RU205620U1 - TOY GUN POWER OFF DETECTION DESIGN - Google Patents

Abstract

The toy gun power outage detection structure has a main structure that includes a pistol body, a barrel formed on one side of the pistol body, a feed channel formed in the pistol body, a chamber formed in the pistol body and communicating with the barrel and feed channel, a chain device located in the pistol body, at least one wireless detection device located in the pistol body and electrically connected to the circuit device, and a bullet forward propelling device located in the chamber and electrically connected to the circuit device. The feed channel can be connected to the clip, and the wireless detection device is configured to detect a bullet fed from the clip. When the magazine runs out of bullets and the wireless detection device does not detect a bullet, a power outage signal is sent to the circuit device to the forward propellant.

Description

Technical field to which this utility model belongs

This utility model relates to a toy pistol power outage detection design that simulates the firing mechanism of a real pistol in the absence of cartridges, reduces energy costs and friction losses, and does not require a special pistol clip to ensure power outage in the absence of cartridges.

Prior Art of the Present Utility Model

Among toy pistols, those that are powered by electricity are commonly referred to as "electric pistols," in which the firing occurs by the motor being configured to actuate the gearbox, causing the piston pump to compress the spring, with the gearbox repeatedly and cyclically performing automatic download operation. Thus, cartridges can be released due to pneumatic pressure and achieve the effect of simulating shooting from a real pistol.

However, the known electric guns have certain disadvantages, which are discussed below, and therefore requires further improvement.

Firstly, due to the lack of a power outage to the motor, most toy pistols continue to work even if there are no cartridges in the clip, which makes it impossible to simulate the firing mechanism of a real pistol in a state when the cartridges have run out.

Secondly, the continuous operation of the motor after the cartridge has run out of cartridges causes unnecessary energy consumption and may even cause damage to its parts.

Thirdly, all the power cut-off devices in the absence of cartridges that have been proposed and are currently known must work with special or specialized clips that have a cartridge ejection function, and it cannot be detected whether there are still cartridges left in the chamber without using such a special pistol clip. ...

Fourth, prior art power cut-off designs use push and contact means to detect if there is still a cartridge in the cartridge, and this can cause damage to parts due to friction and abrasion during long-term use.

Brief disclosure of this utility model

The main purpose of the present invention is to locate a wireless detection device in the gun body to detect the forward moving cartridge in order to achieve the effect of automatically turning off the power in the absence of cartridges remaining in the cartridge, and thus reducing energy consumption and caused by frictional abrasion. as well as imitation of the mechanism of firing from a real pistol in the case when the cartridges have run out.

To achieve the above objective, the present utility model has a main structure, which comprises: a pistol body, wherein the pistol body has one side that forms the muzzle, a feed channel and a chamber formed inside the pistol body, and the chamber communicates with the barrel and feed channel, the body the pistol is also provided within it with a chain device and at least one wireless detection device, wherein the wireless detection device is electrically connected to the circuit device, the wireless detection device is located on one side of the feed channel and chamber, and the bullet forward propelling device is located on one side of the chamber, opposite the muzzle, the propelling device is electrically connected to the circuit device, one side of the propelling device is adjacent to the wireless detection device.

With the structure described above, the user can use the feed channel to connect to the clip so that when the user pulls the trigger, the bullet forward propeller located in the chamber moves backward, namely moves towards one side of the feed channel away from the muzzle. , for supplying bullets from the clip to the junction between the feed channel and the chamber. In this state, the wireless locator detects at this location, and object detection indicates that there are still bullets remaining there. Thus, the device for propelling the bullet forward continues to operate. When the bullets are used up, and the user is still pulling the trigger, causing the bullet advance device to move backward, the wireless detection device does not detect any bullets, and therefore sends a signal to the circuit device indicating that there are no bullets left in the clip, to be disabled by devices of the power circuit of the device for propelling the bullet forward.

