| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 221 | MOTION TRACKING, ANALYSIS AND FEEDBACK SYSTEMS AND METHODS FOR PERFORMANCE TRAINING APPLICATIONS | US14607623 | 2015-01-28 | US20160252326A1 | 2016-09-01 | Erik W. Jones; Norman J. Pressman |
| A highly portable system includes the necessary logic and analysis to provide immediate feedback and corrective instruction for any suitable motion. In particular, the system includes a capability for tracking individual shooter performance in a more comprehensive way, in order to provide an organized and methodical feedback to the shooter for the purpose of data-supported improvement, as well as the opportunity to improve marksmanship using dry-fire techniques, when a shooting range is unavailable and/or to reduce ammunition consumption. | ||||||
| 222 | Malfunction training dummy round | US13646736 | 2012-10-08 | US09423221B2 | 2016-08-23 | James Dillon Bonner |
| The present invention is an instrument for simulating malfunctions in firearms during live fire training which could not previously be simulated during live fire training. In some exemplary embodiments the invention approximately matches the external dimensions of an ammunition cartridge with the addition of novel features described herein which modify the interactions between the present invention, firearm magazine assembly and firearm such that a firearm malfunction desirable for malfunction resolution training is simulated. Some exemplary embodiments also include novel features described herein which serve to maintain a desired orientation of the invention in reference to an firearm magazine assembly, an ammunition cartridge or the firearm such that a particular type of firearm malfunction occurs. Some exemplary embodiments include multiple of said novel orientation features such that the user of the invention may select between multiple possible malfunction types. | ||||||
| 223 | Fire Control Housing | US15000132 | 2016-01-19 | US20160209157A1 | 2016-07-21 | Terrence Dwight Bender |
| In some embodiments, a fire control housing comprises a frame defining a cavity. The frame comprises a floor, a first sidewall and an opposed second sidewall. The first sidewall defines a first window. A trigger assembly comprises a hammer and a finger trigger. The finger trigger extends through the floor of the frame. | ||||||
| 224 | Magnetically actuated sear | US14595791 | 2015-01-13 | US09395134B2 | 2016-07-19 | Frederick B. Swensen |
| A magnetically actuated sear for simulated firearm training is disclosed. The magnetically actuated sear includes a magnet and a magnet catch. The magnetically actuated sear facilitates a crisp trigger break thereby replicating the actual sear release of a firearm. The application of a suitable external trigger force causes the magnet catch to travel along the fulcrum away from the magnet. The greater the difference between the holding force when the magnet is in direct contact with the magnet catch and the attraction force between the magnet and the magnet catch, the crisper the magnetically actuated sear will feel. The magnetically actuated sear can be designed so that slack or trigger creep of the magnetically actuated sear can be matched to the actual firearm's slack or trigger creep. | ||||||
| 225 | System and method for detecting moment of impact and/or strength of a swing based on accelerometer data | US14320998 | 2014-07-01 | US09364748B2 | 2016-06-14 | Steven Rabin |
| An example system and method is provided for detecting a moment of impact and/or strength of a swing based on moving a hand-held device including an accelerometer arrangement. A moment and a magnitude of simulated striking of the object are determined based on one or more accelerometer arrangement outputs resulting from the moving of the hand-held device. Using one or more of aural, visual and tactile outputs, the striking of the object is simulated in accordance with the determined moment of simulated striking and the determined magnitude of the simulated striking. | ||||||
| 226 | Toy projectile launching system | US14658165 | 2015-03-14 | US09364741B2 | 2016-06-14 | Benjamin Rosenberg |
| A toy projectile launching system including at least one toy projectile, and at least one toy launcher, each including a receptacle into which a projectile is loaded, a launching mechanism for physically launching a projectile after it is loaded into the receptacle, a target area sensitive to being hit by a projectile, and a display for presenting a message when a projectile, launched by another launcher, hits the target area. | ||||||
| 227 | System and Method for Timing Firearm Practice Drills | US15018513 | 2016-02-08 | US20160153755A1 | 2016-06-02 | Benjamin J. Morgan |
| A firearm training system includes a practice round and a practice barrel. The practice barrel is configured and dimensioned to replace the factory barrel of the firearm. Prior to performing a practice drill, a user loads the practice round into the chamber of the practice barrel similar to a live round. After a short delay, the electronic device provides a start signal to the user and, simultaneously, an electronic timer is started. In response to the start signal, the user performs the practice drill that ends with the firing pin of the firearm striking the practice round in response to a trigger pull. The practice round senses the strike of the firing pin and stops the electronic timer. The electronic device then displays the elapsed time between the start signal and the strike of the firing pin on the practice round. | ||||||
| 228 | Simulated weapon | US13760816 | 2013-02-06 | US09291420B1 | 2016-03-22 | Rick A. Jensen; Jared R. Orvis |
