RU2348889C2 - Laser sight-range finder (versions) - Google Patents

Abstract

FIELD: physics, optics.

SUBSTANCE: invention concerns the optiko-electronic technics and can be used as the device of optical prompting. The sight-range finder contains the sounding channel including optical system and a radiant of laser radiation and the collimating channel or the receiving channel combined on optical axis of an objective, including a photointake. The sight also contains the channel of range indication, including the lens, the indicator of range and the mirror reflecting surface, placed at a 45° angle to optical axes of the objective and the lens and traversing them. Versions of execution of a sight-range finder, the collimating channel, the sounding channel and the channel of indication of range are given.

EFFECT: making of an unobstructive sight-range finder with the functionality dilated on range.

17 cl, 11 dwg

Description

The invention relates to optical-electronic equipment and can be used as a device for optical guidance of hunting rifles and other pneumatic and firearms, requiring aiming guidance at the object.

Known laser sight-range finder, comprising a probing channel, consisting of a laser radiation source and an optical system, a combined receiving and sighting channel, the optical axis of which is parallel to the optical axis of the probing channel, consisting of a beam splitter, telescope and a photodetector optically coupled to it, and a channel range indication, including a time interval meter and a range indicator. The operation of the well-known rangefinder is based on searching for a target by means of an image in the eyepiece of the telescope, irradiating the target with a laser radiation source, generating an electrical signal from the radiation reflected from the target by the photodetector, measuring the time interval, converting the received signal into a range indicator control signal and combining the “shifted” »Aiming range indicator with a target. In this case, the shift of the reticle corresponds to the distance to the target [1].

A disadvantage of the known rangefinder sight is its large dimensions and mass, due to the spatial diversity of the telescope lens, the optical system of the probing channel and the lens of the range indication channel.

The solution closest in technical essence to the claimed one is a laser sight-range finder containing a probing channel, including an optical system and an infrared laser radiation source, a combined receiving-sighting channel, the optical axis of which is parallel to the optical axis of the probing channel, consisting of a beam splitter made in the form of a transmitting beam and reflecting holograms installed in the entrance pupil of the receiving-sighting channel, the telescope, made in the form of a Galileo telescope, including a lens and negative eyepiece, and a photodetector optically coupled to it, a range indication channel including a range indicator in the form of a line of LEDs and a lens and an electronic unit, the outputs of which are connected to the inputs of the laser radiation source and the range indicator, and the input to the output of the photodetector [2] .

The operation of the laser rangefinder sight [2] is carried out in the same manner as in the well-known above rangefinder [1]. In this case, part of the reflected infrared laser beam from the target after diffraction on the transmission hologram by the telescope objective is collected on a photodetector. And the beam of visible radiation from the range indicator passes the telescope lens, part of it is reflected from the reflecting hologram and in the reverse course through the telescope is observed by the operator in the form of an aiming mark together with the target image.

The disadvantages of the laser rangefinder sight [2] include the large loss of visible and infrared radiation on the transmitting and reflecting holograms in the receiving-sighting channel, which reduces the range of the rangefinder’s functionality. This also leads to the implementation of the telescope in the form of a Galileo telescope, which does not provide the magnification and angular resolution necessary for the sight.

The basis of the invention is the creation of a compact laser sight-rangefinder with extended range of functionality.

The essence of the invention according to the first embodiment consists in the fact that in a laser sight-range finder containing a probe channel with a telescope including a lens with an internal lens and a photodetector optically paired with the lens, a range indication channel with a range indicator, a lens and an electronic unit, the outputs of which are connected to the inputs of the laser source and the range indicator, and the input to the output of the photodetector, the optical axis of the probing channel and the telescope lens p arranged parallel, unlike the prototype, the range indication channel is equipped with a first reflective prism with a metal coating, the specularly reflecting surface of which is mounted at an angle of 45 ° to the optical axes of the telescope objective and the distance indication lens and intersecting them, the maximum projection size of which is on the plane, perpendicular to the optical axis of the lens, does not exceed 1/3 of the light diameter of the inner lens of the lens, the receiving-sighting channel is equipped with a prism BU-45 °, one of the faces of which is made with a mirror coating, an optical wedge glued with a mirror-coated face of the BU-45 ° prism, and a lens system sequentially installed between the lens and the photodetector, while the beam splitter is made on the face with a mirror coating of the BU-45 ° prism in the form of a dichroic coating , the telescope is made in the form of a Kepler telescope with a net and a wraparound system, with the BU-45 ° prism located between the lens and the wraparound system of the telescope, and the range indicator and the telescope grid Installed in optically conjugated planes.

