WO1993012399A1 - Light-beam fire-arm with aiming device - Google Patents

Abstract

A light-beam fire-arm (17) with an aiming device can be used as a toy as well as training appliance and simulator for shooting sports. The object of the invention is to create a light-beam fire-arm (17) with an associated aiming device that works with invisible light and allows both fired shots and hits to be displayed. For that purpose, two infra-red (IR) beam emitting idodes (5, 6) are arranged in the fire-arm and controlled by a remote control emitting circuit so that one of them emits focussed and the other scattered IR pulses which generate electric signals by means of receiving diodes in the aiming device and actuate shot and hit counters by means of remote control circuits.

Description

 Beam gun with aiming device

The invention relates to a light gun with a target device, which can be used both as a toy and as a training device and simulator for sports shooters.

A toy light gun with a target is known, which consists of the actual weapon with a light source, the optically focused rays of which fall on a photo cell after confirmation of a trigger, with the aid of which a rotary plate with cups is then set in motion by means of an electromagnet and if a hit hits one of the cups (DE-OS 28 06 459). In addition to the use of visible light and the possible falsification of the shot result by scattered and external light, the disadvantages of this device are, above all, that the number of shots fired is not registered. The object of the present invention is to provide a light beam firearm with the associated aiming device, which works with invisible light and enables both a hit display and a display of the shots fired. This object is achieved according to the invention in that two transmit diodes for infrared (IR) beams are arranged in the firearm, one of which is controlled via a transmit remote control circuit which transmits one focused, the other scattering IR pulses, each through receive diodes generate electrical signals in the target device and operate shot and hit counters via remote control circuits.

To clarify the invention, it is described using two exemplary embodiments. The associated drawings show:

Fig. 1: A side view of the light beam gun. Fig. 2: A section in an enlarged view through part of the firearm.

REPLACEMENT LEAF 3: A front view of the aiming device in a rectangular shape. Fig. 4: A section in an enlarged view through a target point. Fig. 5: A circuit diagram of the transmitter electronics according to embodiment 1. Fig. 6: A circuit diagram of the transmitter electronics according to

Exemplary embodiment 2. FIG. 7: A circuit diagram of the receiving electronics for the pulses generated according to exemplary embodiment 1. FIG. 8: A circuit diagram of the receiving electronics for the pulses generated according to exemplary embodiment 2. The firearm 17 according to the invention is shown in FIGS. 1 and 2 shown. It has a housing 1 to which a barrel 2 and a piston 19 are attached. The housing 1. is provided with a trigger mechanism 12 which actuates a microswitch 15. In the front part of the housing 1 there is a printed circuit board 3 on which a transmitter diode 5 for the focused IR pulses with an optics carrier 7, a transmitter diode 6 for the scattering IR pulses, the microswitches 18.1 to be actuated from both sides of the firearm .1 and 18.1.2, the microswitches 18.2 to 18 to be operated from the right side of the firearm and all other electronic components are mounted. The microswitches 18.1.1 to 18.n control the IR transmission / reception path for the scattering IR pulses via a discrete or integrated transmit / remote control circuit 25. A receiving diode 9 for the scattering IR pulses controls a discrete or integrated receiving remote control circuit 34, the output signals of which call up the 1 to n functions. The microswitches 18.1.1 or 18.1.2 start a pulse generator 43 of the target device 11

Microswitches 18.2 to 18.n can optionally call n functions, such as. B. reset shot counter 37 and hit counter 36 of target device 11, set pulse time and pulse pause of pulse generator 43, one from 1 to n

REPLACEMENT LEAF Set or reset light beam sources 13.1 to 13.n etc.

The microswitch 15 starts the generation of the IR transmission pulses of the firearm 17, which generate electrical signals in the target device 11 through the receiving diodes, which drive the discrete or integrated receiving remote control circuit 34, the output signals of which continue to count the shot counter 37 and the hit counter 36 increase if the focused IR transmit / receive link had a direct optical connection, d. H. when a hit has been scored.

