axis direction the same as the position of the spherical bullet 782 in FIG. The position of the spherical bullet 782 in FIG. 94 is a position where the bullet bullet 782 is in contact with the bullet feed nozzle member 777. Even when the bullet feeding nozzle member 777 is retracted by the action of the positioning member 783, as shown in FIG. 95, the positional relationship of the next spherical bullet 784 in the Z-axis direction is changed to the position of the spherical bullet 782 in FIG. Can be the same. In FIG. 84, FIG. 85, etc., a positioning member of a type that rotates about an axis is illustrated. If there is no positioning member that moves slightly in conjunction with the movement of the bullet feeding nozzle member and makes the positional relationship of the next spherical bullet constant, each time the bullet feeding nozzle member moves back and forth, the next spherical bullet The positional relationship is changed by being pushed by the tip of the bullet feeding nozzle member. The change reverses the bullet feeding mechanism in the magazine through a spherical bullet in the conveyance path, although it is slightly. Since the bullet feed mechanism is a mechanism that naturally sends out a spherical bullet in a certain direction, it is a failure to give the force to reverse it at a frequency of about 15 times per second each time it is shot. Cause. In a conventional electric air gun, the movement of a spherical bullet that reverses such a bullet feeding mechanism (actually, a movement close to a slight vibration with an amplitude of about 1 mm) has been ignored.

  The inclined portion of the magazine drive member 776 acts on the inclined portion of the passive member 770, the passive member base 767 rotates about the shaft 768, and the arm portion 771 is driven in the direction indicated by the arrow 772. Transmit power. In the magazine 753A, the tip of the arm portion 771 pushes the ratchet hook base portion 764, and the ratchet hook 755 also moves in the direction of the arrow 773, resulting in the state shown in the figure. The state is a state where one tooth is ready for rotation.

  In the magazine 753B, the tip of the arm portion 771 pushes the ratchet hook base 766, and the ratchet hook 759 moves in the direction of the arrow 760 to be in the state shown in the figure. In this state, the ratchet 761 is rotated by one tooth in the direction of the arrow 762.

  When the rotation driving member 779 continues to rotate in the direction of the arrow 780, the state of FIG. 94 and the state of FIG. 95 are alternately repeated, the bullet feeding mechanism in the magazine functions, and the spherical bullets continuously move to the gun side. To be supplied.

  Next, another embodiment of the present invention in which the mechanism on the gun body side is changed using a magazine having the same structure as the magazine described in FIGS. 94 and 95 will be described.

  FIG. 96 is a schematic structural explanatory view of a fifty-second embodiment according to the present invention. 94 and 95, an example in which the cylinder is fixed to the gun body is shown in the 51st embodiment, but an example in which the cylinder reciprocates in the X-axis direction is shown in the 52nd embodiment in FIG. This example is very similar to the example shown in FIG. In the sixth embodiment shown in FIG. 28, the magazine is set from the lower side of the gun engine unit. In FIG. 96, in the 52nd example, the magazine is set only from the upper side of the gun engine unit. Yes. The magazine drive member that moves integrally with the cylinder makes one reciprocation in the X-axis direction for each rotation of the rotary drive member, and the inclined portion of the magazine drive member and the inclined portion of the passive member come into contact with each other so that the passive member becomes an arc. A reciprocating motion is performed, and the arc-shaped reciprocating motion is converted into a rotational motion in a certain direction by using a ratchet, and is sent by a sprocket. The process is completely the same, except that the shape, size, and position of each part differ due to the difference in the shape of the gun. Therefore, the explanation is almost the same as that of the sixth embodiment shown in FIG.

  The piston end 786 provided at the rear of the piston 785 cannot be advanced any further by a stopper 787 provided on the gearbox or gun body. A cylinder head 789 is fixed to the front portion of the cylinder 788, and a nozzle member 790 is provided on the cylinder head 789. A magazine driving member 791 is provided at the upper front of the cylinder 788, and a cam contact member 793 is provided at the rear of the arm member 792. A spring 794 acts on the arm member 792, and the arm member 792 is always pulled forward. A push spring may be used in place of the tension spring in order to always apply a resilient force forward. The use of the push spring has already been described with reference to FIG.

  The passive member 795 is exposed in a convex shape from the end face of the magazine facing the cylinder or barrel (in this case, the lower end face of the magazine). The passive member 795 is fixed to the magazine 797 by a shaft 796 so as to be rotatable. The upper end portion of the arm portion 798 can rotate around the shaft 796. The spring 799 always pushes the passive member 795 in the direction of the arrow 800. The spherical bullet 801 cannot descend further because the nozzle member 790 is present. FIG. 96 depicts the most typical initial state that stops immediately after launch.

  FIG. 97 is a schematic structural explanatory view of a 52nd embodiment according to the present invention. FIG. 97 shows a state where the rotation driving member 802 is rotated in the direction of the arrow 803 and the cam contact member 793 is most retracted. The magazine drive member 791 is also most retracted in the direction of the arrow 804, and pushes up the passive member 795. Then, the upper end portion of the arm portion 798 integrated with the passive member 795 is rotated in the direction of the arrow 805 about the shaft 796. Thereafter, the mechanism in the magazine functions as shown in FIG. 95 to rotate the ratchet and sprocket, and the spherical bullet 806 is pushed down to the front of the nozzle member 790.

  In the 52nd embodiment, the cylinder 788, the cylinder head 789, the nozzle member 790, the magazine driving member 791, the arm member 792, and the cam contact member 793 can be formed as a single cylinder unit product, so that an inexpensive gun can be used. There is a feature that can be provided.

  In the 52nd embodiment, the method of pushing up the passive member when the magazine driving member is retracted has been described. Next, when the magazine driving member is retracted, the passive member is also retracted, and the bullet feeding device in the magazine is Fig. 4 shows another embodiment of the invention of the type that is to function.

  FIG. 98 is a schematic structural explanatory view of a 53rd embodiment according to the present invention. Since the structure on the gun side is exactly the same except that the shape and arrangement position of the magazine drive member 807 are different, the overlapping description is omitted. The structure on the magazine side is exactly the same as that in FIG.

  When the magazine driving member 807 is retracted and the passive member 808 is pulled in the direction of the arrow 809, the ratchet 810 rotates in the direction of the arrow 811. FIG. 99 shows this state.

  FIG. 99 is a schematic structural explanatory diagram of a 53rd embodiment according to the present invention. FIG. 99 shows a state in which the rotation driving member 812 is rotated in the direction of the arrow 813 and the cam contact member 814 is most retracted. The magazine driving member 807 is also most retracted in the direction of the arrow 815, and the passive member 808 is pulled down. The ratchet hook 816 that moves integrally with the passive member 808 is also retracted in the direction of the arrow 817, and the ratchet 810 rotates in the direction of the arrow 811. Thereafter, the mechanism in the magazine functions to rotate the sprocket as shown in FIGS. 81 and 82, and the spherical bullet 818 is pushed down to the front of the nozzle member 819.

  Next, another embodiment of the present invention will be described in which the shape of the passive member on the magazine side is changed using the gun engine section having the same structure as the gun engine section described in FIGS.