In the rangefinder, the first reflective prism is glued to one of the refracting faces either to the inner surface of the telescope objective or to the face of the BU-45 ° prism.

The rangefinder sight is equipped with a plane-parallel transparent plate glued in two parts between the lens and the BU-45 ° prism, the glued sides of which are made at an angle to the optical axis of the lens, a mirror-reflecting surface is made on one of the faces, while the end face of the plate is opposite to the mirror-reflecting surface polished.

In the rangefinder, the range indicator is made in the form of an LED ruler mounted with the ability to move in a direction perpendicular to the direction of placement of the LEDs in the ruler.

In the rangefinder, the range indication channel is equipped with an LED and a translucent mirror mounted on the optical axis of the lens, and the LED is mounted with the ability to move in two mutually perpendicular directions in a plane perpendicular to the axis of the lens and optically paired with the telescope grid, and the range indicator is made in the form LED matrix.

In the rangefinder sight, the lens of the range indication channel is made in the form of a spherical or aspherical surface on the first along the rays of the refracting face of the first reflective prism glued to the BU-45 ° prism.

In the rangefinder, the range indication channel is provided with a second reflective prism, the reflective face of which is glued to the reflective face of the first reflective prism glued to the inner surface of the lens, and the lens of the indication channel is made in the form of a spherical or aspherical surface on one or both refracting faces of the second reflective prism.

The rangefinder sight is equipped with an additional probe channel with a second laser radiation source and a second optical system, the optical axis of which is mounted at an angle to the reflective face of the first reflective prism, the reflective face of the second reflective prism being made opaque to the laser radiation of the second source, and its projection onto a plane perpendicular to the optical axis of the lens, made no less than any projection onto the same plane of the reflective surface of the first reflective prism.

The essence of the invention according to the second embodiment consists in the fact that in a laser sight-range finder containing a probing channel with an optical system and a laser radiation source, a combined receiving-sighting channel with a beam splitter, a sighting device including a lens with an internal lens and an eyepiece, and a photodetector, optically conjugated to the lens, a range indication channel with a range indicator and a lens and an electronic unit, the outputs of which are connected to the inputs of the laser radiation source and the indicator while the input is with the output of the photodetector, and the optical axes of the probing channel and the lens of the sighting device are parallel, unlike the prototype, the range indication channel is equipped with a reflective prism with a metal coating, the mirror-reflecting surface of which is installed at an angle of 45 ° to the optical axis of the lens the sighting device and the lens of the range indication channel and intersecting them, the maximum projection size of which on a plane perpendicular to the optical axis of the lens does not exceed 1/3 of the diameter of the inner lens of the lens, the receiving and sighting channel is equipped with a BU-45 ° prism, one of the faces of which is made with a mirror coating, an optical wedge glued to a face with a mirror coating of the BU-45 ° prism, and a lens system sequentially installed between the lens and a photodetector, the sighting device is equipped with an electron-optical converter with image wrapping, the screen of which is located in the objective plane of the eyepiece, the beam splitter is made on the edge with a mirror coating We use the BU-45 ° prism in the form of a dichroic coating, with the BU-45 ° prism located between the lens and the electron-optical converter of the sighting device, and the range indicator and the photocathode of the electron-optical converter are installed in optically conjugated planes.

In the sighting rangefinder according to the second embodiment, the sighting device is equipped with a lens reversing system, the optical axis of which is parallel to the axis of the electron-optical converter, the first and second retractable flat mirrors located at an angle to the axis of the electron-optical converter on its different sides, and two flat mirrors located on opposite sides of the lens wrapping system at an angle to its optical axis, with one flat mirror parallel to the first retractable mirror, the other - parallel to the second retractable mirror, and the front and rear focal planes of the lens wraparound system are aligned respectively with the rear focal plane of the lens and the objective plane of the eyepiece.