Thus, the effect of power off in the absence of cartridges can be achieved without using a special pistol clip, and it is possible to simulate the firing mechanism of a real pistol in a state of no cartridges, and also reduce the loss of electricity, and in addition, the wireless detection design of the wireless detection device also provides the effect of reducing losses caused by friction and abrasion.

Brief description of the figures

FIG. 1 is a perspective view of the present utility model.

FIG. 2 is a cross-sectional view of the present utility model.

FIG. 3 is an exploded view of the present utility model.

FIG. 4 is a schematic view illustrating a descent according to the present invention.

FIG. 5 is a schematic view illustrating compression according to the present invention.

FIG. 6 is a schematic view illustrating firing according to the present invention.

FIG. 7 is a schematic view illustrating power off according to the present invention.

Detailed disclosure of this utility model

Referring to FIG. 1-3, which are, respectively, a perspective view of the present utility model, a cross-sectional view and an exploded view, these figures clearly show that the present utility model comprises:

a pistol body 1, the pistol body 1 having one side that forms a barrel 11;

a supply channel 12, the supply channel 12 being formed inside the gun body 1, the supply channel 12 being connected to the cage;

a chamber 13, the chamber 13 being formed within the pistol body 1 and communicating with the barrel 11 and the feed channel 12;

device 2 of the chain, and the device 2 of the chain is located in the body 1 of the gun;

at least one wireless detection device 3, wherein the wireless detection device 3 is located in the pistol body 1 and is electrically connected to the circuit device 2, the wireless detection device 3 is located on one side of the feed channel 12 and the chamber 13 for detecting a plurality of bullets or cartridges delivered from clips; and

device 4 for advancing the bullet forward, the device 4 for advancing the bullet forward is located on one side of the chamber 13 opposite the muzzle 11 and is electrically connected to the circuit device 2, and one side of the device 4 for advancing the bullet forward is adjacent to the wireless detection device 3.

Preferably, the chain device 2 is located on one side of the feed channel 12 and the chamber 13, and the location at the junction between the feed channel 12 and the chamber 13 is given as an example for explanation.

Preferably, the circuit device 2 comprises a printed circuit board.

Preferably, the wireless detection device 3 comprises an infrared interrupt sensor.

Preferably, in the present embodiment, an electric pistol is taken as an example of a toy gun in the present embodiment.

In the present embodiment, the chain device 2 is provided on one side with a first connecting arm 21, and on the opposite side is also provided with a second connecting arm 22, so that the chain device 2 has an inverted U-shape. As an illustrative example, two such wireless detection devices 3 are shown, which are respectively located on the first connecting arm 21 and the second connecting arm 22.

In the present embodiment, the forward propellant 4 comprises a bullet pushing member 41, a drive member 42 connected to one side of the bullet pushing member 41 remote from the muzzle 11, a blocking member 43 located on one side of the drive member 42, and an elastic member 44. having two sides abutting, respectively, the drive element 42 and the locking elements 43. For illustration, a spring is taken as an example of the elastic element 44.

In the present embodiment, the chamber 13 is provided with a restriction slot 131 which is formed therein at a location corresponding to the arrangement of the chain 2.

In the present embodiment, the chamber 13 is provided with a restriction member 5, which corresponds in position to the projection device 4 of the bullet. The restricting element 5 is provided with at least one detector through hole 51, which corresponds in position to the wireless detection device 3, and a feed through hole 52, which corresponds in position to the feed channel 12.

The design according to the present utility model can be understood from the above description, and based on the appropriate combination of the above design, the power can be automatically turned off, even if a special pistol clip is not used, to create a mechanism for firing a real pistol when there are no cartridges or bullets, and also to reduce losses related to electricity and friction. A detailed description will be provided below.

Referring to FIG. 1-7, which are, respectively, a perspective view of the present utility model, a cross-sectional view and an exploded view, and schematic views illustrating the descent, squeeze, firing and power off according to the present utility model, using the above-described assembled and The combined design in these figures clearly shows that for the use of the present invention, the feed channel 12 of the pistol body 1 is first connected to the clip 6, and the spring located inside the clip 6 pushes the bullets 7 upward so that the uppermost bullet 7 abuts and contacts the lower side the bullet pushing element 41 of the bullet forward propelling device 4, and in this state, the bullet pushing element 41 blocks the advance of the bullets 7 along the feed channel 12 and entering the chamber 13 due to this blocking state.