  FIG. 100 is a schematic structural explanatory view of a 54th embodiment according to the present invention. Since the structure on the magazine side is basically the same as the structure described in FIGS. 94 and 95, the illustration and description of the top view of the magazine viewed from the XY plane are omitted. Since the magazine driving member 821 enters the rear end surface portion of the magazine 820, the magazine 820 has a shape that is cut off by that amount. In the gun engine section, the magazine drive member 821 is in the most retracted state, as in FIG. The passive member 822 is attached to the magazine 820 so that the passive member 822 can rotate about the shaft 823. The spring 824 always pushes the passive member 822, and the passive member 822 is in an initial state. The spherical bullet 825 is in front of the nozzle member 826. Eventually, when the rotation drive member 827 rotates in the direction of the arrow 828, the magazine drive member 821 moves forward in the X-axis direction and gets into the inclined portion of the passive member 822. FIG. 101 shows such a state.

  FIG. 101 is a schematic structural explanatory diagram of a 54th embodiment according to the present invention. In the gun engine section, the magazine drive member 821 is in the most advanced state in the direction of the arrow 829, as in FIG. The arm portion 830 provided integrally with the passive member 822 rotates about the shaft 823 and transmits a driving force in the direction of the arrow 831. The mechanical unit inside the magazine that has received the transmission of the driving force changes from the state shown in FIG. 94 to the state shown in FIG. 95 to obtain a rotational force in a certain direction. The reciprocating motion in the X-axis direction of the magazine drive member 821 is converted into the reciprocating arc motion of the passive member 822, converted again into the reciprocating motion in the X-axis direction inside the magazine, and then converted into a rotational motion in a certain direction. The bullet feeding mechanism functions.

  In the 54th embodiment of FIG. 100, the embodiment of the present invention is shown using the same structure as the 44th embodiment of FIG. 84 as the basic structure of the gun engine section. Next, as a basic structure of the gun engine unit, the shape of the exposed portion of the magazine driving member is exactly the same as that of the 44th embodiment in FIG. 84, and the magazine driving member is connected to the piston. Examples of

  FIG. 102 is a schematic structural explanatory view of a 55th embodiment according to the present invention. The magazine 832 has the same structure as that of the 54th embodiment of FIG. 101 and is in the same state. The state of the magazine drive member 835 protruding from the magazine catch end face part 834 which is a part of the gun main body 833 is exactly the same as that of the embodiment of FIG. There is a difference in where the gun engine part is obtained from, and how much movement is obtained. In all the embodiments from the first embodiment of FIG. 8 to the 54th embodiment of FIG. 101, the driving force of the magazine driving member is obtained from the rotational movement of the rotating driving member. Cams, cam pins, toothless gears, etc. provided on the rotation drive member act on cam contact members, rack gears, etc. provided on the arm members (or cylinders integrated with the arm members), so that the amplitude is about 8 mm. , Creating a reciprocating motion in the X-axis direction. The reciprocating motion in the X-axis direction has been used as it is reciprocating, converted into reciprocating rotational motion, or converted into rotational motion in a certain direction. In the 55th embodiment shown in FIG. 102, the rear end 837 of the piston 836, the connecting member 838, and the magazine driving member 835 are integrated. The rotation driving member 839 rotates in the direction of the arrow 840, and the uneven portion 841 of the rotation drive member 839 does not mesh with the uneven portion 842 of the piston 836. The piston 836 is pushed by the spring 843 and advanced at a high speed, and is in a state of firing a spherical bullet. The magazine drive member 835 integrated with the piston 836 also moves forward in the direction of the arrow 844 at a high speed, moves the passive member 845 so as to kick up instantaneously, and transmits the drive force as shown by the arrow 846. The fact that the magazine bullet feeding mechanism functions by the driving force indicated by the arrow 846 has already been described with reference to FIGS. In the 55th embodiment shown in FIG. 102, the piston 836 is moved by the rotational movement of the rotary drive member. Therefore, it is the same as the previous examples in terms of where the driving force that moves the magazine drive member is obtained from the gun engine part, but in terms of how much movement it is obtained There is a big difference.

  Since the movement amount of the piston is designed to be about 40 mm to 60 mm, the movement amount is 5 times to 7 times or more compared to the movement amount of about 8 mm of the reciprocating motion so far. An example in which the movement amount is directly used as the movement amount of the magazine driving member 835 is the 55th embodiment of FIG.

  In the 55th embodiment of FIG. 102, the rear end portion 837 of the piston 836, the connecting member 838, and the magazine driving member 835 are integrated. For example, in the vicinity of the arrow 847, the rear end portion 837 and the connecting member 838 are integrated. Can also be separated. In that case, a spring for returning the magazine driving member 835 to the initial position as shown in FIG.

  In the 55th embodiment shown in FIG. 102, an engine mechanism similar to that in the first embodiment shown in FIG. 8 is used to move the nozzle member 848 for feeding, but the same engine as in the second embodiment shown in FIG. A part mechanism can also be used. This is like removing the magazine drive member 686 from the engine portion of the 45th embodiment in FIG. The piston and magazine are the same as the piston and magazine shown in FIG.

  In the 55th embodiment shown in FIG. 102, the magazine driving member 835 integrated with the piston 836 is advanced at a high speed in the direction of the arrow 844 and moved so that the passive member 845 is kicked up in an instant. Another embodiment of the present invention in which the magazine drive member is separated is shown.

  FIG. 103 is a schematic structural view of a 56th embodiment according to the present invention. The spring 850 used for advancing the piston 849 is a very strong spring. The piston 849 that moves forward while being pushed by the strong spring eventually collides with the cushion member 851. An example in which such a collision force is used as the driving force of the magazine is the 56th embodiment of FIG. The magazine drive member 852 is surrounded by a guide wall 853 provided on the gun body side and can only reciprocate in the X-axis direction. The magazine driving member 852 is pushed by the spring 854 and the rear end portion is at the position A. The front end portion is inside a magazine catch end surface portion 856 that is a part of the gun body 855. That is, when the gun engine portion is stopped, the front end portion of the magazine drive member 852 is inside the magazine catch end surface portion 856 and is not exposed in a convex shape. Therefore, the front end portion of the magazine driving member 852 does not become an obstacle when the magazine 857 is attached or detached. A window portion 858 for allowing the front end portion of the magazine driving member 852 to enter is provided on the rear end surface portion of the magazine 857.

  The piston 849 deviated from meshing with the rotary drive member 860 rotating in the direction of the arrow 859 is pushed forward by a strong spring and advanced at a high speed. The rear end portion 861 of the piston 849 also advances in the direction of the arrow 862, and eventually collides with the rear end portion of the magazine drive member 852 at the position A. The timing of the collision may be almost the same as the timing when the piston 849 collides with the cushion member 851. FIG. 104 shows a state immediately after the collision.