In the rangefinder scope of the second embodiment, the first and second retractable mirrors are kinematically connected.

The essence of the invention according to the third embodiment consists in the fact that in a laser sight-range finder containing a probing channel with an optical system and a laser radiation source, a combined receiving and sighting channel with a beam splitter, a sighting device including a lens with an internal lens and an eyepiece, and the first photodetector optically coupled to the lens, a range indication channel with a range indicator, a lens and an electronic unit, the outputs of which are connected to the inputs of the laser radiation source and indicator range, and the input - with the output of the first photodetector, and the optical axis of the probing channel and the lens of the sighting device are parallel, unlike the prototype, the range indication channel is equipped with a reflective prism with a metal coating, the mirror-reflecting surface of which is installed at an angle of 45 ° to the optical axes the lens of the sighting device and the lens of the range indication channel and intersecting them, the maximum projection size of which on a plane perpendicular to the optical axis of the lens is not exceeds 1/3 of the light diameter of the inner lens of the lens, the receiving-sighting channel is equipped with a prism BU-45 °, one of the faces of which is made with a mirror coating, an optical wedge glued with a face with a mirror coating of the prism BU-45 °, and the lens system, in series mounted between the lens and the first photodetector, the sighting device is equipped with a video monitoring device with a second photodetector and a monitor, the screen of which is located in the subject plane of the eyepiece, while the beam splitter is made on the side of the face with a mirror coating of the BU-45 ° prism in the form of a dichroic coating, with the BU-45 ° prism located between the lens and the second photodetector, the output of which is connected to the monitor input, and the input to the output of the electronic unit, and the range indicator is the second photodetector installed in optically conjugated planes.

In the rangefinder sight of the third embodiment, the monitor of the video monitoring device and the eyepiece of the sighting device are made in the form of either a separate unit or a removable unit.

In the sighting rangefinder of the third embodiment, the video monitoring device is equipped with a wireless information transmission system with a transmitter and a receiver, the input of the transmitter being connected to the output of the second photodetecting device, and the output of the receiver being connected to the input of the monitor.

The essence of the invention according to the fourth embodiment consists in the fact that in the laser sight-range finder containing a probing channel with an optical system and a laser radiation source, a combined receiving and sighting channel with a beam splitter, a sighting device including a lens, and a first photodetector optically paired with the lens , a range indication channel with a range indicator, a lens and an electronic unit, the outputs of which are connected to the inputs of the laser source and the range indicator, and the input to the output m of the first photodetector, and the optical axes of the probing channel and the lens of the sighting device are parallel, unlike the prototype, the range indication channel is equipped with a reflective prism with a metal coating, the mirror-reflecting surface of which is installed at an angle of 45 ° to the optical axes of the lens of the sighting device and the channel lens range indication and crossing it, the maximum projection size of which on a plane perpendicular to the optical axis of the lens does not exceed 1/3 of the light ameter of the internal lens of the lens, the receiving-sighting channel is equipped with a BU-45 ° prism, one of the faces of which is made with a mirror coating, an optical wedge glued with a mirror-coated face of the BU-45 ° prism, and a lens system sequentially installed between the lens and the first photodetector device, the sighting device is equipped with a video monitoring device with a second photodetector and a monitor, while the beam splitter is made on the face with a mirror coating of the prism BU-45 ° in the form of a dichroic coating, and p ism BU-45 ° is located between the lens and the second photodetecting device, whose output is connected to the input of the monitor and input - with the output of the electronic unit, a display range and a second photodetector mounted in optically conjugate planes.

In the rangefinder sight of the fourth embodiment, the monitor of the video monitoring device is made in the form of a separate observation unit.

In the fourth-variant sighting range finder, the video monitoring device is equipped with a wireless information transmission system with a transmitter and a receiver, the transmitter input being connected to the output of the second photodetector device, and the receiver output connected to the monitor input.

