| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 261 | System and method for calculating a projectile impact coordinates | US11931059 | 2007-10-31 | US08360776B2 | 2013-01-29 | Paige Manard; Charles Doty |
| A training system and method to calculate actual coordinates of a projectile impact at one or more screens has been disclosed. A projectile is launched at a screen. One or more targets are projected onto the screen. A calibrated sensor is directed at the screen surface. The sensor continually captures thermal images of a screen surface. The sensor comprises software to detect and isolate thermal images of the projectile impacting the screen. These impact images are transmitted to a computer connected to the sensor. A computer comprises software to calculate the actual impact coordinates relative to a projected target. The calculated coordinates are digitally sent to feedback devices for display purposes. The system further comprises virtual training scenarios that are triggered upon notification of actual impact coordinates. These training scenarios simulate real life situations. | ||||||
| 262 | FLASHLIGHT ACTIVITY GAME | US13482051 | 2012-05-29 | US20120315819A1 | 2012-12-13 | Kathleen GANDY |
| A flashlight activity game is disclosed that is played with a common or custom flashlight. The flashlight activity game allows a first player to hide a detector that a second player must find with a flashlight. The flashlight may also have a focusable or diffuser lens to allow younger children to have a broader beam of light and older children to have a narrower beam to equalize the challenge for all players. The detector emits a flashing light and/or sounds when the detector is located with light from a flashlight. Multiple people can also play where the detector is placed by one person and two or more people compete to find the detector first. The detector is self-powered to allow for hours of play without charging or replacement of batteries. | ||||||
| 263 | Stun grenade with time delay trigger | US13068498 | 2011-05-12 | US20120288830A1 | 2012-11-15 | David Van Zuilen; Thomas L. Fiechter |
| A grenade simulator comprises a housing with an integral internal track. A carriage is mounted on the track for linear movement. A travel limit is provided at one end of the track to limit movement of the carriage on the track. A gas source is installed on the carriage. A drive spring installed between the carriage and the housing for urging the carriage against the travel limit. A multi-link trigger is installed on the housing for holding the carriage away from the travel limit until the multi-link trigger is released. A bayonet opens the gas source upon the carriage reaching the travel limit. A release delay is integral with the multi-link trigger. | ||||||
| 264 | NETWORK WEAPON SYSTEM AND METHOD | US11838873 | 2007-08-14 | US20120214137A1 | 2012-08-23 | John Goree; Brian Feldman |
| Allows for the assignment of threat(s) to weapon(s) to allow operators to coordinate actions. Enables dynamic discovery and operation weapon(s), sensor(s) over a local or public network so available weapons can be selected by operators. Sensors may act as simulated weapons and may also reside in a video surveillance system (VSS). Sensors may be collocated or away from weapons which may differ in number. Sensors simulating weapons are transparently interchangeable with actual weapons. Simulated actors and events may be injected into system with operator gestures recorded for later analysis. Operator may control more than one weapon or sensor at a time. Operator user interface may be cloned onto another computer for real-time supervision or for later use. Integration of existing VSS with a network of remotely operated weapons or simulated weapons enables a passive video surveillance system upgrade to become a projector of lethal or non-lethal force. | ||||||
| 265 | FIREARM BARREL PLUG AND TRAINING METHOD | US13397667 | 2012-02-15 | US20120214136A1 | 2012-08-23 | Richard Scott Stone |
| A training/safety plug for use in firearms is provided. In one implementation, the plug comprises a chamber end and a shaft extending away from the chamber end. The chamber end is adapted to fit within a chamber of a designated firearm, the chamber end has a cross-sectional dimension sufficient to prevent the chamber end from extending into a barrel of the designated firearm and further comprises a strike surface for receiving an impact of a firing pin and a proximal end dimension such that the chamber end is not engaged by an ejector mechanism of the firearm. The shaft comprises a barrel end coupled to and extending distally from the generally cylindrical chamber end. The training/safety plug renders the designated firearm inert. Methods of training a student to target a firearm or other targeting device are also disclosed. | ||||||
| 266 | Blank firing adapter for firearm | US12774500 | 2010-05-05 | US08201487B2 | 2012-06-19 | Barry W. Dueck; Karl Honigmann |
| Various techniques are provided for firing blanks from firearms. In one example, a blank firing adapter includes a mount assembly operatively configured to be attached to a muzzle of a firearm. The blank firing adapter also includes a main body having an interior chamber. The blank firing adapter also includes an escape port positioned longitudinally forward of the interior chamber and not in communication therewith. The blank firing adapter also includes a barrier interposed between the escape port and the interior chamber. The blank firing adapter also includes a projectile receiving area positioned longitudinally forward of the escape port and configured to slow down a projectile from the muzzle therethrough. | ||||||
| 267 | Controller for Electrical Impulse Stress Exposure Training | US13314833 | 2011-12-08 | US20120148992A1 | 2012-06-14 | Jeffrey James Quail |
