KR20200019157A - Dot sighting device having a beam splitter - Google Patents

Abstract

The present invention relates to a dot sight apparatus including a beam splitter. According to the present invention, the dot sight apparatus includes: a dot indication creation part placed on one side of the inner edge surface of a body tube to provide a dot indication beam; a reflector placed on a position of the inner edge surface of the body tube, which is opposite to the dot indication creation part, to reflect the dot indication beam provided from the dot indication creation part; and a beam splitter including an inclined surface reflecting or transmitting the dot indication beam and placed in a space between the reflector and the dot indication creation part. The inclined surface of the beam splitter reflects the dot indication beam reflected from the reflector to a user, and transmits incident light provided from a target in front of the body tube.

Description

Dot Sight Device with Beam Splitter {DOT SIGHTING DEVICE HAVING A BEAM SPLITTER}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a dot site apparatus having a beam splitter, and more particularly, to a dot site apparatus capable of providing color close to a natural state while improving parallax.

In the conventional dot sight aiming device, since the optical axis of the reflecting mirror of the collimator is inclined with the optical axis of the barrel, the optical axis of the reflecting mirror of the aiming mirror has a large parallax compared to the optical system coinciding with the optical axis of the barrel, thereby securing an area within the allowable parallax. In order to achieve this, there is a disadvantage in that the dot site is configured by making the distance between the dot target and the reflector farther or making the diameter of the effective reflector smaller.

1 is a cross-sectional view schematically showing a conventional monocular dot sight aiming device.

As shown in FIG. 1, the conventional dot sight aiming device 1 is composed of a light emitting element such as an LED and a mask having a light emitting part having a dot target shape positioned in front of the light emitting element, and is fixed to one side of the inner circumferential surface of the barrel. A target generator 5 and a reflector 7 fixed inside the tip portion facing the target of the barrel so as to reflect the light irradiated from the dot target generator toward the user and allow incident light provided from the target to pass therethrough; And a fixing grill 11 for fixing the sight aiming device 1 to the rifle.

This conventional dot sight aiming device 1 aims by matching a dot, which is a virtual image of a dot target, reflected through a reflector 7 to an aiming target that is stared at no magnification through the protective window 9. Since this is achieved, the accuracy of the accuracy of the aiming target can be improved.

Specifically, the dot sight beam irradiated from the dot sight generator 5 located inside the dot sight device 1 is reflected by the reflector 7 and is incident in parallel to the eyes of the observer. This parallelism is set so as to coincide with the barrel firing axis of the barrel. If the parallelity of the dot sight device 1 and the bullet firing axis of the barrel barrel do not coincide, the user does not hit the aiming target even if the user matches the virtual image of the dot target irradiated by the dot sight generator 5 with the shooting aiming target. The barrel alignment terminals 3, which have vertical and horizontal adjustment functions, should be operated so that the optical axis of the barrel matches the barrel firing axis of the barrel.

As shown in FIG. 1, the conventional dot sight is arranged so that the dot target generator 5 is disposed at the edge of the barrel so that the view of the target object seen through the barrel is not disturbed.

The parallax of the light beam around the reflector 7 decreases as the angle A1 formed between the optical axis C1 of the barrel 10 and the optical axis C2 of the reflector 7 decreases (see FIG. 2).

Therefore, the structure in which the optical axis C1 of the barrel 10 and the optical axis C2 of the reflector 7 are arranged side by side (or coincident with each other) as shown in FIG. Since the amount of parallax is much smaller than that of the arrangement in which the optical axis C1 of (10) and the optical axis C2 of the reflector 7 are inclined at a constant angle A1, the arrangement structure of FIG. Compared with 2 (a), the distance between the dot target generator 5 and the reflector 7 can be made shorter, so that the size of the dot sight equipment can be reduced.

However, the arrangement structure as shown in FIG. 2 (b) is not adopted because the dot target generator 5 is disposed at the center of the dot sight barrel 10 on the optical path and acts as an obstacle to observation of an external target point. .