| A simulated weapon or firearm is provided that is formed with a mechanical operating or firing mechanism similar to that of an actual firearm. The firing mechanism is formed with components found in an actual firearm that are interconnected with components of an electronic mechanism that can monitor and control the mechanical operation of the simulated firearm. This allows for the mechanical operating mechanism to function in a manner similar to that of an actual firearm, while the electronic mechanism can introduce various mechanical failures that do not otherwise occur in the electronics-only operating mechanisms of prior simulated firearms. In addition, the operational cycles of the mechanical and electronic mechanisms are synchronized to provide a highly realistic feel to the simulated weapon. | ||||||
| 229 | Target Device for Determining Received Hits in a Light Based Weapons Simulation System | US14598909 | 2015-01-16 | US20160071426A1 | 2016-03-10 | Jeffrey James Quail; Rory Bochinski; Alex McIlraith; Luke Draper; Fred Swensen |
| A target device is usable with a simulation system which includes a weapon simulator having a trigger, a chamber for firing a blank cartridge in response to the trigger, and a transmitter arranged to emit a light signal defining one or more activation codes of prescribed duration in response to the trigger. The target device includes a sensor array of photodiodes and a processor receiving output signals from the photodiodes. The processor determines that the sensor array has been hit by the weapon simulator in response to a first portion of one activation code being received by one of the photodiodes and at least one second portion of the same activation code being received by the same or a different one of the photodiodes when the first portion and the at least one second portion correspond to an entirety of one activation code within the respective prescribed duration. | ||||||
| 230 | FIREARM ACCESSORY | US14776904 | 2014-03-14 | US20160033221A1 | 2016-02-04 | Stewart Jacob Schmehl; Peter James Hamann; Jacob Stewart Schmehl |
| An accessory device useful for any of training, compliance, safety, and accountability of individuals in the use of firearms. An embodiment comprises a circuit board and housing with a means for attaching the accessory to a firearm. The circuit board may comprise an inertial measurement unit (IMU), a GPS receiver, memory to store data, a means for transmitting data, and a microprocessor unit for controlling operations of the printed circuit board. The IMU may comprise a gyroscope, accelerometer, and magnetometer. The accessory can provide position and movement data of such accuracy as to disclose, after transmission and analysis, a firearm user's stability prior to and during discharge, how well the user managed recoil from the discharge, and how quickly the user returned to a starting position following discharge. A reviewer may also be able to discern movements such as those caused by a user's breathing or involuntary muscle contractions. | ||||||
| 231 | Rifle dry-fire apparatus and method | US14634103 | 2015-02-27 | US09207027B1 | 2015-12-08 | Karl E. Hannan; William Jeff Marshall |
| A rifle lower receiver has a trigger well and a magazine well. A hammer is disposed in the trigger well and configured to pivot from a first hammer position to a second hammer position in response to moving a trigger from a first trigger position to a second trigger position. A gear member attached to the lower receiver has a predefined number of gear teeth and a locking pin extending from the gear member. A pawl is connected to the trigger and operationally engages the gear member to increment the gear member once per trigger pull. Upon reaching a predefined number of trigger pulls, the locking member locks the trigger. A release lever on the lower receiver is operably configured to advance the gear member one increment to unlock the trigger. A method of dry-fire training is also disclosed. | ||||||
| 232 | Virtual environment hunting systems and methods | US13489768 | 2012-06-06 | US09200870B1 | 2015-12-01 | Travis B. Theel |
| One virtual environment hunting system includes a platform, a wall surrounding the platform, a projector system configured to apply images to the wall, and at least one processor. The wall is separated from the platform by a floor, defines an opening above the platform, and is configured such that all bullets fired to the wall from a shooter on the platform reflect into the floor. Programming causes the processor to: (a) actuate the projector system to apply images to the wall to represent an environment; (b) determine a trajectory of a fired bullet using data from at least one housing sensor and at least one shooter sensor; (c) determine how the trajectory of the fired bullets interacts with the represented environment; and (d) actuate the projector system to update the images applied to the wall to account for the trajectory of the fired bullets. | ||||||
| 233 | FIREARM ATTACHMENT APPARATUS FOR DRY FIRE TRAINING | US14582162 | 2014-12-23 | US20150233663A1 | 2015-08-20 | Jonathan Ray Kiehn |
| This disclosure describes a firearm attachment and apparatus for more effectively dry-firing a firearm device during marksmanship training. The firearm attachment includes a coupling portion that is configured to fixedly couple the firearm attachment to a slidable member (e.g., a slide of a pistol or a charging handle of a rifle) of the firearm device, and a tethering aperture that is positioned at a distal end of firearm attachment, relative to the coupling portion. When the firearm attachment is coupled to the firearm device via the coupling portion, and a rearward force is applied at the tethering aperture, the firearm attachment pulls the slidable member of the firearm device into a set position for dry-firing the firearm device. The rearward force can be applied by a sling apparatus that attaches to or through the tethering aperture of the firearm attachment. | ||||||
