KR101214529B1 - Optical fiber light guide type laser transmitter and align method thereof - Google Patents

Abstract

The optical fiber-based laser beam launcher of the present invention comprises: a light source comprising an infrared laser diode for emitting an infrared laser beam and a visible light laser diode for emitting a visible laser beam; An optical fiber laser beam alignment unit of a V / U block connected to the light source and guiding the laser beam such that the traveling direction of the infrared laser beam and the traveling direction of the visible light laser beam coincide with each other; And a lens for advancing the visible light laser beam to a visually identifiable distance and spreading the detection width to the killing distance of the firearm, the central axis of the infrared laser beam through the optical fiber of the optical fiber laser beam alignment unit. And the central axis of the visible light laser beam is aligned in parallel, so that the orientation of the infrared laser beam which is not visible to the naked eye can be visually confirmed through the visible light laser beam to facilitate alignment with the firearm.

Description

Optical fiber light guide type laser transmitter and align method

The present invention relates to an optical fiber-based laser beam launcher and a method for aligning the optical fiber-based laser beam launcher, and more specifically, by configuring the infrared laser beam and the visible light laser beam to proceed in parallel with each other by using an optical fiber The present invention relates to an optical fiber-based laser beam launcher that can easily and quickly perform zero aiming without using a zero point aiming machine and a method of aligning the optical fiber based laser beam launcher.

In general, simulation training is conducted using a laser beam in military training. Such engagement training is performed by simulating the same battlefield effects and weapon performance as actual combat.

In order to simulate real combat, instead of using bullets, a launcher that emits a laser beam is used and a sensor is used to monitor it. The equipment used in the simulation is typically a training weapon that simulates a real firearm such as a personal firearm, a common firearm, an antitank firearm, an anti-aircraft firearm, and a laser beam emitted from a training firearm mounted on equipment such as a trainer or a vehicle. There is a sensor to detect.

Recently, in the military, small arms transmitters (hereinafter referred to as SATs) attached to small guns and other projectile weapons to fire laser beams instead of bullets and a sensing device that can detect the hit by detecting the laser beams ( Introduced the Multiple Integrated Laser Engagement System (hereinafter referred to as the Miles System), which consists of an optical detector, to conduct combat exercises that are similar to real life.

The operation of the Miles system is briefly described as follows.

When a soldier aims at a target and triggers a personal or common weapon, a grenade is fired, and the generated sound or light is detected by an acoustic sensor or a light receiving sensor, which is an internal device of the SAT, to activate an infrared laser diode also mounted on the SAT. The pulsed infrared laser beam is then emitted from the aiming target. If the fired laser beam hits some of the sensing elements of each soldier's helmet and body harness, or of a sensing device mounted outside the target, such as a tank, the laser signal incident on the detected sensing element After being converted into an electrical signal, it is delivered to the MPU (Microprocessor Unit, hereinafter referred to as MPU) embedded in the sensor module unit. After detecting the signal as a shot signal, the sensing device MPU can visually and acoustically indicate whether or not the target is hit by a beacon mounted on the soldier's body according to a predetermined logic, and at the same time, stop the operation of the soldier's projectile SAT. . In addition, by using a communication module of the sensing unit module unit to transmit a signal to the central control system located in the remote is configured to control whether or not the hit.

Recently, survival games have become increasingly popular not only for the military but also for students, young general people, and the like, and they have used small bullets filled with paint, but now, the number of game sites using a laser system using a laser beam is gradually increasing.

In simulated combat training or survival games, firearms equipped with laser launchers (firearms or simulated firearms) are essential.

1 shows a laser beam launcher mounted to a firearm.

Referring to FIG. 1, the conventional laser beam launcher 12 is mounted to the barrel of the firearm 10.

The laser beam emitted from the laser beam launcher 12 must reach the same position as the target to which the bullet of the firearm 10 reaches. Therefore, the direction in which the bullet of the firearm 10 travels and the direction in which the laser beam of the laser beam launcher 12 travels must coincide. The central axis a of the laser beam launcher 12 and the firearm 10 It is necessary to align the central axis (b) of the muzzle direction so that they are parallel to each other.

Conventionally, a zero aimer was used to align the laser beam launcher 12. The zero aimer is not only expensive equipment, but also requires considerable time for installation, and the method of use is not simple and sensitive to the surrounding environment. There was a malfunction.