The execution of the telescope in the first variant of the telescope in the form of a Kepler telescope with a grid and a wrapping system provides the magnification and angular resolution necessary for the sight. Introducing into the display channel the first reflective prism with a metal coating, the specular reflecting surface of which is set at an angle of 45 ° to the optical axes of the telescope objective lens and the lens of the range indication channel and intersecting them, maximizing the projection of the specular reflecting surface onto a plane perpendicular to the optical axis of the lens , not exceeding 1/3 of the diameter of the lens, allows you to combine the optical axis of the sighting channel and the channel indication range and thereby reduce l dimensions and structurally simplify the sight. Introduction to the receiving-target channel of the BU-45 ° prism, an optical wedge glued to the face with a mirror coating of the BU-45 ° prism, and a lens system sequentially installed between the lens and the photodetector, as well as making a beam splitter in the form of a dichroic coating on the face with a BU-45 ° prism mirror coating, it allows optical radiation, the spectral composition of which corresponds to the spectral composition of the radiation of the source of radiation, to be transmitted to the photodetector practically without loss on the dichroic coating grain radiation, and reflect on the wrapping system of the telescope the radiation visible to the eye. The placement of the BU-45 ° prism between the lens and the telescope wrapping system is determined by the design of the sight. Thus, the listed features provide a solution to the problem.

Gluing the first reflective prism of one of the refracting faces either to the inner surface of the telescope lens or to the edge of the BU-45 ° prism allows, in addition to solving the problem, to simplify the design of the sight.

Introduction to the rangefinder sight mounted between the lens and the BU-45 ° prism transparent transparent glued from two parts of a plane-parallel plate, the glued faces of which are made at an angle to the optical axis of the lens, the implementation of the opposite mirror-reflective surface of the end face polished allows, in addition to solving the problem, to simplify the adjustment the sight.

The implementation of the range indicator in the form of an LED ruler installed with the ability to move in the direction perpendicular to the direction of placement of the LEDs in the ruler, provides, in addition to solving the problem, the ability to introduce lateral corrections in the sight to take into account wind speed and target speed. In this case, the remote correction is introduced automatically by connecting the corresponding LED in the ruler, and the lateral correction manually by shifting the LED ruler.

The introduction of the LED range indicator and a translucent mirror mounted on the optical axis of the lens, and the LED is mounted with the ability to move in two mutually perpendicular directions in the plane perpendicular to the axis of the lens and optically paired with the telescope grid, and the implementation of the range indicator in the form of an LED matrix allows , in addition to solving the main problem, form the value of the measured distance to the target on the LED matrix, the image of which the operator observes and mesh jointly with the sighting mark (image LEDs). The operator enters the remote correction by vertical movement of the LED, and the lateral correction by the horizontal movement of the LED.

The implementation of the lens of the channel indicating the range in the form of a spherical or aspherical surface on the first along the rays of the refracting face of the first reflective prism glued to the prism BU-45 °, allows, in addition to solving the problem, to simplify the alignment of the channel indicating the range of the sight-range finder

The introduction into the display channel of the range of the second reflective prism, the reflective face of which is glued to the reflective face of the first reflective prism glued to the inner surface of the lens, and the lens of the display channel in the form of a spherical or aspherical surface on one or both of the refracting faces of the second reflective prism allows, in addition to the solution of this problem, to simplify the alignment of the channel indicating the range of the sight-rangefinder.

The introduction of an additional probing channel into the sight-range finder, including a second laser radiation source and a second optical system, the optical axis of which is installed at an angle to the reflective face of the first reflective prism, allows, in addition to solving the problem, the probing channel to perform a radiation spot forming on the target in the form point or circle, and an additional sounding channel to perform forming a spot on the target in the form of a narrow vertical gap. The implementation of the reflective face of the second reflective prism, opaque to the laser radiation of the second source, and its projection onto a plane perpendicular to the optical axis of the lens, at least in any projection size onto the same plane of the reflective surface of the first reflective prism, protects the photodetector from parasitic rays of the second source of laser radiation.