| 234 | PROPER GRIP CONVERSION | US14094090 | 2013-12-02 | US20150153130A1 | 2015-06-04 | Jack Amis; Jesse Beaudin; Dennis Deutsch; Dan Ewert; Zoltan James; David A. Slayton; Susana Slayton; Doug Walker |
| A rifle controller, having a first controller disposed near a trigger, the first controller comprising a joystick. The first controller is disposed such that a user of the rifle controller can manipulate the joystick with a thumb while properly holding the rifle controller to have a thumb of his firing hand above the safety selector lever. | ||||||
| 235 | System and method for simulating firing a gun | US11562456 | 2006-11-22 | US09011151B1 | 2015-04-21 | Giles D. Jones; Qingce Bian; Christopher A. Tomlinson; Jeffrey E. Decker; William W. Price; Bradley C Huang; Peter M. Wallrich |
| According to one embodiment of the present invention, a system for simulating firing a gun comprises a firing system and a transmitting system coupled to the firing system. The firing system fires a cartridge and comprises a chamber and a hammer. The chamber receives and holds the cartridge, and the hammer strikes the cartridge. The transmitting system detects movement of the hammer and transmits simulation data prior to the hammer striking the cartridge. | ||||||
| 236 | Vehicle Crew Training System for Ground and Air Vehicles | US14331103 | 2014-07-14 | US20150010886A1 | 2015-01-08 | Kevin Schubert; Sean Moran; Greg Wieboldt; Donnie Klein; Mark Haack; Sharon Lay; Chris Howard; Michael Dineen; Jerry R. Hubbard; William Araki |
| A computer based simulation system for virtual training for vehicle crews is disclosed. The Vehicle Crew Training System (VCTS) simulates crew positions for different military ground and air vehicles. Two or more crewman modules are networked together to support a partial or full vehicle crew. The crewman modules are self-contained devices that are modular in hardware and software design, easily reconfigurable, and require minimal facility space, allowing use in restricted environments such as trailers. The VCTS is modular at the crew position level; crewman modules are added or deleted as required to meet a particular training need. | ||||||
| 237 | Shooting training device | US14053594 | 2013-10-14 | US08911235B1 | 2014-12-16 | Malcom Baxter |
| The invention is a trigger pull training device for improving trigger pull technique. The device has a frame with a trigger track opening and a trigger which goes through that opening. A proximity sensor or a plurality of proximity sensors are placed proximate the trigger track opening. The sensors are connected to an indicator whereby pulling the trigger such that the trigger is within the sensing zone causes the proximity sensor to emit a signal. A plurality of sensors can be lined along the trigger track opening to indicate the accuracy of any pull. | ||||||
| 238 | Training Rifle and Magazine | US13907835 | 2013-05-31 | US20140356816A1 | 2014-12-04 | Nisim Zusman |
| The present invention is directed to a polymer training rifle which may include a modular receiver portion, a simulated barrel nut, one or more interchangeable modular barrels, and a receiver extension tube. Selected parts and tactical accessories may be connected to the rifle training system to provide a customized training rifle. The modular receiver may include a magazine well that receives an actual magazine or an inert replica magazine. The receiver portion also may include a functional magazine catch assembly which allows a trainee to selectively secure and release a magazine from the magazine well. The one or more modular barrels, modular receiver portion, and inert replica magazine may each include a metal core to allow for detection by security screening equipment. | ||||||
| 239 | Vehicle crew training system | US11055708 | 2005-02-11 | US08864496B2 | 2014-10-21 | Sean C. Moran; Donnie R. Klein; Mark D. Haack; Sharon E. Lay; Christopher J. Howard; Michael J. Dineen; Jerry R. Hubbard; William M. Araki |
| A computer based simulation system for virtual training for vehicle crews is disclosed. The vehicle crew training system (VCTS) simulates crew positions for different military vehicles. Two or more crewman modules are networked together to support a partial or full vehicle crew. The crewman modules are self-contained devices that are modular in hardware and software design, easily reconfigurable, and that require minimal facility space, allowing use in restricted environments such as trailers. The VCTS is modular at the crew position level; crewman modules are added or deleted as required to meet a particular training need. One of the crewman modules can be a gunner module, which provides an unrestricted view of the simulated environment to the gunner by means of a display and a simulated vehicle-mounted weapon. | ||||||
| 240 | Shooting equipment shooting direction control system for shooter game | US13801417 | 2013-03-13 | US08840473B2 | 2014-09-23 | Peng-Hsien Chen; Fa-Quey Lai; Ying-Fu Lin; Shih-Hao Wang |
| A shooting equipment shooting direction control system includes a base unit including a circuit module, a transmission mechanism and a driver controllable by a first micro switch and a second micro switch of the circuit module to rotate the transmission mechanism horizontally left and right, a rotary holder shell coupled and rotatable by the transmission mechanism to move a baffle between the first micro switch and the second micro switch, and a shooting equipment including an equipment base, a power drive unit controllable by the circuit module through a third micro switch and a fourth micro switch in the rotary holder shell to rotate the equipment base vertically up and down relative to the rotary holder shell and a dogleg-shaped trigger movable with the equipment base relative to the rotary holder shell between the third micro switch and the fourth micro switch. | ||||||
QQ群二维码
意见反馈
意见反馈