  FIG. 104 is a schematic structural explanatory view of a 56th embodiment according to the present invention. The piston 849 collides with the cushion member 851 and stops. The rear end portion 861 of the piston 849 also collides with the rear end portion of the magazine driving member 852 and stops at the position A. Then, the magazine drive member 852 that has received the impact force has advanced in the direction of the arrow 863 due to inertia. The spring 854 is contracted. The rear end portion of the magazine drive member 852 advances to the position B and stops. The front end portion of the magazine drive member 852 transmits a force in the direction of the arrow 864 through the window portion 858 and moves a passive member (not shown) inside the magazine 857. As the internal mechanism of the magazine 857, a mechanism as shown in the 44th embodiment of FIG. 84 or the 54th embodiment of FIG. 100 can be used. It is free to adopt a method of transmitting a linear motion as it is, or a method of transmitting a linear motion by converting it into a rotational motion. In order to increase the inertia, a bulking member 865 may be added. The magazine drive member 852 that has finished transmitting force to the passive member is retracted instantaneously by the action of the spring 854.

  A method of making the magazine drive member jump out for a moment using inertia is already shown in FIG. 77. In the forty-third embodiment, a system is adopted in which linear motion is converted into rotational motion and transmitted.

  In FIGS. 102, 103, and 104, the magazine driving member is operated using the movement when the piston moves forward. Next, the magazine driving member is moved using the movement when the piston moves backward. Another embodiment of the present invention in which the system is operated will be described.

  FIG. 105 is a schematic structural view of a 57th embodiment according to the present invention. The structure of the engine part on the gun body side is basically the same as the structure shown in FIG. It can be considered that the magazine driving member 686 is removed from the structure shown in FIG. A convex portion 867 </ b> A is provided on the rear upper portion of the piston 866. The rotation drive member 868 rotates in the direction of the arrow 869, and the bullet feeding nozzle member 870 moves forward in the direction of the arrow 871 to push the spherical bullet 872 into the barrel packing 873. The piston 866 is retracted in the direction of the arrow 874A, and is just before the convex portion 867A contacts the rear end portion 876 of the magazine drive member 875. The magazine driving member 875 is pressed by the spring 877, and the stopper 878 is in contact with the inner wall of the gun body 879, and is in the state shown in the figure. This state is the initial state of the magazine drive member 875. A passive member 881 is disposed inside the magazine 880. The passive member 881 is supported by the shaft 883 of the passive member base 882 and pressed by the spring 884. With such a configuration, the passive member 881 is provided with an escape mechanism. Because of the escape mechanism, the magazine 880 can be attached and detached at any time even when the front end hook portion 885 of the magazine driving member 875 is stopped at a position other than the initial state. A long hole 887 is provided above the cylinder 886. The convex portion 867 provided at the upper rear portion of the piston 866 moves within the range of the elongated hole 887. Note that the magazine drive member 875 can be changed to a shape as shown in the figure below so that it becomes a magazine drive member 888. The rear end portion 889 of the magazine drive member 888 is pushed by the convex portion 867B provided at the upper front portion of the piston 866. Since the convex portion 867B does not jump out of the cylinder 886, it is convenient to handle it when assembled as a cylinder unit. Regarding the cylinder and piston in the partial view shown below, the position in the X-axis direction is drawn in the same manner as the position shown in the upper drawing. The shape of the magazine drive member 875 and the shape of the magazine drive member 888 are the same in function. When the rotation driving member 868 further rotates in the direction of the arrow 869, the piston 866 is in the most retracted state. FIG. 106 shows this state.

  FIG. 106 is a schematic structural explanatory view of a 57th embodiment according to the present invention. Piston 866 is in the most retracted state in the direction of arrow 874A. The convex portion 867A most retracts the rear end portion 876 of the magazine driving member 875 in the direction of the arrow 874B. The tip hook portion 885 of the magazine driving member 875 pulls the passive member 881 in the direction of the arrow 874C, and the passive member base 882 is also in the most retracted state. If a member such as the passive member base 882 reciprocates in the X-axis direction inside the magazine 880, it is easy to make the bullet feeding mechanism function using that movement. 84. A structure similar to that shown in the forty-fourth embodiment may be adopted. Alternatively, a structure similar to that shown in FIG. 90, the 47th embodiment or FIG. 92, the 49th embodiment may be adopted. Also, a structure similar to that shown in FIG. However, in that case, it is necessary to convert the movement in which the magazine driving member 875 is pulled backward into the movement of pushing forward in the gun. Alternatively, if it is desired to use the pulling movement as it is, the arrangement method of the sector gear 745 and the parallel movement member 748 shown in the 50th embodiment of FIG. 93 is shown in the 49th embodiment of FIG. What is necessary is just to change like the arrangement | positioning method of the sector gear 741 and the parallel displacement member 739. In that case, by recognizing a part of the magazine drive member 875 as a parallel movement member, it is possible to output a reciprocating rotational motion as shown in the 50th embodiment of FIG. It has already been described that the magazine driving member 875 can be changed to a shape as shown in the figure below so as to be a magazine driving member 888. Regarding the cylinder and piston in the partial view shown below, the position in the X-axis direction is drawn in the same manner as the position shown in the upper drawing.

  105 and 106 In the 57th embodiment, the method of pulling the passive member having a hook shape in the X-axis direction when the piston is retracted has been described. Next, changes such as providing a convex portion on the piston are made. In addition, the present invention is of a type in which the slot provided in the upper part of the cylinder is also made smaller and the passive member is flipped up in the Z-axis direction by tilting the tip of the magazine drive member to function the bullet feeding device in the magazine. Another embodiment is shown.

  FIG. 107 is a schematic structural explanatory view of a 58th embodiment according to the present invention. The magazine 890 is exactly the same as the magazine used in the embodiment of FIG. As described above, when the magazine driving member is retracted, the passive member is flipped up in the Z-axis direction to be in a state as shown in FIG. 95 and the bullet feeding mechanism functions.

  A long hole 892 is provided above the cylinder 891. The magazine drive member 893 has an inclined portion and faces the inclined portion of the passive member 894. The rear lower end portion of the magazine driving member 893 hits the rear upper end portion of the piston 895 and is in a state of being pushed. A rear upper end portion of the magazine driving member 893 is pressed by a spring 896. A stopper 897 provided near the front of the magazine drive member 893 is in contact with the inner wall of the gun body 898 and is in the state shown in the figure. This state is the initial state of the magazine drive member 893. The rotation driving member 899 rotates in the direction of the arrow 900, and the bullet feeding nozzle member 901 advances in the direction of the arrow 902 to push the spherical bullet 903 into the barrel packing 904. Piston 895 is retracted in the direction of arrow 905.

  Since the rear upper end of the piston 895 does not have a convex portion as shown in FIG. 57, the long hole 892 above the cylinder 891 can be small. Note that in the 58th embodiment of FIG. 107, the central axis of the bullet feeding nozzle member 901 and the central axis of the cylinder 891 do not coincide. In a so-called offset state. This is because the overall shape of the magazine drive member 893 has changed. Functionally, it is the same as the engine unit as shown in FIG.

  FIG. 108 is a schematic structural explanatory view of a 58th embodiment according to the present invention. Piston 895 is in the most retracted state in the direction of arrow 905. The magazine drive member 893 is also in the most retracted state in the direction of the arrow 906. The inclined portion of the magazine driving member 893 acts on the inclined portion of the passive member 894 to rotate the passive member 894 about the shaft 907 and transmit force in the direction of the arrow 908. This state is the same as the state of the magazine shown in FIG. It has already been described that the bullet feeding mechanism functions when a force is transmitted in the direction of the arrow 908. Since the passive member 894 rotates about the shaft 907, the magazine 890 can be attached and detached at any time. This has already been explained.