| A control module used in combination with an activation device for generating an activation signal in response to a stress exposure training event and an electrical impulse device for delivering an electrical shock to the user. The control module has a housing for being carried on the user. The module includes a controller function which sends a shock signal to the impulse device to shock the user according to prescribed shock criteria in response to an activation signal. The control module can be used with various activation devices including light-based force-on-force training or video shoot-back simulations. An operator input of the controller enables the prescribed shock criteria stored on the controller which is carried on the user to be adjusted by an operator directly at the module or remotely. | ||||||
| 268 | ENHANCEMENT OF LIVE AND SIMULATED PARTICIPANT INTERACTION IN SIMULATORS | US12902991 | 2010-10-12 | US20120088209A1 | 2012-04-12 | Chandria A. Poole; Jonathan C. Brant; Omar Hemmali; Michael Riera |
| A simulated participant system is configured to interoperate with existing simulators to create an integrated simulation platform with enhanced capabilities to provide, on a readily-scalable basis, simulated participants of one or more different types that are based on dynamically constructed virtual models of live simulation participants. The system observes live participants as they train with a simulator using a closed-loop, self-training configuration by continuously monitoring conversations and actions to create and maintain the virtual models on-the-fly. The virtual models may then be utilized to generate simulated participants to stand in for the live participants when they are absent from future simulator training sessions. Because a simulated participant was virtually modeled from observations of a live participant, the simulated behaviors, as expressed by actions and responses, can typically closely match the expected behavior of the absent live participant. | ||||||
| 269 | M249 NON-FIREARM SIMULATING A FUNCTIONAL M249 FIREARM | US13155683 | 2011-06-08 | US20110306019A1 | 2011-12-15 | Robert I. Landies; Daniel L. Albright; Joshua G. Hershberger; Brian E. Johnson |
| A non-firing housing imitates a functioning receiver for an M249 machine gun. The non-firing housing includes one or more of a number of alterations as compared to a functioning M249 receiver. Such alterations include: providing a non-firing barrel support with substantial dimensional differences as compared to a standard M249 barrel support; providing a non-firing barrel support with additional structural features that prevent any bolt head (and particularly a standard M249 bolt head) from entering the battery position; providing right or left non-firing bolt rails with dimensional or structural or positional alterations as compared to standard right and left bolt rails for a standard M249; providing the non-firing housing with the absence of an ejection port; providing a non-firing right bolt rail with the absence of a hinge bore; and providing a non-firing left bolt rail with the absence of an ejector pin bore and back stop material. | ||||||
| 270 | Drill cartridges, adaptors, and methods for multi-caliber drill cartridge training | US13190135 | 2011-07-25 | US20110287389A1 | 2011-11-24 | Oren UHR |
| A caliber specific drill cartridge and an adaptor assembly for transforming the caliber specific drill cartridge for use in a first firearm chamber into a caliber specific drill cartridge assembly for use in a second firearm chamber. The adaptor assembly may include a drill cartridge having a first central axis, a rear casing, and a front casing with a first maximum outer dimension perpendicular to the first central axis. The front casing may be connected to the rear casing such that the front and rear casings cooperate to form a housing, which may be configured and dimensioned for chambering in a first firearm chamber. The adaptor assembly further may include a cartridge specific adaptor with a second central axis. The drill cartridge and the cartridge specific adaptor may be combined such that the adaptor assembly is configured and dimensioned for chambering in a second firearm chamber. | ||||||
| 271 | GUN SIGHT | US12785781 | 2010-05-24 | US20110283589A1 | 2011-11-24 | John W. Matthews; Mark Buczek; Mark Squire |
| Various gun sights for firearms and related methods of use are provided. In one embodiment, the sight includes an apparatus adapted to be mounted at a rear end of a firearm and arranged to occlude one eye of a user of the firearm and to generate an illuminated dot that is disposed such that it is generally centered on the longitudinal axis of the barrel of the firearm. The gun sight produces a collimated beam of light that creates an image of an illuminated dot by either a refractive method or a reflective method. In use, a dominant eye of the user is occluded by the sight and the other eye of the user is focused on the target. The user then adjusts the position of the gun relative to the target such that the user perceives the illuminated dot of the sight to be positioned on the target. In one embodiment the sight includes a dry fire detector that generates some output to the user, such as an increase in brightness of the illuminated dot, at the instant the weapon would have fired if a round had been in the chamber. | ||||||
| 272 | Method of training utilizing a threat fire simulation system | US12643097 | 2009-12-21 | US08016594B2 | 2011-09-13 | Robert D. Ferris; Roger D. Malin |
| A threat fire simulation system (40) for simulating a projectile impacting a user (26) includes an electrical impulse element (44) configured for physical contact with the user (26). A controller (42) is in communication with the electrical impulse element (44). The controller (42) enables receipt of a signal (54) for activating electrical impulse element (44) to deliver a non-disabling electrical pulse (46) to the user (26). The electrical pulse (46) simulates an impact of the projectile on the user (26). | ||||||