The present invention is to solve the above problems, by using the optical fiber and the infrared laser beam and visible light laser beam is configured to proceed in parallel with each other, the laser launcher to the barrel of the firearm without using a separate zero aimer An object of the present invention is to provide a fiber-based laser beam launcher that can accurately and quickly align and a method of aligning the fiber-based laser beam launcher.

In order to achieve the above object, the optical fiber based laser beam launcher according to the first example of the present invention includes a light source comprising an infrared laser diode for emitting an infrared laser beam, and a visible light laser diode for emitting a visible laser beam; An optical fiber laser beam alignment unit of a V / U block connected to the light source and guiding the laser beam such that the traveling direction of the infrared laser beam and the traveling direction of the visible light laser beam coincide with each other; And a lens for advancing the visible light laser beam to a visually identifiable distance and spreading the detection width to the killing distance of the firearm, the central axis of the infrared laser beam through the optical fiber of the optical fiber laser beam alignment unit. And the central axis of the visible light laser beam is aligned in parallel, so that the orientation of the infrared laser beam, which is not visible to the naked eye, can be visually confirmed through the visible light laser beam to facilitate alignment with the firearm.

The lens may be either a bulk lens or an optical fiber coupled lens.

On the other hand, the optical fiber-based laser beam launcher according to a second example of the present invention includes a light source consisting of an infrared laser diode for emitting an infrared laser beam, and a visible light laser diode for emitting a visible laser beam; A 2 × 1 optical fiber laser beam alignment unit connected to the light source and guiding the laser beam such that the traveling direction of the infrared laser beam and the traveling direction of the visible light laser beam coincide with each other; And a lens for advancing the visible light laser beam to a visually identifiable distance and diffusing a detection width to a killing distance of the firearm, the center of the infrared laser beam through the optical fiber of the optical fiber laser beam alignment unit. The axis and the central axis of the visible laser beam are aligned in parallel so that the orientation of the infrared laser beam, which is not visible to the naked eye, can be visually confirmed through the visible laser beam to facilitate alignment with the firearm.

The lens may be any one of a bulk lens and an optical fiber coupled lens.

The optical fiber of the optical fiber laser beam alignment unit may be a single or multi-mode optical fiber, an optical fiber converting from a multi-mode to a single mode, a photonic crystal fiber having a single mode characteristic of a core size, and the material may be made of silica or plastic.

On the other hand, the optical fiber-based laser beam launcher according to the third embodiment of the present invention includes a light source consisting of an infrared laser diode for emitting an infrared laser beam, and a visible light laser diode for emitting a visible laser beam; An optical filter passing through the laser beam of the infrared laser diode and reflecting the laser beam of the visible light laser diode; A housing fixing the light source and the optical filter; A ferrule combining and arranging a laser beam of the infrared laser diode and a laser beam of the visible light laser diode; An optical fiber-coupled lens for advancing the visible laser beam to a visually identifiable distance and spreading the detection width to the killing distance of the firearm; wherein the central axis of the infrared laser beam and the center of the visible laser beam are provided. The axes are aligned so that the orientation of the infrared laser beam, which is not visible to the naked eye, can be visually confirmed through the visible light laser beam to facilitate alignment with the firearm.

The ferrule has a built-in optical fiber and is detachably installed on the housing and the optical fiber coupled lens.

On the other hand, the optical fiber based laser beam launcher alignment method according to the invention comprises the steps of attaching a laser beam launcher to the barrel of the firearm; Switching the laser beam launcher to a visible light laser beam firing mode; Aiming the aiming line of the firearm at a target point dedicated to zero shooting; Firing the visible light laser beam; Matching a line of sight laser beam with the aiming line of the firearm and the zero target shooting target; Checking whether they matched; If it does not match, adjusting the up, down, left and right directions of the laser beam launcher; And if so, terminating the alignment of the laser beam launcher; And switching to an infrared laser beam firing mode.

As described above, the present invention is a structure in which the optical fiber-based visible light and infrared laser beams are aligned, and additionally, laser beam alignment between the firearm and the laser beam launcher can be easily performed without using an expensive zero aimer. This allows zero aiming at low cost and can also be used during the day, providing an excellent effect of aligning the line of sight quickly and accurately without being constrained by time and place.