In addition, the reflector 7 is coated so as to reflect light rays in the wavelength band of the dot target generator. This coating reflects the light of the wavelength band of the dot sight generator 5 on the outer surface of the reflector 7, and the reflected light is more prominent than the reflected light of other objects in the surroundings. There is a problem that can be exposed to. For example, if the light source of the dot target generator 5 uses a 650 nm (red) LED, the light reflecting the coating conditions of the reflector among the external light incident on the outer surface of the reflector is reflected, so that the entire reflector is close to red. Since the color is exposed to the other party, the user's position may be easily detected.

Accordingly, an object of the present invention is to solve such a conventional problem, and by reducing the parallax as well as miniaturization of the dot site apparatus by arranging the optical axis of the dot target generator and the optical axis of the reflecting mirror on the same line. A dot site apparatus having a beam splitter is provided.

Another object of the present invention is to provide a dot-site apparatus having a beam splitter capable of preventing the dot-target beam provided from the dot-target generator from being reflected in the target direction.

According to the present invention, the object is a dot target generating unit disposed on one side of the inner peripheral surface of the barrel to provide a dot target beam; and the dot target disposed on the opposite side of the dot target generating unit of the inner peripheral surface of the barrel. A reflector reflecting the dot sight beam provided from the generator; And a beam splitter configured to reflect or transmit a dot target beam and disposed in a space between the dot target generator and the reflector, wherein the inclined surface of the beam splitter is a dot target beam reflected from a reflector. Is reflected by the user, and the incident light provided from the target in front of the barrel is transmitted by the dot site apparatus with the beam splitter.

According to the dot-site apparatus provided with the beam splitter of the present invention, the optical axis of the dot target generator and the optical axis of the reflecting mirror are arranged on the same line, thereby reducing parallax and miniaturizing the dot-site apparatus.

In addition, it is possible to prevent the dot target beam provided from the dot target generator from being reflected in the target direction.

1 is a cross-sectional view schematically showing a conventional monocular dot sight aiming device,
2 is a cross-sectional view showing the relationship between the optical axis of the reflector of the conventional dot sight device and the optical axis of the barrel;
3 is a schematic configuration diagram of a dot sight device having a beam splitter according to a first embodiment of the present invention;
4 is a schematic configuration diagram showing another example of the beam splitter of the dot sight apparatus according to the first embodiment of the present invention;
5 is a cross-sectional view showing various modifications of the reflector according to the dot sight device with the beam splitter of the present invention;
6 is a schematic configuration diagram of a dot sight device having a beam splitter according to a second embodiment of the present invention;
7 is a schematic structural diagram showing a configuration of a beam splitter according to a second embodiment of the present invention;
8 is a schematic configuration diagram of a dot sight device having a beam splitter according to a third embodiment of the present invention;
9 is a view for explaining internal total reflection,
10 is a view for explaining an example of internal total reflection prevention processing;
11 is a schematic structural diagram of a dot site apparatus having a beam splitter according to another embodiment of the present invention.

Prior to the description, in the various embodiments, components having the same configuration will be representatively described in the first embodiment using the same reference numerals, and in other embodiments, different configurations from the first embodiment will be described. do.

Hereinafter, a dot site apparatus having a beam splitter according to a first embodiment of the present invention will be described in detail with reference to the accompanying drawings.

3 is a schematic structural diagram of a dot site apparatus having a beam splitter according to a first embodiment of the present invention.

The dot-site apparatus having the beam splitter according to the first embodiment of the present invention as shown in the drawings is arranged on one side of the barrel 110, which is arranged in parallel with the barrel on the upper side of the firearm, and the inner peripheral surface of the barrel 110. The dot target generator 120 and the inner surface of the barrel 110 are disposed opposite the dot target generator 120 to provide a dot target beam provided from the dot target generator 120. The reflector 130 reflects the light, and is disposed between the dot target generator 120 and the reflector 130 to transmit light of the dot target provided from the dot target generator 120 toward the reflector 130. And a beam splitter (140) having an inclined surface (141) having a coating surface for reflecting the light of the dot target which is reflected back from the reflector (130) toward the beam splitter (140) and generates the dot target. Disposed between the unit 120 and the beam splitter 140 1 and polarizing unit 151 is configured by a second polarizer 152 disposed on the barrel 110, internal space between the beam splitter 140 and the targets.