The introduction in the laser sighting rangefinder according to the second embodiment, in contrast to the sighting rangefinder according to the first embodiment, of an electron-optical converter with image wrap, the screen of which is located in the objective plane of the eyepiece, and placement of the range indicator and The photocathode of the electron-optical converter in optically conjugated planes provides, in addition to solving the problem, the possibility of using a rangefinder sight at night.

The introduction of the lens reversing system, the optical axis of which is parallel to the axis of the electron-optical converter, of the first and second retractable flat mirrors located at an angle to the axis of the electron-optical converter on its opposite sides, and two flat mirrors located on opposite sides of the lens rolling system at an angle to its optical axis, with one flat mirror parallel to the first retractable mirror, the other parallel but the second retractable mirror, and combining the front and back focal planes of the relay lens system, respectively, with the back focal plane of the lens and the object plane of the eyepiece provides, in addition to the solution of the problem, the possibility of sight at all times.

The introduction of a kinematic connection between the first and second retractable planar mirrors in the second variant of the sight according to the second variant provides, in addition to solving the problem posed, the possibility of simultaneous withdrawal or return to the initial position of retractable mirrors. That is, a convenient switching of the rangefinder sight from daytime to nighttime and vice versa is provided.

Introduction to the laser sighting rangefinder according to the third embodiment, in contrast to the sighting rangefinder according to the first embodiment, into a sighting device containing a lens and an eyepiece, a video monitoring device including a second photodetector and a monitor whose screen is located in the objective plane of the eyepiece, connecting the output of the second a photodetector with monitor input, and input with the output of the electronic unit and the placement of the range indicator and the second photodetector in optically paired planes provides up to In addition to solving the problem posed, the possibility of eliminating aiming errors when the eye is displaced in the plane of the exit pupil of the eyepiece, since there is no parallax between the target and the reticle.

The implementation in the sight rangefinder of the third version of the monitor of the video monitoring device and the eyepiece of the sighting device in the form of either a separate observation unit or a removable observation unit provides, in addition to solving the task, the ability to fix a separate or removable observation unit on a helmet, helmet or headband in front of the operator’s eye and carry out targeted observation, holding weapons at the waist or thigh.

The introduction of a wireless information transmission system, including a transmitter and a receiver, into the video monitoring device of the third variant in the video monitoring device and the connection of the transmitter input to the output of the second photodetector device, and the receiver output to the monitor input, provides, in addition to solving the problem, the possibility of comfortable use rangefinder sight.

Introduction to the laser sighting rangefinder according to the fourth embodiment, in contrast to the sighting rangefinder according to the first embodiment, into the sighting device containing the lens, a video monitoring device including a second photodetector and a monitor, connecting the output of the second photodetector to the monitor input, and the input to the output of the electronic unit, and the placement of the range indicator and the second photodetector in optically paired planes provides, in addition to solving the problem, the possibility is excluded errors of aiming at eye displacements, since there is no parallax between the target and the aiming mark, and the possibility of increasing the distance between the rangefinder sight and the operator’s eye, which is especially necessary when installing it on weapons with high recoil when firing.

Performing in the sight-range finder according to the fourth version of the monitor a video monitoring device in the form of a separate observation unit provides, in addition to solving the task, the possibility of remote, aimed observation when installing the sight-range finder on a remotely controlled weapon.

The invention is illustrated by the diagrams in figure 1-11. Figure 1-4 shows the functional diagrams of examples of the execution of the laser rangefinder sight according to the first embodiment, figure 5 and 6 - diagrams of the examples of the execution of the rangefinder sight according to the second embodiment, Figures 7 and 8 are diagrams of the examples of the execution of the rangefinder sight the third option, Fig.9 is a diagram of an example embodiment of a rangefinder sight according to the fourth embodiment, Fig.10 and 11 are a diagram of the operation of the shutters in an elastic eyecup.