With this design of the electric gun, when the user pulls the trigger, the motor starts to rotate and drives the gear to rotate to, through the rack transmission, move the actuator 42 backward. Since the bullet pushing element 41 is connected to the drive element 42, the bullet pushing element 41 moves backward simultaneously with it, and the bullets 7 in the cartridge 6 are no longer blocked by the bullet pushing element 41 and are biased or pushed by the spring inside the cartridge 6 into the chamber 13 with the location between two devices 3 wireless detection.

At the same time, when the bullet pushing member 41 moves backward, the wireless detection devices 3 are activated. According to the above description of the present embodiment, the wireless detecting devices 3 are infrared interrupt sensors, and their number is two, one of which performs the function of transmitting an infrared signal and the other receives an infrared signal when the signal transmission between the two wireless detecting devices 3 is blocked and interrupted. , this indicates that bullets 7 remain in the clip 6, and thus the propellant 4 continues to operate.

When the actuator 42 moves the bullet pushing member 41 back to dead center, since the resilient member 44 is abutted against the structure of the locking members 43, the bullet pushing member 41 resiliently returns back into the chamber 13, contacting the bullet 7 that moves along the channel 12 feed into the chamber 13, forcing the bullet 7 to move into the barrel of the pistol to complete the reloading operation. Then the piston is activated, compressing the air to pass through the bullet pushing element 41 for firing the bullet 7 from the muzzle 11.

When the magazine 6 runs out of bullets 7, if the user pulls the trigger again, the bullet-pushing element 41 is activated in the same way as described for moving backwards, and the wireless detection devices 3 also operate to detect in the area of the chamber 13. However, since there is no bullets 7 remaining in the clip 6, when the bullet pushing element 41 moves backward, there is no object causing an interruption between the two wireless detectors 3, so that the infrared signal can pass from one side to the opposite side, allowing the wireless detectors 3 to detect the absence of bullets 7 remaining in the clip 6, and the signal of the absence of cartridges is transmitted to the circuit device 2, so that the circuit device 2 stops the supply of electricity to the device 4 for advancing the bullet forward and the motor, thereby stopping the operation of the device 4 for advancing the bullet forward and the motor, and thus, providing power outage effect.

The operation of pulling the trigger and firing bullets 7, described above, affects only the design of the known electric pistol, and thus the figures are prepared to reveal the main features of the present utility model. On the basis of the above-described design of wireless detection devices 3 located in the pistol body 1, the effect of turning off the power in the absence of cartridges can be achieved without using a clip with special technical characteristics, which is characterized by the abutment of the cartridge, to simulate the firing mechanism from a real pistol in a state of no cartridges. and also to avoid unnecessary energy consumption. In addition, due to the wireless detection design, the detection operation can always be performed without direct contact with the bullet or cartridge 7, and this reduces friction and abrasion losses and thus helps to increase the overall service life.

In the present embodiment, the first connecting arm 21 and the second connecting arm 22 of the chain device 2 are exemplified by the adhesive attached to the gun body 1. The first connecting arm 21 and the second connecting arm 22 are adapted to mount the chain device 2 with an inverted U-shape, which allows the chain device 2 to be positioned in the chamber 13 and fit over the bullet pushing element 41 and its coverage. Thus, the wireless detection device 3 can be placed directly on the circuit device 2 on one side of the feed channel 12 without the need for additional wires, thereby improving the overall usability.

In the present embodiment, the restriction slot 131 is configured to limit or limit the position of the chain device 2 to securely fix the chain device 2 in the gun body 1. A curved or arcuate groove that corresponds to the curved side line of the chain device 2 is exemplified by the restriction slot 131 for illustration.