The dot target generator 120 may include a mask or a reticle having a light emitting device such as an LED and a light transmitting part having a dot target shape positioned in front of the light emitting device.

The reflector 130 is disposed on the opposite side of the dot target generator 120 of the inner peripheral surface of the barrel 110 so that the optical axis is located on the same line as the optical axis of the dot target generator 120, The dot sight beam reflected at 130 is configured to be provided as a virtual image to the user, and in the present embodiment, a concave flat lens of negative refractive power having a single reflective surface is applied.

The beam splitter 140 is disposed between the dot target generator 120 and the reflector 130 to transmit a dot target beam that is provided toward the reflector 130 from the dot target generator 120 and passes through the reflector. The dot sight beam reflected back at 130 serves to reflect toward the user. The beam splitter 140 may be configured as a beam splitting prism in which two rectangular prisms are combined. That is, when A% reflective coating is applied to one of the two inclined surfaces 141 which are the boundary surfaces of two rectangular prisms, the beam splitter transmits (100-A)% of incident light provided to the beam splitter 140 and reflects A% ( 140). For example, when the 50% reflective coating is applied and then bonded, the beam splitter 140 transmits 50% and reflects 50%.

Meanwhile, as shown in FIG. 4, the beam splitter 140 is beam-separated and transmitted according to a transmission amount of a beam required on at least one surface, and beam separation is disposed between the dot target generator 120 and the reflector 130. It is also possible to comprise the flat plate 160.

The first polarizer 151 is disposed between the dot target generator 120 and the beam splitter 140, and the second polarizer 152 has a barrel between the beam splitter 140 and a target. 110) It is disposed in the interior space. In this case, the first polarizer 151 and the second polarizer 152 are formed of linear polarizers in which polarization directions are perpendicular to each other, or rotating polarizers in which rotation directions of polarizations are opposite to each other.

The operation of the first embodiment of the dot sight apparatus with the beam splitter described above will now be described.

As shown in FIG. 3, the dot target beam provided by the dot target generator 120 may be applied to the reflectance of the inclined surface 141 of the beam splitter 140 disposed in front of the dot target generator 120. Are reflected and transmitted accordingly. The dot target beam transmitted through the inclined surface 141 is reflected by the reflector 130 disposed on the opposite side of the dot target generating unit 120 and proceeds in the opposite direction, and the inclined surface 141 of the beam splitter 140 is provided. Reflected by and incident on the eyes of the user.

For example, when the inclined surface 141 has a coating surface that transmits 70% of the dot target beam provided by the dot target generation unit 120 and reflects 30% of the dot target beam, the reflector 13 may be 100%. Assuming reflection, about 21% of the light of the dot viewing beam is incident on the user.

On the other hand, since the reflected light reflected from the inclined surface 141 toward the target has passed through the first polarization part 151, the beam splitter 140 is set to be perpendicular or opposite to the polarization direction of the first polarization part 151. ) And the second polarizer 152 disposed between the target and the target. Therefore, the position of the user may not be exposed to the front counterpart by the reflected light reflected from the inclined surface 141 toward the target.

According to the first embodiment of the present invention, the optical axis of the reflector 130 is disposed to be orthogonal to the optical axis of the barrel 110, and the angle of 45 degrees at the position where the optical axis of the reflector 130 and the optical axis of the barrel 110 intersect. By arranging the beam splitter 140 having the inclined surface 141 which is inclined to the beams, the dot time beam reflected by the reflecting mirror 130 is connected to the optical axis of the barrel 110 by the inclined surface 141 of the beam splitter 140. It can be reflected in a parallel direction.

That is, since the optical axis of the reflector 130 may be obtained in parallel with the optical axis of the barrel 110, the parallax in the reflector 130 may be minimized. In particular, by excluding the reflector on the optical path between the user and the target, it is possible to prevent the loss of the amount of light caused by the incident light provided from the target through the reflector as in the prior art, and to prevent color damage caused by the reflector. In addition, by disposing the first polarizer 151 and the second polarizer 152, it is possible to prevent the user's position is exposed to the counterpart by the reflection on the outer surface of the reflector 130.