The laser sight-range finder contains a combined receiving-sighting channel, containing in the examples of Figs. 1-4 a telescope in the form of a Kepler telescope 1, including a lens 2, a grid 3, an eyepiece 4 and a wrapping system 5 in the form of a prism VkR-45 ° ( 1-3) or in the form of a lens system 6 (figure 4). Grid 3 can be made with scales to determine the angular coordinates of the target. The lens wrapping system 6 is made with either constant or variable magnification. In the examples of FIGS. 5 and 6, the combined receiving-sighting channel comprises a sighting system 7 including a lens 2, an eyepiece 4 and an electron-optical transducer 8 with image wrap, the screen of which is located in the object plane of the eyepiece 4. In the example embodiment of FIG. 6, the sighting system 7 contains a lens wrapping system 9, the optical axis of which is parallel to the axis of the transducer 8, the first and second retractable flat mirrors 10 and 11, located at an angle to the axis of the transducer 8 on its opposite sides, and two flat stool 12 and 13 disposed on opposite sides of the relay system 9 at an angle to its optical axis. The mirror 12 is parallel to the first retractable mirror 10, the mirror 13 is parallel to the second retractable mirror 11, and the front and rear focal planes of the wrapping system 9 are aligned respectively with the rear focal plane of the lens 2 and the plane of the objects of the eyepiece 4. In Fig.6, the dotted line shows the position of the mirrors 10 and 11 in the state removed from the course of the rays. In the examples of FIGS. 7 and 8, the sighting system 7 includes a lens 2, an eyepiece 4, and a video monitoring device consisting of a second photodetector 14 and a monitor 15, the screen of which is located in the subject plane of the eyepiece 4. In the embodiment of FIG. 8, a video monitoring device comprises a wireless information transmission system including a transmitter 16, the input of which is connected to the output of the second photodetector 14, and a receiver 17, the output of which is connected to the input of the monitor 15. In this case, the receiver 17, the monitor 15 and the eyepiece 4 They are in the form of a separate or removable observation unit 18. In the embodiment of FIG. 9, the target system 7 includes a lens 2 and a video monitoring device consisting of a second photodetector 14 and a monitor 15. Monitor 15 can be made as a separate observation unit (not shown in FIG. 9). The combined receiving-sighting channel also contains a BU-45 ° 19 prism, an optical wedge 21, a lens system 22, a photodetector 23 (the first photodetector in Figs. 7-9) and a beam splitter made on a section glued to its face 20 with a mirror coating 24 faces 20 with a mirror coating of the prism 19 in the form of a dichroic coating. The dichroic coating in section 24 is made with a transmittance of at least 0.95 for infrared radiation and a reflection coefficient of at least 0.95 for radiation visible to the eye. Prism 19 is located in FIGS. 1-4 between the lens 2 and the wrapping system in the form of a prism 5 (FIGS. 1-3) or in the form of a lens system 6. In FIGS. 5 and 6, the prism 19 is located between the lens 2 and the electron-optical converter 8, and in Figs. 7-9, between the lens 2 and the second photodetector 14. The rangefinder includes a probing channel 25, including an optical system 26 and an infrared laser radiation source 27. The probe channel 25 can be made forming a radiation spot on the target in the form of a point or circle and can be made forming a spot in the form of a narrow vertical gap. The rangefinder sight also contains a range indication channel 28, including a lens 29, a range indicator 30 and a specular surface 31 mounted at an angle of 45 ° to the optical axes of the lens 2 and the lens 29 and intersecting them. The maximum projection size of the specularly reflecting surface 31 onto a plane perpendicular to the optical axis of the lens 2 does not exceed 1/3 of the light diameter of the inner lens of the lens 2. In figures 1, 2, 4-9, the specularly reflecting surface 31 is made in the form of a first reflective prism 32 with a metal coating on a reflective face glued by a refracting face either to the inner surface of the lens 2 (Figs. 4-9) or to the first face of the prism 19 (Figs. 1 and 2). In the embodiment of FIG. 2, the lens 29 is made in the form of a spherical or aspherical surface on the first along the rays of the refracting face 33 of the first reflective prism 32 glued to the prism BU-45 °. In the examples of FIGS. 6 and 8, channel 28 contains a second reflective prism 34, the reflective face of which is glued to the reflective face 31 of the first reflective prism 32, and the lens 29 is made in the form of a spherical or aspherical surface 35 on one or both of the refracting faces of the prism 34. In the example embodiment of FIG. 3, the rangefinder sight contains a transparent plane-parallel plate mounted between the lens 2 and the prism 19, glued from two parts 36 and 37, the glued edges of which are made at an angle to the optical axis of the lens 2, mirror azhayuschaya surface 31 is formed on one of these faces, and the opposite mirror-reflecting surface 31 end face 38 formed parallel plate polished. 