The target device designated overall by 11 is shown in FIGS. 3 and 4. The geometrical dimensions of its front plate 8 can be selected, here it has a rectangular shape, in the approximate center of which the receiving diode 9 for the scattering IR pulses is installed. The 1 to n target points 10 for the focused IR pulses can be arranged as desired and were installed here in a rising straight line and limited to 8 pieces. The diameters of the openings of the target points 10 for the focused IR pulses can be selected and are approximately 3-5 mm here. The target points 10 have assembly units 60. They are equipped in the same number with IR filters 16, IR receiving diodes 14 for the focused IR pulses and with light sources 13. Behind the front plate 8 there is a printed circuit board behind the target points 10, on which shot counter 37, hit counter 36, microswitch 50.1 to 50.n and all other electronic components are mounted. The microswitch 50.1 starts a pulse generator 43. The microswitches 50.2 to 50.n can optionally call n functions, such as. B. reset shot counter 37 and hit counter 36 of the target device 11, set the pulse time and pulse pause of the pulse generator 43, set or reset one of 1 to n light beam sources 13.1 to 13.n, etc. The mode of operation of the firearm according to the invention and the aiming device according to the embodiment game 1 generates single IR pulses and

REPLACEMENT LEAF will now be described with reference to the circuit diagrams shown in FIGS. 5 and 7.

The pulse generator 43 is started either by actuating the microswitches 18.1.1 or 18.1.2 of the firearm 17. The microswitches 18.1.1 or 18.1.2 start the mono-flop 48. It generates a pulse with a time duration with its Q output of at least 2 bytes of the codes of the discrete or integrated transmit / remote control circuit 25, which controls the remote control circuit 25 via a driver 45.1. At the same time, a switch 29 is switched via an OR gate 52 and a negator 30, which passes the electrical signals coming from the transmitter remote control circuit 25 via preamplifiers 26 to the amplifier 27, which controls the transmitter diode 6 for the scattering IR pulses leaves. The pulses of the transmitter diode 6 generate electrical signals in the IR receiver diode 9, which are led via the preamplifier 31 to the discrete or integrated receive remote control circuit 34. This decodes the electrical signals and its output signal starts the pulse generator 43. The high-active output signals of the pulse generator 43 optionally control via the selector 42 (here the inputs E1 to E8 are directly connected to the outputs AI to A8) via the negators 55.1 to 55.8 the light beam sources 13.1 to 13.8. At the same time, the anodes of the IR receiving diodes 14.1 to 14.8 are connected to high potential. The light beam sources 13.1 to 13.8 light up one after the other in time with the pulse generator 43. The light points migrating here (activated target points) are tracked with the sighting device of firearm 17. If the trigger mechanism 12 of the firearm 17 is actuated, the microswitch 15 switches the mono-flop 22 on. With its Q output, it generates a pulse with a duration of at least 2 bytes of the codings of the transmitter remote control circuit 25, which controls the discrete or integrated remote control circuit 25 via a driver 20.

REPLACEMENT LEAF The electrical signals coming from it are routed via the preamplifier 26 via the switch 29 to the amplifier 28, which controls the IR transmitter diode for the focused IR pulses 5. When they pass through the openings of the target points 10.1 to 10.8, they generate electrical signals via the IR filters 16.1 to 16.8 in the IR receiving diodes 14.1 to 14.8, which then leads via the preamplifier 32 to the remote reception control circuit 34, are decoded by this and the hit counter 36 is incremented with the output signal.

After the pulse time of the mono-flop 22 has elapsed, the low / high edge of the negated Q output starts the mono-flop 23. It generates a pulse with a duration of at least 2 bytes of the codes of the remote control circuit 25, which is transmitted via the driver 21 controls the remote control circuit 25. At the same time, the analog switch 29 is switched via the OR gate 52 and the negator 30, which thus allows the electrical signals coming from the transmitter / remote control circuit 25 to pass through the preamplifier 26 to the amplifier 27.

The scattering pulses of the transmitter diode 6, as already described when the pulse generator 43 was started, now produce a different output signal from the discrete or integrated receive remote control circuit 34, with which the shot counter 37 is incremented.

The mode of operation of the light beam firearm according to the invention and the aiming device according to exemplary embodiment 2 simultaneously generates the same IR pulses and will now be described with reference to the circuit diagram shown in FIGS. 6 and 8.

The pulse generator 43 of the target device 1 is started either by actuating the microswitches 18.1.1 or 18.1.2 of the firearm 17. The microswitches 18.1.1 or 18.1.2 start the mono-flop 48. It generates a pulse with its Q output , with a duration of at least 2 bytes of the codes of the discrete or integrated transmit remote control circuit 25, which controls the remote control circuit 25 via the driver 45.1.