1 shows a laser beam launcher mounted to a firearm
Figure 2 is a schematic view showing a fiber-based laser beam launcher according to the present invention
3A is a diagram for explaining an optical fiber based laser beam launcher according to the first example of the present invention.
Figure 3b is a longitudinal cross-sectional view of the optical fiber laser beam alignment unit of the V block in the optical fiber based laser beam launcher according to the first example of the present invention
3C is a longitudinal sectional view of the optical fiber laser beam alignment unit of the U block in the optical fiber based laser beam launcher according to the first example of the present invention;
4A and 4B are diagrams for describing an optical fiber based laser beam launcher according to a second example of the present invention.
5 is a view for explaining an optical fiber based laser beam launcher according to a third example of the present invention.
6 is a flowchart showing a method of aligning an optical fiber based laser beam launcher according to the present invention.

Hereinafter, an alignment method of an optical fiber based laser beam launcher and an optical fiber based laser beam launcher according to the present invention will be described in detail with reference to the accompanying drawings.

2 is a block diagram showing an optical fiber based laser beam launcher according to the present invention, Figure 3a is a view for explaining an optical fiber based laser beam launcher according to a first example of the present invention, Figure 3b is a first view of the present invention Fig. 3C is a longitudinal sectional view of the optical fiber laser beam aligning unit of the V block in the optical fiber based laser beam launcher according to the example, and Fig. 3C shows the optical fiber laser beam alignment of the U block in the optical fiber based laser beam launcher according to the first example of the present invention. This is a longitudinal cross section of the unit.

Referring to the drawings, the optical fiber based laser beam launcher 100 according to the first embodiment of the present invention is an infrared laser diode 111 for emitting an infrared laser beam, and a visible light laser diode for emitting a visible laser beam ( A light source 110 composed of 113; An optical fiber laser beam alignment unit 120 connected to the light source 110 and guiding the laser beam so that the traveling direction of the infrared laser beam and the traveling direction of the visible light laser beam coincide with each other; And a lens 130 for advancing the visible light laser beam to a visually identifiable distance and spreading the detection width to the kill distance of the firearm 12.

The feature of the optical fiber-based laser beam launcher 100 according to the first example of the present invention is the central axis of the infrared laser beam and visible light through the glass fiber 121 of the optical fiber laser beam alignment unit 120 of the V / U block. Since the central axis of the laser beam is aligned in parallel, the orientation of the infrared laser beam, which is not visible to the naked eye, can be visually confirmed through the visible light laser beam, so that the alignment with the firearm 12 can be easily performed.

The lens 130 may be configured as a bulk lens (see FIG. 3A), or may be configured as an optical fiber coupling lens (not shown).

The optical fiber of the optical fiber glass block 140 is a single or multi-mode optical fiber, a taper optical fiber having a characteristic of converting from a multiple mode to a single mode, a photonic crystal fiber having a large core size and a single mode characteristic, and a material of silica or plastic It may be any one produced.

The operating principle of the optical fiber based laser beam launcher 100 according to the first example of the present invention configured as described above will be briefly described.

The infrared laser beam emitted from the light source 110 travels along the path of the optical fiber 121, and the sensing width propagates uniformly to the killing distance of the firearm 12 through the lens 130. The visible light laser beam emitted from the light source 110 travels along the traveling path of the optical fiber 121 and propagates through the lens 130 toward the zero-only target, which is the firing target point of the firearm 12. Since the infrared laser beam and the visible laser beam proceed through the optical fiber 121, the two laser beams are aligned and propagate on the same axis. Therefore, it is possible to easily check whether the aiming line of the firearm 12 and the zero-only target site through the visible light laser beam visually identifiable without using a separate zero aimer.

4A and 4B are diagrams for describing an optical fiber based laser beam launcher according to a second example of the present invention.

The optical fiber based laser beam launcher 200 according to the second example of the present invention is a light source composed of an infrared laser diode 211 for emitting an infrared laser beam and a visible light laser diode 213 for emitting a visible laser beam. 210; A 2 × 1 optical fiber laser beam alignment unit 220 connected to the light source 210 and guiding the laser beam such that the traveling direction of the infrared laser beam and the traveling direction of the visible laser beam coincide with each other; And a lens 230 for advancing the visible light laser beam to a visually identifiable distance and diffusing a detection width to a kill distance of the firearm 12, wherein the optical fiber laser beam alignment unit 220 is provided. The central axis of the infrared laser beam and the central axis of the visible laser beam are aligned in parallel through the optical fiber of the optical fiber, so that the orientation of the infrared laser beam, which is indistinguishable to the naked eye, can be visually confirmed through the visible laser beam. And to facilitate alignment with the.