  In the 57th embodiment and the 58th embodiment, the method of moving the passive member when the piston is retracted has been described. Next, without changing the piston or the like, a long portion is provided above the cylinder. Another embodiment of the present invention of a type in which the bullet feeding device in the magazine is made to function by adding a device near the cylinder head without providing a hole will be described.

  FIG. 109 is a schematic structural explanatory view of a 59th embodiment according to the present invention. This is a system in which the magazine feed member is caused to reciprocate in the X-axis direction by using the piston crash and the spring repulsion, and the force is transmitted to the passive member on the magazine side so that the magazine bullet feed mechanism functions. This method is similar to the method shown in FIG. 56 in Example 56 in that it uses the collision of the piston, but there is no extra force transmission mechanism disposed above the piston. As a system, the system is very small and easy to assemble.

  A cylinder head 910 is fitted in front of the cylinder 909. The cylinder 909 is fixed to the gun body 911 and does not move. An exhaust pipe 912 passes through a first hole provided in the cylinder head 910. A packing 914 is set on the outer periphery of the exhaust pipe base 913 to prevent air leakage. The magazine drive member 915 is attached to the exhaust pipe base 913 through a second hole provided in the cylinder head 910. The magazine drive member 915 is in the most retracted position when pushed by the spring 916. The state shown in the figure is the initial state of the magazine drive member 915. The piston 917 is disengaged from the engagement with the rotary drive member 918 and is advanced at high speed in the direction of the arrow 919. Since the arm member 920 is not affected by the cam pin 921, the arm member 920 is pulled in the direction of the arrow 923 by the spring 922. The bullet feeding nozzle member 924 also moves integrally with the arm member 920 and is at the most advanced position. The spherical bullet 926 that has been caught in the barrel packing 925 is fired in the direction of the arrow 927. When the rotary drive member 918 further rotates in the direction of the arrow 928 after the piston 917 completes the forward movement, the cam contact member 929 is pushed by the cam pin 921 and moves backward. At the same time, the bullet feeding nozzle member 924 moves rearward, and the next spherical bullet 930 is fed into the rear portion of the barrel packing 925.

  The description on the gun body 911 side is as described above. Next, since the magazine is shown in a view of the XY plane, its basic structure will be described. A passive member 932 is disposed in the magazine 931 and is about to receive movement from the magazine driving member 915. The passive member 932 is supported by the passive member base 933, and has a structure that temporarily escapes when it comes into contact with the upper end of the magazine drive member 915 when the magazine is set. This structure of the passive member escape has already been described many times. The passive member base 933 is supported by the shaft 934 and can rotate. The arm portion 935 of the passive member base portion 933 has elasticity, and when the tip hook portion 936 returns after feeding one ratchet 937, it escapes with its own elasticity and does not reverse the ratchet 937. A spring 938 for preventing reverse rotation is disposed on the ratchet 937. The passive member base 933 is provided with a spring 939 but has a stopper 940 so that it is in the state shown in the figure. This state is the initial state of the magazine 931.

  109. The basic structure of the magazine 931 of the 59th embodiment is similar to the basic structure of the magazine 202 of the sixth embodiment in FIG. The linear movement of the magazine drive member in the X-axis direction is converted into the circular movement of the passive member, and the tip hook that moves integrally with the passive member rotates the ratchet by only one tooth (or only two teeth). It is a structure to let you. The ratchet shaft is provided with a spring spring for livestock power, and the outer end of the spring spring fits into a recess provided on the inner wall of the sprocket to transmit power while having a relief clutch function.

  FIG. 110 is a schematic structural explanatory diagram of a 59th embodiment according to the present invention. The piston 917 has completed the forward movement. The exhaust pipe base 913 and the magazine drive member 915 are pushed by the piston 917 and advanced in the direction of the arrow 941. The magazine is shown in a view of the XY plane. Inside the magazine 931, the magazine drive member 915 pushes the passive member 932. The passive member base 933 supporting the passive member 932 rotates about the shaft 934 in the direction of the arrow 942. The state where the tip hook portion 936 near the tip of the arm portion 935 has sent the ratchet 937 by one tooth in the direction of the arrow 943 is depicted. The magazine drive member 915 can be inserted from the front of the cylinder head 910 even after the cylinder unit is completed. This is very convenient in the assembly process.

  Since the magazine driving member 915 is pushed by the spring 916, when the rotation driving member 918 further rotates in the direction of the arrow 928, the magazine driving member 915 is located on the uneven portion below the piston 917 and on the outer periphery of the rotation driving member 918. The projections and depressions engage with each other again to move the piston 917 backward. Since the influence of the piston 917 that has pressed the exhaust pipe base 913 forward is lost, the magazine drive member 915 is pushed by the spring 916 and returns to the initial state as shown in FIG. The internal mechanism of the magazine 931 also returns to the initial state as shown in FIG. Such a cycle is repeated so that spherical bullets are continuously fired and fired continuously.

  109 and 110, in the 59th embodiment, the special system in which the exhaust pipe 912 and the magazine driving member 915 move simultaneously has been described. Next, without arranging the exhaust pipe base 913, the exhaust pipe, the cylinder head, Another embodiment of the present invention is shown in which the magazine is fixed to the cylinder and only the magazine driving member is moved by the advance of the piston so that the bullet feeding device in the magazine functions.

  FIG. 111 is a schematic structural explanatory diagram of a 60th embodiment according to the present invention. The exhaust pipe 944 and the cylinder head 945 are integrated. The cylinder head 945 is fitted in front of the cylinder 946. The cylinder 946 is fixed to the gun body 947 and does not move. The rear end 949 of the magazine drive member 948 protrudes through the hole provided in the cylinder head 945 toward the inside of the cylinder 946. A packing 956 is disposed between the magazine drive member 948 and the cylinder head 945 to prevent air in the cylinder from leaking. 109. The shape of the magazine drive member 915 in the 59th embodiment is exactly the same as the shape of the magazine drive member 948 in the 60th embodiment of FIG. And the arrangement position is also exactly the same.

  The structure of the magazine 950 in the 60th embodiment shown in FIG. 111 is exactly the same as the structure of the magazine 931 in the 59th embodiment shown in FIG. The piston 951 advances at a high speed in the direction of the arrow 952, and eventually collides with the rear end portion 949 of the magazine drive member 948. Then, the magazine driving member 948 moves forward in the direction of the arrow 953 and pushes the passive member 954. The mechanism in the magazine functions as shown in the diagram of the magazine in FIG. The cushion member 955 absorbs the collision force of the piston 951 so that the cylinder head 945 is not destroyed. The magazine driving member 948 can be inserted from the front of the cylinder head 945 even after the cylinder unit is completed. This is very convenient in the assembly process.