In addition, since the entire length of the barrel 110 can be designed to be short, there is an advantage that the size and weight of the device can be achieved.

Meanwhile, in the present exemplary embodiment, the beam splitter 140, the first polarizer 151, and the second polarizer 152 have been described as an example. However, a situation in which the position of the dot site user is exposed to the other party is allowed. In this case, the first polarizing unit 151 and the second polarizing unit 152 may be used in a state of being excluded.

Meanwhile, in the present embodiment, the reflector 130 is a concave single lens having a single reflecting surface. For example, the reflector 130 may be configured in various forms as shown in FIG. 5. That is, as shown in (a) of FIG. 5, the reflector is a doublet lens having a concave surface and having a reflective coating applied to any one of the first surface 131a and the second surface 132a to which the dot sight beam is incident. A singlelet which is 130a or is reflective coated on any one of the concave first surface 131b and the convex second surface 132b into which the dot sight beam is incident, as shown in FIG. 5B. The reflector 130b may be configured as a lens. In addition, as shown in FIG. 5C, the reflector 130c may be formed of a singlet lens having a flat surface and a second surface 132c having a convex surface on which the first surface 131c is incident. As shown in FIG. 5 (d), the first surface 131d on which the dot sight beam is incident is a flat surface, and the second surface 132d or the third surface 133d is a doublet coated with reflection coating. The reflecting mirror 130d can be configured. In addition, as shown in FIGS. 5C and 5D, when the first surfaces 131c and 131d on which the dot sight beam is incident are formed in a plane, the first surfaces 131c and 131d of the reflecting mirrors 130c and 130d. It may also be possible to construct an integral surface of the beam splitter 140 by bonding the opposite surface of the beam splitter 140 with the other side.

Next, a dot site apparatus having a beam splitter according to a second embodiment of the present invention will be described.

6 is a schematic structural diagram of a dot site apparatus having a beam splitter according to a second embodiment of the present invention.

In the dot-site apparatus having the beam splitter according to the second embodiment of the present invention as shown in FIG. 6, the beam splitter 140 'is formed of a polarization beam splitting prism (PBS) prism. A third polarization part 153 composed of a λ / 4 plate (Quater wave plate) is disposed between the beam splitter 140 'and the reflector 130, and the beam splitter facing the target. The second polarization part 152 composed of linear polarizers is disposed in front of 140 ', which is different from the first embodiment.

Here, the inclined surface 141 'of the beam splitter 140' made of the polarizing beam splitting prism reflects the polarization beam of the S wave component of the dot viewing beam (arrow) as shown in FIG. The polarization beam has a coating surface set to transmit, and the second polarization portion 152 disposed in front of the beam splitter 140 'is set to block the polarization beam of S wave component.

The coating surface of the inclined surface 141 reflects only a portion (for example, 60%) of the S wave component and transmits the remaining portion (for example, 40%), and sets the P wave component to transmit 100%. The wave P wave may be combined to make the total transmitted light amount 50% or more (for example, 70%).

The operation of the second embodiment of the dot sight apparatus with the beam splitter described above will now be described.

As shown in FIG. 6, the dot target beam irradiated from the dot target generation unit 120 is provided toward the inclined surface 141 'of the beam splitter 140' and includes a beam splitter made of a polarizing beam splitting prism ( 140 '), the inclined surface 141' is set to reflect the polarized beam of the S-wave component and transmit the polarized beam of the P-wave component, so that the P-wave component of the dot target beam provided toward the inclined surface 141 ' The polarization beam is transmitted toward the reflecting mirror 130 opposite the dot sight generator 120, and the polarization beam of the S-wave component is reflected toward the target.

