81 |
Apparatus for repelling birds or beasts |
US370 |
1987-01-05 |
US4745859A |
1988-05-24 |
Kim M. Kyoung; Chung K. Hong |
An apparatus for repelling birds or beasts by exploding gunpowder automatically and repeatedly to make explosive sounds. The apparatus comprises a housing, a body plate on which most of other parts of the apparatus are mounted, an electric motor, a disk-like gear mechanically connected to the electric motor via reduction gears, a gunpowder striking hammer and a driving link, respectively, rotatably secured to the body plate and being actuated by the rotation of the disk-like gear, a gunpowder supply plate driven by the driving link, a gunpowder band winding spool, a bottom plate for placing the gunpowder band, and a switch assembly operated by the rotation of disk-like gear and electrically connected with a timer, a dry cell battery, and the electric motor. |
82 |
Automatic weapons effect signature simulator |
US485597 |
1983-04-18 |
US4654008A |
1987-03-31 |
Lester C. Elmore |
An automatic weapons effects simulator (AWES) reproduces the visual and acoustic signatures associated with the firing of a weapon used in combat troop engagement simulation. The AWES is directly integrated into the weapon and allows the weapon operator to utilize the basic weapon mechanism in the same manner as with the original parts and at a cost advantage as compared to the cost of blank ammunition. |
83 |
Apparatus for simulated shooting with hit indicator |
US120541 |
1980-02-11 |
US4342556A |
1982-08-03 |
Werner Hasse |
An apparatus for simulated shooting is disclosed which includes a laser transmitter for directing a laser beam, as a simulated shot, towards a target; a receiver and evaluation device on the target for determining the deviation of the laser beam from the target in terms of magnitude and direction, and an impact indicating device on the target which is controllable by the evaluation device such that pyrotechnic charges are ejected in the determined direction of the deviation of the laser beam from the target and ignited so as to represent the light and smoke phenomena of the impact of a real projectile. |
84 |
Detonation producing ammunition |
US3749018D |
1969-10-22 |
US3749018A |
1973-07-31 |
GERMERSHAUSEN R |
A detonation producing ammunition which comprises a discharging cup and a detonation body which is ignitable in the discharging cup. A bucket-shaped container of synthetic material is arranged which receives the detonation body jolt-free and closeable. The container is secured relative to the detonation body and the discharging cup surrounds the container such, to form during and after the firing of the detonation body a lining protecting the discharging cup and remaining unimpaired, and the lining is easily removable.
|
85 |
Firing equipment for simulating gunfire |
US7266970 |
1970-09-16 |
US3712230A |
1973-01-23 |
HOFFMANN OSWALD |
Firing equipment for simulating gunfire having a plurality of firing cups for accommodating pyrotechnic devices and each firing cup is associated with a separate detonating device to be set off by control apparatus.
|
86 |
Gunfire simulator employing friction type detonators |
US72904358 |
1958-04-16 |
US2958150A |
1960-11-01 |
DU BOIS EDWIN R |
|
87 |
Small weapons noise simulator |
US45899854 |
1954-09-28 |
US2836919A |
1958-06-03 |
DU BOIS EDWIN R |
|
88 |
Thermostatic electric switch |
US75013847 |
1947-05-23 |
US2471806A |
1949-05-31 |
WILSON BENJAMIN J; MACHLER RAYMOND C; POLSTER NORMAN E; MURRAY GEORGE E R |
|
89 |
Device for making sound effects |
US52968644 |
1944-04-05 |
US2425975A |
1947-08-19 |
JOHN WITTE LOUIS; HARRISON SOUTHLAND BENJAMIN |
|
90 |
Apparatus for firing powder |
US47197243 |
1943-01-11 |
US2338762A |
1944-01-11 |
ALFRED GROTH; HANAUER HENRY J |
|
91 |
Jtnta hirayama |
US282891D |
|
US282891A |
1883-08-07 |
|
|
92 |
Frank s |
US262240D |
|
US262240A |
1882-08-08 |
|
|
93 |
PNEUMATIC SYSTEM AND METHOD FOR SIMULATED FIREARM TRAINING |
US15660700 |
2017-07-26 |
US20180313630A9 |
2018-11-01 |
Benjamin T. Tiberius; Jonathan S. Willson |
A training method and apparatus are disclosed. The training method may include converting a firearm capable of firing live ammunition to a pneumatic training device incapable of firing live ammunition. The training method may further include cycling a pneumatic training device through one or more cycles. Each of the cycles may simulate an actual firing of the firearm. Each of the cycles may also include triggering a trigger assembly of the pneumatic training device, using a charge of a pressurized gas to reset the trigger assembly, and advancing a counter of the pneumatic training device. After a certain number of cycles have been completed, a next cycle may be attempted, but not completed. Accordingly, the training method may enable a user to safely and realistically practice reloading, jam or malfunction clearing, or the like. |
94 |
NOISE GENERATION DEVICE |
US15559087 |
2016-03-18 |
US20180071645A1 |