The lens 230 may be any one of a bulk lens (see FIG. 4A) and an optical fiber coupling lens (see FIG. 4B).

The optical fiber of the optical fiber glass block 220 may be a single or multi-mode optical fiber, a taper optical fiber having a characteristic of converting from a multiple mode to a single mode, a photonic crystal fiber having a large core size and a single mode characteristic, and a material of silica or plastic. It may be any one produced.

The operating principle of the optical fiber based laser beam launcher 200 according to the second embodiment of the present invention configured as described above will be briefly described.

The infrared laser beam emitted from the light source 210 proceeds along the path of the optical fiber of the optical fiber laser beam alignment unit 220, and has a constant detection width through the lens 230 to the kill distance of the firearm 12. Spread.

The visible light laser beam emitted from the light source 210 travels along the path of the optical fiber, and passes through the lens 230 and propagates toward the zero-only target, which is the firing target point of the firearm 12.

The infrared laser beam and the visible light laser beam propagate through the optical fiber of the optical fiber laser beam alignment unit 220, so that the two laser beams are aligned and propagate on the same axis. Therefore, it is possible to easily check whether the aiming line of the firearm 12 and the target line dedicated to the zero point through the visible light laser beam visually identifiable without using a separate zero aimer.

On the other hand, the optical fiber-based laser beam launcher 300 according to the third embodiment of the present invention is composed of an infrared laser diode 311 for emitting an infrared laser beam, and a visible light laser diode 313 for emitting a visible laser beam A light source 310; An optical filter (320) passing through the laser beam of the infrared laser diode and reflecting the laser beam of the visible light laser diode; A housing (330) fixing the light source (310) and the optical filter (320); A ferrule 340 for coupling and aligning the laser beam of the infrared laser diode and the laser beam of the visible light laser diode; And a fiber-optic coupled lens 350 for advancing the visible light laser beam to a visually discernible distance and spreading the detection width to the killing distance of the firearm 12, including the central axis and the visible of the infrared laser beam. The central axis of the beam laser beam is aligned so that the orientation of the infrared laser beam, which is not visible to the naked eye, can be visually confirmed through the visible laser beam to facilitate alignment with the firearm 12.

The optical fiber-based laser beam launcher 300 according to the third embodiment of the present invention is an infrared laser diode 311 that emits an infrared laser beam, an optical fiber that is provided in a traveling direction of the laser beam and spreads the detection width of the infrared laser beam to be constant. Combination lens 350, the optical filter 320 is disposed in the direction of the laser beam, these are all assembled to the housing 330. Here, the infrared laser diode 311 emits an infrared laser beam. Infrared laser diodes are lasers that emit light in the wavelength range of 0.8 to 1,000 μm, with good monochromaticity and intensity. A representative example is a gallium-arsenic semiconductor laser having a wavelength of 0.9 μm.

The optical fiber coupling lens 350 is manufactured through a known technique and spreads and directs the infrared laser beam transmitted from the infrared laser diode 311 and transmitted through the optical filter 320 toward the firing target point of the firearm.

The optical filter 320 has a characteristic of separating one beam into two or more beams, and reflectance and transmittance may be adjusted differently according to the length of the wavelength. This is a known technique and a detailed description thereof will be omitted.

As shown in FIG. 5, the optical filter 320 has a first surface 321 and a second surface 322 which are in contact with each other, and an infrared laser beam is incident on the first surface 321. In this case, excellent transmittance (approximately 90% or more) to the infrared laser beam is maintained, and when the visible light laser beam is incident on the second surface 322, it is excellent reflectivity (approximately 90 degrees) to the visible light laser beam. % Or more) is maintained.

Different characteristics of the first side 321 and the second side 322 of the optical filter 320 are derived from the difference in the coating. Since the manufacturing method for this corresponds to a known technique, a detailed description thereof will be omitted.

In general, the housing 330 may be manufactured by extrusion molding, injection molding, or the like, and various molding methods may be used separately.