Although in such FIG embodiment was flying a toy gun motorized example, gun according to the invention, since actuates the magazine drive member by transferring the movement of the components inside the gun, the toy gun it may be a toy gun gas formula of the old type of gas blow-back type. Many gas- type toy guns take a system in which a gas valve is opened when a trigger is pulled, and gas flows into a fixed cylindrical space. A piston-like member is disposed in the cylindrical space, and when the gas pressure increases, the piston-like member moves by a certain amount. Or, conversely, there is a gas type toy gun in which the cylindrical member moves by a fixed amount outside the fixed piston-like member. Then, when the piston-like member or the cylinder-like member moves by a certain amount, a mechanism for discharging the gas works, and the piston-like member or the cylinder-like member returns to the initial position. By repeating such a cycle, continuous shooting is possible. In gas- type toy guns, a fixed amount of reciprocating motion can be obtained by connecting a magazine drive member to such a moving piston-like member or a moving cylinder-like member. By incorporating a system that converts reciprocating motion into rotational motion, the continuous bullet feeding mechanism on the magazine side can be made to function. Magazine according to the present invention, as long as the position and shape of the gun side of the magazine drive member is designed in the same, in a toy gun Gas in toy gun motorized, also use the same magazines for both And you can enjoy continuous shooting.

It is the figure which copied the gazette of the conventional invention and corrected numbers. It is the figure which copied the gazette of the conventional invention and corrected numbers. It is the figure which copied the gazette of the conventional invention and corrected numbers. It is the figure which copied the gazette of the conventional invention and corrected numbers. It is the figure which copied the gazette of the conventional invention and corrected numbers. It is the figure which copied the gazette of the conventional invention and corrected numbers. It is the figure which copied the gazette of the conventional invention and corrected numbers. It is a schematic structure explanatory drawing of 1st Example by this invention. (1/3) It is a schematic structure explanatory drawing of 1st Example by this invention. (2/3) It is a schematic structure explanatory drawing of 1st Example by this invention. (3/3) It is a schematic structure explanatory drawing of the 2nd Example by this invention. (1/4) It is a schematic structure explanatory drawing of the 2nd Example by this invention. (2/4) It is a schematic structure explanatory drawing of the 2nd Example by this invention. (3/4) It is a schematic structure explanatory drawing of the 2nd Example by this invention. (4/4) It is structure explanatory drawing of a general magazine stopper. (1/2) It is structure explanatory drawing of a general magazine stopper. (2/2) It is structure explanatory drawing of a general spring type magazine. (1/2) It is structure explanatory drawing of a general spring type magazine. (2/2) It is structure explanatory drawing of the magazine which employ | adopted this invention. (1/1) It is a schematic structure explanatory drawing of the 3rd Example by this invention. (1/3) It is a schematic structure explanatory drawing of the 3rd Example by this invention. (2/3) It is a magazine external view of the 3rd example by the present invention. (3/3) It is a schematic structure explanatory drawing of the 4th Example by this invention. (1/3) It is a schematic structure explanatory drawing of the 4th Example by this invention. (2/3) It is a magazine external view of the 4th example by the present invention. (3/3) It is a schematic structure explanatory drawing of the 5th Example by this invention. (1/2) It is a schematic structure explanatory drawing of the 5th Example by this invention. (2/2) It is a schematic structure explanatory drawing of the 6th Example by this invention. (1/2) It is a schematic structure explanatory drawing of the 6th Example by this invention. (2/2) It is a schematic structure explanatory drawing of the 7th Example by this invention. (1/2) It is a schematic structure explanatory drawing of the 7th Example by this invention. (2/2) It is a schematic structure explanatory drawing of the 8th Example by this invention. (1/1) It is a schematic structure explanatory drawing of the 9th Example by this invention. (1/2) It is a schematic structure explanatory drawing of the 9th Example by this invention. (2/2) It is a schematic structure explanatory drawing of the 10th Example by this invention. (1/2) It is a schematic structure explanatory drawing of the 10th Example by this invention. (2/2) It is a schematic structure explanatory drawing of the 11th Example by this invention. (1/3) It is a schematic structure explanatory drawing of the 11th Example by this invention. (2/3) It is a magazine external view of the 11th Example by this invention. (3/3) It is a schematic structure explanatory drawing of the 12th Example by this invention. (1/1) It is a schematic structure explanatory drawing of the 13th Example by this invention. (1/1) It is a schematic structure explanatory drawing of the 14th Example by this invention. (1/4) It is a schematic structure explanatory drawing of the 14th Example by this invention. (2/4) It is a magazine external view of the 14th Example by this invention. (3/4) It is a schematic structure explanatory drawing of the 14th Example by this invention. (4/4) It is a schematic structure explanatory drawing of the 15th Example by this invention. (1/1) It is a schematic structure explanatory drawing of the 16th Example by this invention. (1/1) It is a schematic structure explanatory