2018-03-15 |
Mark Daniel Hugill; Shane Ross Hugill |
A noise generation device comprising: a housing defining a chamber, the housing comprising a wall member moveable between a sealed position and an open position, wherein in the sealed position the chamber is fluidly sealed and in the open position the chamber is open; an injection assembly for injecting combustible material into the chamber; and a triggering assembly for triggering the combustible material to combust inside the chamber to generate a noise, wherein the noise generation device is configured such that the moveable wall member moves from the sealed position to the open position on combustion of the material inside the chamber to allow material to exit the chamber. A gun attachment and a simulation weapon are also disclosed. |
95 |
Haptic feedback spark device for simulator |
US15657275 |
2017-07-24 |
US09879958B2 |
2018-01-30 |
William John Carey |
Haptic feedback system that simulates a detonation or explosive event. The system includes a power supply, an energy storage circuit, a switching circuit, and a conductor operatively connected to said energy storage circuit through said switching circuit whereby said conductor causes a haptic event when said energy storage circuit is electrically connected to said conductor by operation of said switching circuit. The system creates shock waves and pressure waves in a safe manner for use in a simulator. |
96 |
PNEUMATIC SYSTEM AND METHOD FOR SIMULATED FIREARM TRAINING |
US15660700 |
2017-07-26 |
US20180010878A1 |
2018-01-11 |
Benjamin T. Tiberius; Jonathan S. Willson |
A training method and apparatus are disclosed. The training method may include converting a firearm capable of firing live ammunition to a pneumatic training device incapable of firing live ammunition. The training method may further include cycling a pneumatic training device through one or more cycles. Each of the cycles may simulate an actual firing of the firearm. Each of the cycles may also include triggering a trigger assembly of the pneumatic training device, using a charge of a pressurized gas to reset the trigger assembly, and advancing a counter of the pneumatic training device. After a certain number of cycles have been completed, a next cycle may be attempted, but not completed. Accordingly, the training method may enable a user to safely and realistically practice reloading, jam or malfunction clearing, or the like. |
97 |
Haptic Feedback Spark Device for Simulator |
US15657275 |
2017-07-24 |
US20170336182A1 |
2017-11-23 |
William John Carey |
Haptic feedback system that simulates a detonation or explosive event. The system includes a power supply, an energy storage circuit, a switching circuit, and a conductor operatively connected to said energy storage circuit through said switching circuit whereby said conductor causes a haptic event when said energy storage circuit is electrically connected to said conductor by operation of said switching circuit. The system creates shock waves and pressure waves in a safe manner for use in a simulator. |
98 |
ELECTRONIC SIMULATION DEVICE FOR WEAPON |
US15310310 |
2015-05-13 |
US20170268845A1 |
2017-09-21 |
Eriksroed Ole Jakob |
A device for simulation of the mechanical functions of a real weapon using electronic and mechanical solutions is described. The simulation device can be mounted on a real weapon. |
99 |
Haptic feedback device for simulator |
US14858411 |
2015-09-18 |
US09719759B2 |
2017-08-01 |
Owen James Bergen; Andreas Alfred Neuber; Ryan David Nord; Austin Randall Patten; William John Carey; Aaron Jay Wiebe; Mark Allen Thornburg |
Haptic feedback system that simulates a detonation or explosive event. The system includes a power supply, an energy storage circuit, a switching circuit, and a conductor operatively connected to said energy storage circuit through said switching circuit whereby said conductor causes a haptic event when said energy storage circuit is electrically connected to said conductor by operation of said switching circuit. The system creates real explosions, shock waves and pressure waves in a safe manner for use in a simulator. |
100 |
Inflatable bag with burst control envelope and gas generator |
US15058848 |
2016-03-02 |
US09574858B2 |
2017-02-21 |
Curtis E. Graber |
A rupturable bag assembly including a balloon, an outer wall, an inlet port, and a heat resistant shield. The balloon is fabricated from an elastic material. The outer wall is disposed around the balloon, the outer wall having a perimeter seam which parts abruptly at a predetermined tension. The inlet port passes through the outer wall into the balloon for inflating the balloon to produce the predetermined tension. The heat resistant shield is disposed within the balloon opposite the inlet port. The outer wall is constructed of a relatively inelastic material in comparison to the material used to construct the balloon. There is a dispersible medium disposed within the outer wall and/or the balloon. |