SPARE BLADE The electrical signals of the remote control circuit 25 control the IR transmitter diodes 6 via the preamplifier 26 through the amplifiers 27 and 28; 5, which simultaneously generate the same multiple IR pulses. These pulses generate in the receiving diodes 14.1 to

14.8 electrical signals for the focused IR pulses, which via the preamplifier 31; 32 are led to the analog switch 33 which, controlled by the mono-flop 35, blocks the electrical signals generated by the focused IR pulses, while the electrical signals generated by the scattering IR pulses are sent to the discrete or integrated receive remote control circuit 34 passie¬ whose output signal starts the pulse generator 43. The high-active output signals of the pulse generator 43 optionally control via the selection device 42. se (here the inputs E1 to E8 are directly connected to the outputs AI-A8) via the negators 55.1 to 55.8 the light beam sources 13.1 to 13.8. At the same time, the anodes of the IR receiving diodes 14.1 to 14.8 are connected to high potential. The light beam sources 13.1 to 13.8 light up one after the other in time with the pulse generator 43. The moving light points (activated target points) are tracked with the sighting device of the firearm 17. If the trigger mechanism 12 of the firearm 17 is actuated, the microswitch 15 switches the mono-flop 22 on. With its Q output, it generates a pulse with a duration of at least 2 bytes of the codes of the discrete or integrated transmit remote control circuit 25, which controls the remote control circuit 25 via the driver 20. The electrical signals coming from it control via the preamplifier 26 through the amplifiers 27 and 28 the IR transmitter diode 6 for the scattering IR pulses and the IR transmitter diode 5 for the focused IR pulses, which simultaneously generate the same pulses The pulses of the IR transmitter diode 6 generate electrical signals in the IR receiver diode 9 for the scattering IR pulses of the target device 11, which signals are transmitted via the preliminary

REPLACEMENT LEAF stronger 31 pass the analog switch 33 controlled by the mono-flop 35 and control the remote control circuit 34, the output signal of which increments the shot counter 37. After the pulse time of the mono-flop 22 of the firearm 17, the pulses of the transmitter diode 6 end and the high / low edge of the output signal of the remote control circuit 34 of the target device 11 drives the negator 40, whose output signal has the low / high edge the mono-flop 35 starts, the outputs Q and Q 'negate switch 33 switch. Simultaneously after the pulse time of the mono flop 22 of the firearm 17 has elapsed, the low / high edge of the negated Q output starts the mono flop 23. The Q output of the mono flop 23 generates a pulse with a duration of at least 2 Byte of the codes of the transmitter remote control circuit 25, which controls the remote control circuit 25 via the driver 21. Their signals control via the preamplifier 26 through the amplifiers 27 and 28, the transmitter diodes 6 and 5, which simultaneously generate the same IR pulses.

The focused pulses of the transmitter diode 5 generate electrical signals when they pass through the openings of the target points 10.1 to 10.8, the filters 16.1 to 16.8 in the receive diodes 14.1 to 14.8 of the target device 11. They pass through the preamplifier 31 to the switch 33 switched by the mono-flop 35 and control the receive remote control circuit 34, the output signal of which increments the hit counter 36.

SPARE BLADE

Claims

Claims

1. Light beam gun with aiming device, in which light-sensitive sensors are connected via a light beam with the aid of a gun-like aiming device, which register hits, characterized in that in the firearm (17) two transmitting diodes (5; 6) for Infrared (IR) beams are arranged, of which, controlled by a transmitter remote control circuit (25), which emits one (5) focused, the other (6) scattering IR pulses, each of which is generated by receiving diodes (14; 9 ) generate electrical signals in the target device (11) and actuate shot (37) and hit counter (36) via a remote control circuit (34).

2. Firearm according to claim 1, characterized in that it generates time-shifted IR individual pulses by actuating a micro switch (15) by means of the trigger device (12), which controls a mono-flop (22), with the pulse on a driver (20) generates a discrete or integrated transmit remote control circuit (25), electrical signals which pass through an analog switch (29) via a preamplifier (26) and control the IR transmitter diode (5) through an amplifier (28), the duration of which is limited by the pulse of a mono-flop (22) which, after its pulse time has elapsed, drives a mono-flop (23), the pulse of which generates the remote control circuit (25) via a driver (21) which pass through the preamplifier (26) the switch (29) switched by an OR gate (52) and a negator (30) and by an amplifier (27) an IR transmitter diode (6) for the scattering ones Control IR pulses, the duration of which is determined by the pulse of the mono flop (23) is limited.

REPLACEMENT LEAF

3. Firearm according to claim 1, characterized in that it simultaneously generates the same IR multiple pulses by actuating the micro switch (15) by means of the trigger device (12), which controls the mono-flop (22), with its pulse via the driver (20) generates the discrete or integrated transmit remote control circuit (25) electrical signals which control the transmit diodes (6; 5) via the preamplifier (26) through the amplifiers (27; 28), which are simultaneously the same Generate pulses, the duration of which is limited by the pulse of the mono-flop (22), which drives the mono-flop (23) after its pulse time has elapsed, with the pulse of the driver (21) the remote control circuit (25) electrical signals generated by the preamplifier (26) by the amplifier

(27; 28) control the transmitter diodes (6; 5), which simultaneously generate the same IR pulses, the duration of which is limited by the pulse of the mono-flop (23).