drawing of the 17th Example by this invention. (1/1) It is a schematic structure explanatory drawing of the 18th Example by this invention. (1/2) It is a schematic structure explanatory drawing of the 18th Example by this invention. (2/2) It is a schematic structure explanatory drawing of the 19th Example by this invention. (1/1) It is a schematic structure explanatory drawing of the 20th Example by this invention. (1/1) It is a schematic structure explanatory drawing of the 21st Example by this invention. (1/1) It is a schematic structure explanatory drawing of the 22nd Example by this invention. (1/1) It is a schematic structure explanatory drawing of the 23rd Example by this invention. (1/1) It is a schematic structure explanatory drawing of the 24th Example by this invention. (1/1) It is a schematic structure explanatory drawing of the 25th Example by this invention. (1/2) It is a partial explanatory view of the 25th example by the present invention. (2/2) It is a partial explanatory view of the 26th example by the present invention. (1/2) It is a partial explanatory view of the 26th example by the present invention. (2/2) It is a partial explanatory view of the 27th example by the present invention. (1/1) It is a partial explanatory view of the 28th embodiment according to the present invention. (1/1) It is a schematic structure explanatory drawing of the 29th Example by this invention. (1/1) It is a schematic structure explanatory drawing of the 30th Example by this invention. (1/1) It is a schematic structure explanatory drawing of the 31st Example by this invention. (1/1) It is a schematic structure explanatory drawing of the 32nd Example by this invention. (1/1) It is a schematic structure explanatory drawing of the 33rd Example by this invention. (1/1) It is a schematic structure explanatory drawing of the 34th Example by this invention. (1/1) It is a schematic structure explanatory drawing of the 35th Example by this invention. (1/1) It is a schematic structure explanatory drawing of the 36th Example by this invention. (1/1) It is a schematic structure explanatory drawing of the 37th Example by this invention. (1/1) It is a schematic structure explanatory drawing of the 38th Example by this invention. (1/1) It is a schematic structure explanatory drawing of the 39th Example by this invention. (1/1) It is a schematic structure explanatory drawing of the 40th Example by this invention. (1/1) It is a schematic structure explanatory drawing of the 41st Example by this invention. (1/1) It is a schematic structure explanatory drawing of the 42nd Example by this invention. (1/1) It is a schematic structure explanatory drawing of the 43rd Example by this invention. (1/3) It is a schematic structure explanatory drawing of the 43rd Example by this invention. (2/3) It is a schematic structure explanatory drawing of the 43rd Example by this invention. (3/3) It is a schematic structure explanatory drawing of the 44th Example by this invention. (1/7) It is a schematic structure explanatory drawing of the 44th Example by this invention. (2/7) It is a schematic structure explanatory drawing of the 44th Example by this invention. (3/7) It is a schematic structure explanatory drawing of the 44th Example by this invention. (4/7) It is a schematic structure explanatory drawing of the 44th Example by this invention. (5/7) It is a schematic structure explanatory drawing of the 44th Example by this invention. (6/7) It is a schematic structure explanatory drawing of the 44th Example by this invention. (7/7) It is a schematic structure explanatory drawing of the 45th Example by this invention. (1/2) It is a schematic structure explanatory drawing of the 45th Example by this invention. (2/2) It is a schematic structure explanatory drawing of the 46th Example by this invention. (1/1) It is a schematic structure explanatory drawing of the 47th Example by this invention. (1/1) It is a schematic structure explanatory drawing of the 48th Example by this invention. (1/1) It is a schematic structure explanatory drawing of the 49th Example by this invention. (1/1) It is a schematic structure explanatory drawing of the 50th Example by this invention. (1/1) It is a schematic structure explanatory drawing of the 51st Example by this invention. (1/2) It is a schematic structure explanatory drawing of the 51st Example by this invention. (2/2) It is a schematic structure explanatory drawing of the 52nd Example by this invention. (1/2) It is a schematic structure explanatory drawing of the 52nd Example by this invention. (2/2) It is a schematic structure explanatory drawing of the 53rd Example by this invention. (1/2) It is a schematic structure explanatory drawing of the 53rd Example by this invention. (2/2) It is a schematic structure explanatory drawing of the 54th Example by this invention. (1/2) It is a schematic structure explanatory drawing of the 54th Example by this invention. (2/2) It is a schematic structure explanatory drawing of the 55th Example by this invention. (1/1) It is a schematic structure explanatory drawing of the 56th Example by this invention. (1/2) It is a schematic structure explanatory drawing of the 56th Example by this invention. (2/2) It is a schematic structure explanatory drawing of the 57th Example by this invention. (1/2) It is a schematic structure explanatory drawing of the 57th Example by this invention. (2/2) It is a schematic structure explanatory drawing of the 58th Example by this invention. (1/2) It is a schematic structure explanatory drawing of the 58th Example by this invention. (2/2) It is a schematic structure explanatory drawing of the 59th Example by this invention. (1/2) It is a schematic structure explanatory drawing of the 59th Example by this invention. (2/2) It is a schematic structure explanatory drawing of the 60th Example by this invention. (1/1)