| 273 | NON-FIRING HOUSING IMITATING A FUNCTIONING RECEIVER FOR A FIREARM | US12625082 | 2009-11-24 | US20110120291A1 | 2011-05-26 | Robert I. Landies; Daniel L. Albright; Joshua G. Hershberger |
| A non-firing housing imitates a functioning receiver for a semi-automatic or fully automatic gun. The non-firing housing includes a thick sidewall that is thicker than the corresponding sidewall of the functioning receiver such that the non-firing housing prohibits the receipt of at least one of the required firing components that are received in the functioning receiver to create a functioning gun, thus prohibiting the use of the non-firing housing as a functioning receiver in a semi-automatic or fully automatic gun. | ||||||
| 274 | Trigger finger strengthening apparatus and method | US12259704 | 2008-10-28 | US07927266B1 | 2011-04-19 | Jeffrey Scott Morris |
| A finger strengthening device is a simulated handgun fitted with an adjustable spring-loaded trigger mechanism. The handgun simulation is selected to match the model of gun to be used, and the exertion required to pull the trigger is initially set at the maximum resistance the shooter can achieve with a steady pull and aim. A method or regimen for proper strengthening is included. | ||||||
| 275 | Simulated firearm | US11502662 | 2006-08-12 | US07926405B2 | 2011-04-19 | Charles J. Ducastel, Jr. |
| A simulated firearm for discharging a blank cartridge and generating a realistic flash and report from the muzzle. The simulated firearm of the present invention prevents the discharge of lethal cartridges or projectiles. The simulated firearm has a chamber 65. The chamber 65 is reversed so that the entrance to the chamber 65 faces the forward section of the simulated firearm. A blank cartridge is loaded into the chamber 65. The blank cartridge is safely discharged from the reversed chamber. | ||||||
| 276 | Training bolt for rifle | US12231247 | 2008-08-28 | US07841118B2 | 2010-11-30 | Shayle VanVlymen |
| A training bolt for use in an automatic or semi-automatic firearm includes a training bolt installable in a bolt receiver of a firearm, wherein the training bolt is constructed and arranged with cutouts and protrusions which cooperate with the internal structure of the firearm bolt receiver and which allow function of the hammer/trigger/safety mechanism of the firearm, wherein the training bolt is configured to prevent, absolutely, chambering or firing a live round. | ||||||
| 277 | METHOD OF TRAINING UTILIZING A THREAT FIRE SIMULATION SYSTEM | US12643097 | 2009-12-21 | US20100227299A1 | 2010-09-09 | Robert D. Ferris; Roger D. Malin |
| A threat fire simulation system (40) for simulating a projectile impacting a user (26) includes an electrical impulse element (44) configured for physical contact with the user (26). A controller (42) is in communication with the electrical impulse element (44). The controller (42) enables receipt of a signal (54) for activating electrical impulse element (44) to deliver a non-disabling electrical pulse (46) to the user (26). The electrical pulse (46) simulates an impact of the projectile on the user (26). | ||||||
| 278 | SHOOTING SIMULATION SYSTEM AND METHOD | US12608820 | 2009-10-29 | US20100221685A1 | 2010-09-02 | George Carter |
| A shooting simulation system and method. The system includes a plurality of firearms. Each firearm is held by a separate player and includes a man-worn computer, an optical system associated with the firearm for capturing an image. The image provides information on a trajectory of a simulated bullet fired from a shooting firearm. The system determines if the captured image is a hit or a miss of targeted player and informs a man-worn computer of the targeted player of a hit by the shooting firearm. The determination if the captured image is a hit or miss and identity of the targeted player may include utilizing various types of information, such as the location of the shooting firearm and the targeted player, orientation of the shooting firearm, trajectory of the projected ammunition of the shooting firearm, terrain data and atmospheric conditions. | ||||||
| 279 | Non-firing training rifle | US11647817 | 2006-12-29 | US07753679B1 | 2010-07-13 | Brian D. Schuetz |
| A non-firing rifle that emulates a semi-automatic or automatic rifle for training in procedures for safe handling, cleaning, and field stripping of such weapons. The non-firing rifle retains the upper receiver assembly, barrel assembly, and ammunition magazine of the emulated rifle, as well as some of the components of the lower receiver assembly of the emulated rifle, but substitutes a modified forging for the lower receiver forging of the emulated rifle. Unlike the lower receiver forging of the emulated rifle, the modified forging has no cutouts to allow a trigger or hammer to be installed. A cutout is provided in a bottom wall of the forging, however, to allow installation of a pseudo-trigger. Accordingly, it is incapable of firing a live ammunition round. | ||||||
| 280 | GUN SIMULATOR | US12467989 | 2009-05-18 | US20100099059A1 | 2010-04-22 | Sandford H. Burford |
| The chain gun simulator provides a high-fidelity simulation of the electrical control system signals for any weapon platform using a variety of chain gun types. The simulator device is stand-alone, requiring no external equipment, and replicates the electrical states, levels, and timing of the real guns such that the weapon platform's fire control interface can function normally without the need for a real gun and live ammunition. In addition, the simulator provides user control for selecting gun type and mode, and provides visual indication of modes, feed selection, and simulated weapon bolt position. There may also be an audible indication every time the simulator has advanced through the normal shutdown portion of the gun cycle. | ||||||
QQ群二维码
意见反馈
意见反馈