4. Firearm according to claim 2, characterized in that by means of microswitches (18.1.1 or 18.1.2) with the help of the mono-flop (48) and the driver (45.1) as well as microswitches (18.2 to 18.n) and Trei¬ bern (45.2 to 45.n) the remote control circuit (25) generates electrical signals which pass through the preamplifier (26) through the switch (29) switched by the OR gate (52) and the negator (30) and through the Amplifiers (27) control the transmitting diode (6), the pulses of which generate electrical signals for the scattering pulses in an IR receiving diode (9) installed in the target device (11), which signals generate a receiving signal via the preamplifier (31). Activate remote control circuit (34), with whose output signals the pulse generator (43) is started and n-functions are called.

REPLACEMENT LEAF

5. Firearm according to claim 3, characterized in that by means of the microswitch (18.1.1 or 18.1.2) with the aid of the mono-flop (48) and the driver (45.1) and the microswitch (18.2 to 18.n) and the Driver (45.2 to 45.n) the remote control circuit (25) generates electrical signals which control the transmit diodes (6; 5) via the preamplifier (26) through the amplifiers (27; 28), the pulses of which in the target device (11) installed receiving diodes (9; 14) generate electrical signals which are routed via the preamplifier (31; 32) to the analog switch (33), which, controlled by a mono-flop (35), is generated by the focused IR -Impulses generated electrical signals blocks, while it lets the electrical signals generated by the scattering IR pulses pass to the receiving remote control circuit (34), with whose output signals the pulse generator (43) is started and n functions are called up.

6. Target device according to one of claims 1 to 5, characterized in that it is equipped for receiving temporally offset IR individual pulses with a discrete or integrated receive remote control circuit (34) which, when the individual pulse of the transmitter diode ( 5) one of the IR receiving diodes (14.1 to 14.n) controlled by the pulse generator (43) and the selection device (42), whose electrical signals are controlled via the preamplifier (32), has hit the hit counter (36 ) incremented, the subsequent individual pulse of the transmitting diode (6) in the receiving diode (9) generates electrical signals which control the remote control circuit (34) via the preamplifier (31), the output signal of which increments the shot counter (37).

REPLACEMENT LEAF

7. Aiming device according to one of claims 1 to 5, characterized in that it is equipped with a discrete or integrated receiving remote control circuit (34) for receiving the same IR multiple pulses at the same time, which when the scattering pulses of the firearm (17 ) have generated electrical signals, which are controlled by the preamplifier (31) and the switch (33), the output signal of which increments the shot counter (37) and, after the scattering pulses have elapsed, the high / low edge of the output signal a negator (40) controls, whose output signal starts the mono-flop (35) with the low / high edge, whose outputs Q and Q ¹ negate switch the switch (33) via which the electrical coming from the preamplifier (32) Signals, when the focused pulses of the transmitter diode (5) have hit one of the receive diodes (14.1 to 14.n) controlled by the pulse generator (43) and the selection device (42), the remote control circuit (34 ), whose output signal increments the hit counter (36) and the mono-flop (35) switches the switch (33) back after its pulse time has expired.

8. Aiming device according to one of claims 6 and 7, characterized in that the target points (10.1 to 10.n) of the target device (11) with openings in the diameter selectable in the front plate (8) are provided, through which the Light rays emerge from the light sources (13.1 to 13.n) controlled by the pulse generator (43) and the selection device (42), through which the focused single or multiple pulses of the firearm (17) pass through the filters (16.1 to 16.n. ) hit the receiving diodes (14.1 to 14.n), which were activated by the pulse generator (43) and the selection device (42).

REPLACEMENT LEAF

9. Aiming device according to one of Claims 6 and 7, characterized in that the 1 to n output signals of the pulse generator (43) are passed to the inputs (El to En) of the selection device (42), the inputs (El to En) are selectively electrically connected to the outputs (AI to An) of the selection device (42) by means of suitable materials or components, so that the activation of the light sources (13.1 to 13.n) and the receiving diodes (14.1 to 14.) of the permanently installed

Target points (10.1 to 10.n) of the target device (11) can be selected.

- 6 sheets of drawings -

REPLACEMENT LEAF