Explanation of symbols

Concavity and convexity 1, 6, 78, 79, 841, 842
Convex parts 56, 113, 187, 221, 222, 245, 249, 867A, 867B
Recesses 16, 62... Protrusions 48, 109
Piston 2, 74, 145, 165, 186, 785, 836, 849, 866, 895, 917, 951
Spring 3, 12, 75, 84, 182
Cylinder 5, 77, 189, 649, 788, 886, 891, 909, 946
Cylinder head 20, 190, 789, 910, 945
Packing 4, 18, 73, 76, 914, 956
Barrel packing 52, 683, 873, 904, 925
Motors 8, 81 ... gearbox 10 ... barrel 53
Nozzle members 19, 167, 191, 682, 790, 819, 826, 848
Nozzle units 15, 166, 652
Upper frame 21 ... lower frame 22 ... fixing base 23
Rotation drive member 7, 80, 147, 162, 197, 229, 242, 267, 310, 325, 337, 357, 372, 409, 459, 495, 515, 526, 552, 601, 654, 703, 779, 802 , 812, 827, 839, 860, 868, 899, 918
Magazine drive member 26, 89, 135, 161, 181, 192, 214, 224, 241, 251, 257, 274, 300, 308, 315, 335, 355, 370, 394, 407, 415, 419, 426, 438 445, 453, 464, 487, 497, 508, 521, 557, 561, 564, 568, 573, 648, 686, 776, 791, 807, 821, 835, 852, 875, 888, 893, 915, 948
Passive members 28, 91, 137, 168, 180, 200, 213, 217, 226, 239, 247, 258, 273, 275, 287, 297, 307, 313, 316, 336, 356, 371, 395, 408, 416, 420, 433, 439, 446, 452, 471, 489, 499, 509, 528, 558, 562, 566, 569, 598, 660, 691, 696, 712, 722, 731, 739, 770, 795, 808, 822, 830, 845, 881, 894, 932, 954
Passive member base 29, 92, 259, 276, 317, 454, 469, 472, 483, 501, 548, 663, 767, 882, 933
Cam contact member 13, 85, 134B, 164, 183, 194, 236, 657, 793, 814, 929
Arm members 87, 134A, 193, 220, 253, 302, 309, 359, 374, 411, 421, 429, 440, 447, 467, 511, 574, 650, 688, 792, 920
Magazine 27, 90, 136, 202, 255, 284, 332, 396, 417, 596, 620, 623, 644, 647, 694, 705, 709, 753, 753A, 753B, 797, 820, 832, 857, 880 , 890, 931, 950
Cam portion 11, 163, 184, 603, 656
Engagement projections 17, 71, 651, 653
Rail part 31, 94, 248, 260, 261, 456, 664
Crank 35, 98, 250, 299 ... Rack 46
Ratchet push bar 34, 97, 142, 203, 296
Driving ratchet 36, 99, 131, 154, 176, 210, 215
Stop ratchet 44
Arrows 9, 14, 33, 38, 41, 45, 50, 54, 55, 57, 58, 58b, 64, 65, 66, 67, 82, 86, 96, 101, 104, 108, 111, 114, 115 116, 119, 122, 125, 126, 128, 129, 130, 132, 141, 148, 151, 152, 153, 160, 169, 170, 171, 175, 177, 179, 185, 206, 208, 209 211,216,228,230,231,232,233,238,243,246,256A, 256B, 263,265,268,271,280,282,283,285,286,290,292,305,306 311, 312, 326, 327, 328, 330, 333, 334, 338, 346, 347, 348, 50, 358, 362, 363, 365, 373, 391, 397, 410, 418, 423, 424, 431, 432, 434, 435, 436, 437, 443, 444, 450, 451, 460, 461, 462, 463, 478, 479, 482, 488, 490, 492, 496, 498, 500, 516, 517, 518, 527, 540, 547, 586, 588, 597, 602, 604, 605, 606, 607, 609, 610, 611, 612, 615, 617, 622, 624, 625, 627, 629, 630, 631, 634, 635, 642, 646, 655, 659, 667, 672, 674, 680, 681, 684, 685, 690, 697, 698, 700, 702, 706, 710, 711, 7 8, 719, 720, 721, 725, 726, 727, 729, 735, 736, 738, 740, 742, 744, 749, 752, 756, 758, 760, 762, 772, 773, 775, 778, 780, 781, 800, 803, 804, 805, 809, 811, 813, 815, 817, 828, 829, 831, 840, 844, 846, 847, 859, 862, 863, 864, 869, 871, 874A, 874B, 874C, 891, 892, 900, 902, 905, 906, 908, 919, 923, 927, 928, 941, 942, 943, 952, 953
Spring 32, 37, 39, 40, 43, 72, 95, 100, 102, 103, 107, 110, 121, 133, 140, 144, 195, 205, 227, 237, 252, 262, 270, 277, 279 289, 295, 298, 314, 319, 322, 324, 393, 442, 449, 455, 550, 578, 585, 587, 618, 632, 641, 658, 662, 666, 671, 675, 679, 689 693, 695, 763, 765, 774, 794, 799, 824, 843, 850, 854, 877, 884, 896, 916, 922, 938, 939
Pins 24, 25, 428, 484, 583, 584, 591, 734
Axis 30, 93, 201, 204, 223, 240, 269, 278, 288, 301, 318, 321, 323, 339, 344, 427, 491, 576, 592, 600, 661, 670, 678, 692, 768 796, 823, 883, 907, 934
Stopper 42, 49, 106, 120, 188, 196, 281, 291, 579, 581, 608, 787, 878, 897, 940
Gun body 619, 643, 707, 754, 833, 855, 879, 898, 911, 947
Spherical bullet 51, 69, 112, 118, 157, 158, 159, 207, 621, 645, 782, 784, 801, 806, 818, 825, 872, 903, 926, 930
Cushion members 70, 851, 955
Cam pins 83, 149, 198, 514, 525, 921
Bullet feeding nozzle member 88, 146, 687, 777, 870, 901, 924
Sprocket 59, 117, 178, 212, 364, 481, 636
Spring springs 60, 384, 638,... Spring spring shaft member 383
Slots 430, 486, 589, 732, 887, 892
Central shaft 63, 639, 717, 730, 750
Shafts 414, 520, 530, 539, 560
Ratchet 266, 329, 616, 640, 673, 701, 757, 761, 810, 937
Ratchet hooks 264, 320, 614, 669, 677, 699, 755, 759, 816
Ratchet hook base 668, 676, 764, 766
Ratchet arm 343, 380, 476, 716, 751
Ratchet push bar base 105
Shaft 354, 369, 379, 382, 386, 403, 414, 539, 542, 544, 556
Pulleys 340, 342, 402, 505, 507, 567
Belt 341, 401, 506, 572
Arm part 293, 473, 502, 771, 798, 935
Guide members 138, 139, 173, 174
Rack gear 360, 375, 412, 457, 470, 474, 493, 713, 723
Pinion gears 366, 392, 405, 504, 546
Pinion spur gears 351, 361, 563, 565
Spur gear 47, 345, 349, 458, 475, 480, 551, 553, 714, 715, 724, 728, 737, 743, 746, 747
Second spur gear 399
Bevel gears 352, 353, 367, 368, 378, 543, 545, 555
Pinion Bevel Gear 554
Spur gear 570 with pulley bevel gear 571 with pulley
Intermediate gears 413, 477... Missing gear 494
Fan-shaped rack gears 485, 503... Fan-shaped gears 733, 741, 745
Tip portions 124, 594, 704
Rear end portion 593, 837, 861, 876, 889, 949
End 244 ... Upper end 304 ... End face 595 ... Outer end 61
Lower end surface 626, 708 ... rear end surface 628
A guide groove 143... B guide groove 172... Guide groove 665
Cam members 510, 523 ... Cam pin base members 512, 522
Cam grooves 513, 524
Exhaust pipes 912, 944... Exhaust pipe base 913
Animal power mechanism 400, 519, 529, 536, 559
One-way clutch mechanism 398, 425, 535
Rib 199 ... Rotating body 225 ...
Pipe portion 123 ... discharge ports 422, 441, 448, 637
Biting prevention member 127... Parallel movement members 294 and 748
Support members 575, 769 ... intermediate member 613 ... connecting member 838
Screw 404 ... Vertical screw 538 ... Horizontal screw 541
Screw pin base members 531, 549... Push plate 633
Screw member 532 ... Screw groove 533 ... Screw pin 534
Hook member 577 ... hook rear end 303 ... tip hook 885, 936
Propeller 387 ... Separation claw 388 ... Conveyance path 389, 406
Space part 155, 156 ... support part 235 ... retaining part 254, 468
Reference center line 234... Passive member bodies 272, 331.
Arm 218, 219 ... Lid 537 ... Piston end 786
Coupling 381, 385 ... Release knob 390
Inclined part 580... Window part 599, 858.
Direction changing member 590 ... positioning member 783 ... increasing member 865
Magazine catch end face part 834, 856 ... guide wall 853
Magazine body 1001... Storage unit 1002... Sprocket 1003... Guide wall 1004... Stopper member 1005. ··· Stopper member 1010 ··· Arm member 1011 · · · Tip portion 1012 · · · Rotary member 1013 · · · Sensor member 1014 · · · Switch 1015 · · · magazine body 1016 · · · storage portion 1017 · · · cup Ring 1018 ... Screw conveyor 1019 ... Motor 1020

Claims (14)