In the present embodiment, the restraining element 5 is configured to limit or limit the position of the bullet-pushing element 41. The tubular body in which the outer part of the bullet-pushing element 41 is located is shown as an example of the restraining element 5 for securely holding the bullet-pushing element 41 for the purpose of realizing pushing operations. The construction diagram, in which the detector through hole 51 is shown in the restriction member 5 at a location corresponding to the wireless detection device 3, is designed to prevent the restriction member 5 from blocking and interrupting the infrared signal emitted by the wireless detection device 3. In addition, the structural diagram of the feed through hole 52, represented in the restriction element 5, is such that the bullets 7 from the feed channel 12 can pass through the feed through hole 52 and enter the chamber 13, avoiding the blockage of the bullets 7 by the restriction element 5.

Thus, the toy gun power outage detection structure of the present invention provides the following key features that improve the prior art.

Firstly, the structural diagram of the wireless detection device 3 ensures the detection of bullets 7 remaining in the clip 6, so that when the trigger is pressed, the power will be turned off when there are no bullets 7 left in the clip 6, thereby simulating the firing mechanism from a real pistol in the state lack of cartridges, as well as reducing unnecessary energy costs.

Secondly, with the help of the structural diagram of the wireless detection device 3 located in the pistol body 1, the effect of turning off the power in the absence of cartridges can be realized with a conventional clip 6 without using a clip with special technical characteristics, which is characterized by the cartridge attachment.

Third, the wireless detection design of the wireless detection device 3 helps to reduce friction and abrasion losses, thereby increasing the overall service life.

Fourth, the structural diagram of the chain device 2, having a first connecting arm 21 and a second connecting arm 22, ensures that the chain device 2 is positioned in the chamber 13 and fits over the bullet pushing element 41 and its coverage, providing the location of the wireless detection device 3 on the chain device 2 without the need for additional electrical wires.

Claims (10)

1. A power outage detection structure for a toy pistol, generally comprising: a pistol body, the pistol body having one side that forms a barrel; a supply channel, wherein the supply channel is formed inside the gun body, and the supply channel is connected to the ferrule; a chamber, the chamber being formed within the body of the pistol and communicating with the muzzle and the feed channel; a chain device, the chain device being located in the gun body; at least one wireless detection device, wherein the wireless detection device is located in the pistol body and is electrically connected to the circuit device, the wireless detection device is located on one side of the feed channel and chamber for detecting a plurality of bullets or cartridges delivered from the clip; and a propelling device, the propelling device being located on one side of the chamber opposite the muzzle and electrically connected to the circuit device, one side of the propelling device being adjacent to the wireless detection device. 2. The toy gun power outage detection structure of claim 1, wherein the circuit device is located on one side of the feed channel and chamber. 3. The toy gun power outage detection structure according to claim 2, wherein the wireless detection device is located on the circuit device. 4. The toy gun power outage detection structure of claim 2, wherein the circuit device comprises a first connecting arm formed on one side thereof, and the circuit device comprises a second connecting arm formed on one side opposite the first connecting arm. 5. The toy gun power outage detection structure according to claim 1, wherein the chamber is provided with a restriction slot formed therein at a location corresponding to the circuit arrangement. 6. The toy gun power outage detection structure according to claim 1, wherein the chamber is provided with a restriction member that corresponds in position to the bullet forward propelling device. 7. The toy gun power outage detection structure according to claim 6, wherein the restriction member is formed therein with at least one detector through hole, the position of which corresponds to the wireless detection device, and the feed through hole, the position of which corresponds to the feed channel. 8. The toy gun power outage detection structure according to claim 1, wherein the bullet forward propellant comprises a bullet pushing member, a drive member connected to one side of the bullet pushing member remote from the muzzle, a blocking member located on one side of the drive member, and an elastic element having two sides adjacent, respectively, to the drive element and the blocking elements. 9. The toy gun power outage detection structure of claim 1, wherein the at least one wireless detection device comprises two wireless detection devices. 10. The toy gun power outage detection structure according to claim 1, wherein the wireless detection device comprises an infrared interrupt sensor.

Images