The polarized beam of the P-wave component provided toward the reflector 130 passes through the λ / 4 wave plate 153 (λ / 4 wave plate) disposed between the beam splitter 140 'and the reflector 130 and polarizes in right direction. The beam is converted into a left circularly polarized beam, and is reflected by the reflector 130 and then passed through the λ / 4 wave plate 153 and the λ / 4 wave plate again to be converted into a S-wave polarized beam. Subsequently, the polarization beam of the S-wave component provided from the reflector 130 to the inclined surface 141 'of the beam splitter 140' is reflected toward the user at the inclined surface 141 '. Therefore, the user may aim to match the virtual image of the dot target provided from the dot target generator 120 and reflected by the reflector 130 onto the external target observed through the beam splitter 140 '.

Meanwhile, the dot target beam provided from the dot target generator 120 is reflected toward the target by the inclined surface 141 ′ positioned between the dot target generator 120 and the target to be observed by the counterpart. There is concern. However, according to the present exemplary embodiment, the polarization beams of the S-wave component reflected from the inclined surface 141 'toward the target are all blocked by the second polarization part 152 disposed in front of the beam splitter 140'. The target beam may be provided toward the target to prevent the user's location from being exposed to the opponent around the target.

According to the second embodiment of the present invention as described above, the beam splitter 140 'is formed of a polarizing beam splitting prism, so that the amount of light lost from the beam splitter 140' is lower than that of the beam splitter 140 in the first embodiment. Since it is small, it is possible to provide a clearer dot timeline to the user.

Next, a dot site apparatus having a beam splitter according to a third embodiment of the present invention will be described.

8 is a schematic structural diagram of a dot site apparatus having a beam splitter according to a third embodiment of the present invention.

In the dot-site apparatus having the beam splitter according to the third embodiment of the present invention as shown in FIG. 8, the beam splitter 140 'is made of a polarizing beam splitting prism (PBS prism), and the dot timetable is generated. A first polarizer 151 composed of a linear polarizer is disposed between the unit 120 and the beam splitter 140 ', and lambda / is disposed between the beam splitter 140' and the reflector 130. It differs from the first embodiment in that four wave plates 153 (λ / 4 plate: Quarter wave plate) are arranged.

Here, the inclined surface 141 ′ of the beam splitter 140 ′ formed of the polarization beam splitting prism reflects the polarization beam of the S-wave component and transmits the polarization beam of the P-wave component, and the dot target generator 120 And the first polarization portion 151 disposed between the beam splitter 140 'is set to transmit only the polarization beam of the P-wave component.

The coating surface of the inclined surface 141 ′ is set to reflect only a portion (eg, 60%) of the S wave component and transmit the remaining portion (eg, 40%) and transmit the P wave component 100%. In this case, the total amount of transmitted light may be 50% or more (for example, 70%) by combining S wave P wave.

The operation of the third embodiment of the dot sight device having the beam splitter in the direction of the gaze line described above will now be described.

As shown in FIG. 8, while the dot target beam irradiated from the dot target generator 120 passes through the first polarizer 151, the polarization beam of the S wave component is blocked, and the polarization beam of the P wave component is blocked. Is transmitted and provided towards the beam splitter 140 '.

The polarized beam having the P-wave component passing through the first polarization part 151 passes through the inclined surface 141 'of the beam splitter 140' made of the polarization beam splitting prism, and then the beam splitter 140 'and the reflector ( 130 is converted into a right polarization beam or a left circular polarization beam while passing through the λ / 4 wave plate 153 disposed between the first and second polarization parts 153. It passes again and is converted into a polarization beam of S wave component. Subsequently, the polarization beam of the S-wave component provided to the inclined surface 141 'of the beam splitter 140' is reflected toward the user at the inclined surface 141 '. Therefore, the user may aim to match the virtual image of the dot target provided from the dot target generator 120 and reflected by the reflector 130 onto the external target observed through the beam splitter 140 '.

As described above, the inclined surface 141 'of the beam splitter 140' has a coating surface that reflects S waves and transmits P waves. However, when the dot target beam provided from the dot target generator 120 toward the beam splitter 140 'is incident on the inclined surface 141' of the beam splitter 140 ', the inclined surface 141 Since the coated surface of ') blocks the S-wave component and transmits only the P-wave, it is possible to prevent the dot target beam from being reflected toward the target.