Functions by the passive member that makes contact with the magazine drive member placed on the toy gun with continuous firing function and passively drives the magazine drive output, and the passive member that makes the magazine drive output transmitted from the magazine drive member passive In a toy gun magazine having a bullet feeding device for continuously sending out spherical bullets , a livestock device is provided between the passive member arranged in the magazine and the bullet feeding device, and A surplus drive force that is transmitted beyond the consumption of actual ammunition is provided by a clutch mechanism that works when it reaches the point of the power is consumed by the clutch mechanism, the magazine toy gun, which comprises replenishing the spherical space bullets conveying path generated by Okutama mistake Okutama device instantaneously by animal power opening of the animal power device Functions by the passive member that makes contact with the magazine drive member placed on the toy gun with continuous firing function and passively drives the magazine drive output, and the passive member that makes the magazine drive output transmitted from the magazine drive member passive In a toy gun magazine having a bullet feeding device for continuously sending out spherical bullets , a rack gear is provided on a member that receives a driving force from a magazine driving member and reciprocates in the magazine, and the rack gear. to engage in, by placing the spur gear having a plurality of projections, by reciprocating rotational motion spur gear, by contacting the projection to the spherical bullets, characterized in that to eliminate the bridge phenomenon of the spherical bullets that occur in the magazine A magazine for toy guns. Functions by the passive member that makes contact with the magazine drive member placed on the toy gun with continuous firing function and passively drives the magazine drive output, and the passive member that makes the magazine drive output transmitted from the magazine drive member passive In a toy gun magazine equipped with a bullet feeding device that continuously sends out spherical bullets , a plurality of protrusions are provided on a member that reciprocates in the magazine in response to transmission of driving force from the magazine driving member, A magazine for a toy gun , characterized in that a bridging phenomenon of a spherical bullet generated in the magazine is eliminated by bringing a protrusion into contact with the spherical bullet . Functions by the passive member that makes contact with the magazine drive member placed on the toy gun with continuous firing function and passively drives the magazine drive output, and the passive member that makes the magazine drive output transmitted from the magazine drive member passive In a magazine for toy guns equipped with a bullet feeding device that continuously sends out spherical bullets, depending on the switching mode of shooting modes such as semi-auto and full-auto, or due to the difference in timing to stop firing by releasing your finger from the trigger, A magazine that can be used for a toy gun whose stop position of the magazine drive member is not necessarily constant, and the stop position of the magazine drive member arranged on the gun side is the initial engagement position of the passive member arranged on the magazine side If the magazine is installed when it is off the The passive member has a mechanism for temporarily retracting, and when the continuous firing starts again, the passive member returns to the initial setting position so that the magazine driving member and the passive member normally engage with each other at the initial setting position. A toy gun magazine comprising a return mechanism . Functions by the passive member that makes contact with the magazine drive member placed on the toy gun with continuous firing function and passively drives the magazine drive output, and the passive member that makes the magazine drive output transmitted from the magazine drive member passive In a magazine for toy guns equipped with a bullet feeding device that continuously sends out spherical bullets, depending on the switching mode of shooting modes such as semi-auto and full-auto, or due to the difference in timing to stop firing by releasing your finger from the trigger, A magazine that can be used for a toy gun whose stop position of the magazine drive member is not necessarily constant, and the stop position of the magazine drive member arranged on the gun side is the initial engagement position of the passive member arranged on the magazine side If the magazine is to be mounted when it is off the center, the inclined part of the passive member By jostling and the magazine drive member, receiving member had a pressed move mechanism, toy gun magazine receiving member is characterized by having an inclined shape portion. Functions by the passive member that makes contact with the magazine drive member placed on the toy gun with continuous firing function and passively drives the magazine drive output, and the passive member that makes the magazine drive output transmitted from the magazine drive member passive In a magazine for toy guns equipped with a bullet feeding device that continuously sends out spherical bullets, depending on the switching mode of shooting modes such as semi-auto and full-auto, or due to the difference in timing to stop firing by releasing your finger from the trigger, A magazine that can be used for a toy gun whose stop position of the magazine drive member is not necessarily constant, and the stop position of the magazine drive member arranged on the gun side is the initial engagement position of the passive member arranged on the magazine side If the magazine is to be mounted when it is off the By rotating in contact with the inclined shape portion having Jin driving member, driven member having a pressed move mechanism, toy gun magazine receiving member is characterized in that it is a rotating body. Functions by the passive member that makes contact with the magazine drive member placed on the toy gun with continuous firing function and passively drives the magazine drive output, and the passive member that makes the magazine drive output transmitted from the magazine drive member passive In a toy gun magazine comprising a bullet feeding device for continuously sending out spherical bullets, a passive member exposed in a convex shape from the side of the magazine (a surface perpendicular to the surface on which the spherical bullet discharge port is arranged) is provided. When the magazine is to be attached or detached, a magazine driving member is provided with a mechanism in which the exposed convex portion of the passive member hits the magazine introduction wall provided on the gun side and temporarily retracts into the magazine. A toy gun magazine characterized in that it can be used without any problem for a toy gun whose stop position is not always constant . Functions by the passive member that makes contact with the magazine drive member placed on the toy gun with continuous firing function and passively drives the magazine drive output, and the passive member that makes the magazine drive output transmitted from the magazine drive member passive A magazine for toy guns equipped with a bullet feeding device for continuously sending out spherical bullets, and a propeller and a claw for separating spherical bullets inside a cylindrical container provided with a spherical bullet outlet at the lower side. The bullet feeding device with the structure is placed in the magazine, and between the rotating shaft that rotates by the rotary motion transmitted from the passive member and the rotating shaft of the bullet feeding device, A toy gun magazine characterized by a clutch mechanism that works when it arrives . Functions by the passive member that makes contact with the magazine drive member placed on the toy gun with continuous firing function and passively drives the magazine drive output, and the passive member that makes the magazine drive output transmitted from the magazine drive member passive In a toy gun magazine equipped with a bullet feeding device for continuously sending out spherical bullets, the spherical bullets guided by the tapered inner wall portion whose interval is gradually narrowed by the longitudinally placed screw arranged on the inner wall portion of the magazine A toy comprising a bullet feeding device having a structure for feeding into a conveyance path, and comprising a livestock power device and a clutch mechanism that works when the limit of livestock power is reached between the passive member and the bullet feed device. Magazine for guns. Functions by the passive member that makes contact with the magazine drive member placed on the toy gun with continuous firing function and passively drives the magazine drive output, and the passive member that makes the magazine drive output transmitted from the magazine drive member passive In a toy gun magazine equipped with a bullet feeding device for continuously sending out spherical bullets, the spherical bullets guided by the tapered inner wall portion, whose intervals are gradually reduced, are placed on the magazine inner wall portion by a laterally placed screw. A toy comprising a bullet feeding device having a structure for feeding into a conveyance path, and comprising a livestock power device and a clutch mechanism that works when the limit of livestock power is reached between the passive member and the bullet feed device. Magazine for guns. A toy gun having a continuous firing function, characterized in that a magazine driving member is provided in the magazine mounting portion for the purpose of transmitting a force for driving the bullet feeding device in the magazine, and is an electric toy gun, A magazine drive member having a mechanism for performing livestock power linked to a member that reciprocates while being influenced by a cam or cam pin or a toothless gear provided on a rotary drive member for driving a piston, and releasing the livestock power. A toy gun having a continuous firing function characterized in that a magazine driving force is instantaneously transmitted to the magazine side by momentarily moving the magazine and utilizing inertia . A toy gun having a continuous firing function, characterized in that a magazine driving member is provided in the magazine mounting portion for the purpose of transmitting a force for driving the bullet feeding device in the magazine, and is an electric toy gun, This is a toy gun whose magazine drive member stop position is not always fixed, depending on how the shooting mode is switched, such as semi-auto, full-auto, etc. When the magazine is installed when the stop position of the magazine drive member is deviated from the initial setting position of the mesh of the passive member arranged on the magazine side, it is pushed by the passive member arranged on the magazine side. The magazine drive member has a mechanism for temporarily retracting, and when the continuous fire starts again, the magazine drive member and the passive member are To engage properly with each other initialization position seen, toy gun having a continuous firing function magazine drive member and having a return mechanism for returning to the initial setting position. A toy gun having a continuous firing function, characterized in that a magazine driving member is provided in the magazine mounting portion for the purpose of transmitting a force for driving the bullet feeding device in the magazine, and is an electric toy gun, This is a toy gun whose magazine drive member stop position is not always fixed, depending on how the shooting mode is switched, such as semi-auto, full-auto, etc. When the magazine is mounted when the stop position of the magazine drive member is deviated from the initial setting position of the engagement of the passive member arranged on the magazine side, the rotary member that is the magazine drive member is The magazine drive member can be moved by pushing the passive member by rotating in contact with the inclined shape part. Toy gun with a continuous firing function, characterized in that there. A toy gun having a continuous firing function, characterized in that the magazine mounting member is provided in the magazine mounting part for the purpose of transmitting a force for driving the bullet feeding device in the magazine, and is a gas type toy gun, A moving member that moves along the axial direction of the barrel is provided, and the moving member reciprocates by supply and discharge of gas pressure, and is equipped with an animal power mechanism that generates animal power as the moving member moves, and the animal power is released. A toy gun having a continuous firing function, characterized in that a striker member that strikes an impact valve is provided outside the cylinder, the magazine driving member is linked to the striker member, and the magazine driving force is output as a reciprocating motion. .