Positions of the infrared laser diode 311 and the visible light laser diode 313 for emitting the visible light laser beam may be switched with each other according to design conditions.

The operating principle of the optical fiber based laser beam launcher 300 according to the third example of the present invention configured as described above will be briefly described.

The infrared laser beam irradiated from the infrared laser diode 311 is incident on the first surface 321 of the optical filter 320. The incident infrared laser beam passes through the first surface 321 of the optical filter 320 and spreads through the optical fiber coupling lens 350 to travel toward the directing point of the laser beam launcher. The infrared laser beam passing through the optical fiber coupling lens 350 reaches a directing point.

The visible light laser beam irradiated from the visible light laser diode 313 is incident on the second surface 322 of the optical filter 320. The incident visible light laser beam is reflected with respect to the second surface 322 of the optical filter 320. The reflected visible laser beam passes through the optical fiber coupling lens 350 toward the directing point of the laser launcher.

The traveling direction of the infrared laser beam emitted from the infrared laser diode 311 and transmitted through the first surface 321 and the visible light laser beam emitted from the visible light laser diode 313 and reflected by the second surface 322. The direction of travel coincides with each other.

In other words, the directing point at which the infrared laser beam reaches and the directing point at which the visible light laser beam arrives coincide with each other. Since the width of the infrared laser beam at the final reaching point is wider than the width of the visible light laser beam at the directing point, The central axis of the infrared laser beam at the directing point coincides with the central axis of the visible light laser beam.

The orientation of the infrared laser beam, which is not visible to the naked eye, can be visually confirmed through the visible light laser beam so that alignment with the firearm 12 (see FIG. 1) can be easily performed.

On the other hand, Figure 6 is a flow chart showing a fiber-based laser beam launcher alignment method according to the present invention.

Referring to Figure 6, the optical fiber based laser beam launcher alignment method according to the present invention comprises the steps of attaching a laser beam launcher to the barrel of the firearm (S10); Converting the laser beam launcher into a visible light laser beam firing mode (S20); Aiming the aiming line of the firearm at a target shooting target for zero shooting (S30); Firing the visible light laser beam (S40); Matching a visible laser beam with the aiming line of the firearm and the target shooting target target (S50); Checking whether it is matched (S60); If it does not match, adjusting the up, down, left and right directions of the laser beam launcher and ending the alignment of the laser beam launcher (S70); If it matches, terminating the alignment of the laser beam launcher (S80); And switching to an infrared laser beam firing mode (S90).

As such, the rights of the present invention are not limited to the above-described embodiments, but are defined by the claims, and various modifications can be made within the scope of the claims by those skilled in the art. It is self evident.

100: optical fiber based laser beam launcher
110: light source
111: infrared laser diode
113: visible light laser diode
120: fiber laser beam alignment unit
121: optical fiber
130: lens

Claims (9)

delete delete delete delete delete A light source 310 composed of an infrared laser diode 311 for emitting an infrared laser beam and a visible light laser diode 313 for emitting a visible laser beam;
An optical filter (320) passing through the laser beam of the infrared laser diode and reflecting the laser beam of the visible light laser diode;
A housing (330) fixing the light source (310) and the optical filter (320);
A ferrule 340 for coupling and aligning the laser beam of the infrared laser diode and the laser beam of the visible light laser diode;
And an optical fiber coupling lens 350 for advancing the visible light laser beam to a visually identifiable distance and spreading the detection width to the killing distance of the firearm 12.
Since the central axis of the infrared laser beam and the central axis of the visible light laser beam are aligned, the orientation of the infrared laser beam, which is indistinguishable to the naked eye, can be visually confirmed through the visible light laser beam, thereby facilitating alignment with the firearm 12. And a fiber-based laser beam launcher, configured to cause The method according to claim 6,
The ferrule (340) is an optical fiber is built-in, the optical fiber-based laser beam launcher, characterized in that installed detachably to the housing (330) and the optical fiber coupled lens (350). The method of claim 7, wherein
The optical fiber of the ferrule 340 is a single- or multi-mode optical fiber, a taper optical fiber having a characteristic of converting from a multimode to a single mode, a photonic crystal fiber having a large core size and a single mode characteristic, and a material of silica or plastic Fiber-based laser beam launcher, characterized in that can be manufactured as one. delete

Images