However, as shown in FIG. 8, the dot target beam provided from the dot target generator 120 has a predetermined light emission angle (for example, an angle of about 45 degrees) and has an inclined surface of the beam splitter 140 '( 141 '), it is difficult for the first polarization part 151 to completely separate the S wave and the P wave, that is, block the S wave and transmit only the P wave. That is, when a part of the beam of the P-wave component is reflected by the inclined surface 141 'to face the target, the position of the user is exposed.

In order to solve this problem, the beam splitter 140 'according to the present embodiment has a predetermined light emission angle (for example, an angle of about 45 degrees) from the dot target generator 120, Of the dot viewing beams incident on the inclined surface 141 ', the P wave and the S wave are separated into only the light incident within an angle less than or equal to the emission angle (for example, about 5 degrees from the vertical to the left and right), that is, the S wave By having a coating surface that reflects and transmits P waves, a portion of the light may be directed toward the target, thereby preventing the user's position from being exposed.

When the coating surface is set to separate S and P waves for all light emission angles of the dot sight generator, the light is reflected by the inclined surface 141 'of the beam splitter 140' and directed toward the target. It can certainly prevent the location from being exposed. However, such a configuration is undesirable because the cost increases and the processing period increases greatly. Therefore, it is preferable to set the P wave and the S wave to be separated only at an angle equal to or smaller than the emission angle, preferably about 5 degrees (about 10 degrees) from the vertical to the left and right.

At this time, when the dot site apparatus is close to the target, the position of the user is exposed, but the position of the user is not exposed outside the predetermined distance. That is, it is preferable to set to separate the P wave and the S wave in accordance with the angle range that the coating surface can cover according to the purpose of the dot sight device.

That is, the first polarization part 151 which blocks the polarization beam of the S-wave component is disposed between the dot time generation part 120 and the beam splitter 140 ', and the inclined surface 141' of the beam splitter 140 'is disposed. ) Is set to transmit the polarization beam of the P-wave component and reflect the polarization beam of the S-wave component, thereby preventing the dot time beam from being reflected toward the target, thereby exposing the user's position to the other party around the target. Can be prevented.

According to the third embodiment of the present invention as described above, since the polarizing member is not disposed between the beam splitter 140 'and the target, the incident light provided from the target is provided to the user as it is, so that the target can be observed more clearly. do.

The polarizing beam splitting prism in the second and third embodiments of the present invention is composed of two flat plates, and may be replaced by a polarizing beam splitting plate having a polarizing beam (S wave / P wave) separating coating between the two flat plates. have.

On the other hand, when bright light enters the prism from the outside, the four sides of the prism are shimmered like a mirror due to total internal reflection, which obstructs shooting by giving many obstacles to the observer to observe the target. . In other words, when looking at an external target through a prism, total internal reflection occurs on the four sides of the prism, and under the strong light such as the sun, it shines like a mirror. Therefore, the difficulty of full-view through the prism may occur.

)이라고 하는데 이 임계각은 This internal reflection occurs when light tries to refraction from a medium having a high refractive index (prism refractive index n ') as shown in FIG. 9 to a medium having a low refractive index (air refractive index n = 1). The angle of incidence for internal total reflection is defined as the internal total reflection critical angle (

) And this critical angle

으로 결정된다.

Is determined.

Accordingly, as shown in FIG. 9, all light incident on the side of the prism at an angle greater than or equal to the critical angle is totally internally reflected, causing a phenomenon in which the light shines like a mirror surface.

In order to solve this problem, as shown in FIG. 10, internal reflection prevention processing is performed on the outer surfaces 142a, 142b, and 142c where the prism constituting the beam splitter 140 'is not reflected or transmitted.

Sandblasting or grinding the upper surface 142a of the beam splitter 140 'and the side surfaces 142b and 142c where the junction boundary of the two rectangular prisms is exposed is subjected to a surface treatment for the appearance of fine unevenness, followed by matt black Alternatively, the coating can prevent total internal reflection on three sides. At this time, the light transmitting portion 143 (shape is not limited) having a diameter of about 5 mm to which the dot target generating portion of the upper surface 122a is attached excludes surface treatment. For example, a 5 mm round protective film made of a hard metal plate or the like is attached to the light transmitting portion 143 at a position corresponding to the dot mark generating portion in a detachable state, and squared on both sides 142b and 142c facing each other. After attaching the protective film, sand granules can be applied to the surface by spraying fine sand grains with high pressure to make fine irregularities on the surface.

Also, after the sand blasting process on the upper surface 142a and both side surfaces 142b and 142c, the remaining reflector attaching surface is filled with lens chords instead of placing an air layer between the reflector and the beam splitter 140 ', You can prevent internal reflection from happening.

In addition, after sandblasting the upper surface 142a and the both sides 142b and 142c of the beam splitter 140 ', the remaining reflector attaching surface (corresponding to the bottom portion of the beam splitter 140' in the drawing) is upward. By disposing the observer in the front view, the internal reflection of the total reflection can be turned downward to avoid difficulty in using the dot site apparatus of the present invention.

In addition, the reflector attaching surface remaining after sandblasting of the upper surface 142a and both side surfaces 142b and 142c has a certain thickness of flat glass to prevent total internal reflection between the beam splitter 140 'and the flat glass. It is also possible to prevent the difficulty of using dot sites by bonding the balsam and then placing the reflector so that the observer does not appear in the viewer's view of the total reflection of the internal reflections in the forward field of view. In this case, the [lambda] / 4 wave plate in the above-described second and third embodiments may be disposed between the flat glass having a certain thickness and the reflecting mirror.

On the other hand, when the beam splitter is configured as a beam splitting plate or a polarizing beam splitting plate, internal reflection prevention processing can be performed on the side of the flat plate.

Meanwhile, in the drawings according to the above-described embodiment, the case in which the reflector 130 is positioned below the beam splitter 140 'is described as an example. However, the reflector 130 is different from the dot target generator 120. Since the present invention is characterized by being disposed at opposite positions, the present invention is not limited only to the embodiment described above. For example, the reflector 130 and the dot target generator 120 may be disposed on both sides of the beam splitters facing each other, and the dots may be disposed with the reflector 130 on the top, as shown in FIG. The target generation unit 120 may be disposed below. In the case of the configuration in which the dot target generator 120 is disposed below the reflector 130, the reflection and the internal reflection by external light are further prevented.

In addition, the dot target generation unit 120 has been described as being composed of LED, but it is also possible to display the shape of the desired dot target is composed of a display panel such as OLED, LCD, LCOS.

According to the present invention described above, the optical axis of the dot target generating unit 120 and the optical axis of the reflecting mirror 130 are arranged on the same line to reduce parallax, and to provide a beam splitter capable of miniaturizing the dot site apparatus. One dot site apparatus can be provided.

In addition, a dot sight device having a beam splitter capable of preventing the dot sight beam provided from the dot sight generator 120 from being reflected toward a target and exposing a user's position may be provided.

In addition, since there is no reflector in the forward direction of illumination, there is no problem of reducing the amount of transmitted light by coating the reflector, thereby providing a natural color to the user.

The scope of the present invention is not limited to the above-described embodiments but may be implemented in various forms of embodiments within the appended claims. Without departing from the gist of the invention claimed in the claims, it is intended that any person skilled in the art to which the present invention pertains falls within the scope of the claims described herein to various extents which can be modified.

110: barrel, 120: dot time generation unit,
130: reflector, 140,140 ': beam splitter,
141,141 ': inclined plane, 151: first polarizer,
152: second polarization portion, 153: lambda / 4 wave plate

Claims (1)

A dot target generator disposed at one side of the inner circumferential surface of the barrel to provide a dot target beam;
A reflecting mirror disposed on the inner circumferential surface of the barrel opposite the dot sight generating unit to reflect the dot sight beam provided from the dot sight generating unit; And
And a beam splitter disposed on a space between the dot target generator and the reflector to form an inclined surface that reflects or transmits the dot target beam.
And the inclined surface of the beam splitter reflects the dot target beam reflected by the reflector toward the user, and transmits incident light provided from the target in front of the barrel.

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