1-4, the range indicator 30 and the grid 4 are located in optically conjugated planes. 5 and 6, the range indicator 30 and the photocathode of the electron-optical converter 8 are located in optically conjugated planes. 7-9, the range indicator 30 and the second photodetector 14 are located in optically conjugated planes. 3 and 7, the range indicator 30 is made in the form of an LED ruler mounted to move along the arrow “z” in the direction perpendicular to the direction of placement of the LEDs in the ruler. 2 and 4, the range indicating channel 28 comprises an LED 39 and a translucent mirror 40 mounted on the axis of the lens 29, the LED 39 being mounted for movement in two mutually perpendicular directions “z” and “y” in a plane perpendicular to the optical axis of the lens 29 and optically conjugated to the grid 4 of the telescope 1, and the range indicator 30 is made in the form of an LED array. In Fig. 4, the range indicating channel 28 contains a lens 41, the optical axis of which is mounted at an angle to the surface 31 and passes through the LED 39. In Figs. 1-8, to improve the layout, the channel 28 contains a deflecting mirror 42. In the examples of Fig. 6 and 8, an additional sounding channel 43 is introduced, including a second infrared laser radiation source 44 and a second optical system 45, the optical axis of which is mounted at an angle to the reflective surface 31 of the first reflective prism 32. The projection of the reflective surface of the second reflector hydrochloric prism 34 in a plane perpendicular to the optical axis of the lens 2 is made not less than the projection of the reflecting surface 31 of the first reflective prism 32 on the same plane. In these examples, the probing channel 25 is made forming a radiation spot on the target in the form of a point or circle, and the additional probing channel 43 is made forming a radiation spot on the target in the form of a narrow vertical gap. The rangefinder sight contains an electronic unit 46, the outputs of which are connected to the inputs of the sources of laser radiation 27 and 44, range indicator 30, LED 39 (FIGS. 2 and 4) and the second photodetector 14 (FIGS. 7-9), and the input with the output of the photodetector 23. In FIGS. 2 and 4, the telescope 1 contains an LED 47 of the illumination of the grid 4 connected to the output of the block 46. The rangefinder scope includes an elastic eyecup 48 mounted on the eyepiece 4, including a diaphragm in the examples of FIGS. 5 and 7 49 with a shutter of two petals 50 and 51, made with possibly Tew opening aperture 49 upon axial compression of the eye cup 48 using the spring member 52. The spring member 52 is formed, for example, in the form of Y-shaped spring, the ends of which are connected kinematically with the petals 50 and 51, and the base kinematically connected with the fitting 4 eyepiece.

The operation of the laser sight rangefinder is as follows. The device is mounted on small arms, a grenade launcher, or a direct-guided artillery installation. In the embodiment of FIG. 8, a separate or removable observation unit 18 is fixed in front of the eye of the operator on a helmet, helmet or headband (not shown in FIG. 8). In the embodiment of FIG. 9, in the case of the monitor 15 being a separate observation unit, the rangefinder is mounted on a remote-control weapon, and the monitor 15 is in a shelter or other protected place.

In the General case, after turning on the power supply of the rangefinder sight in the range indication channel 28, the “zero” range LED on the line of 30 LEDs (FIGS. 1, 3, 5-9) or LED 39 (FIGS. 2 and 4) are turned on, the image of the emitting crystal of which formed by a lens 29 (figures 1, 3, 5-7 and 9) or 41 (figure 4), or a spherical (aspherical) surface 33 or 35 (figures 2 and 6, 8), and a mirror-reflecting surface 31 in the center mesh 3 (Fig.1-4), or in the center of the photocathode of the electron-optical Converter 8 (Fig.5 and 6), or in the center of the second photodetector 14 (Fig.7-9 ) and serves as the aiming mark. The path of the rays of the range indication channel 28 is indicated by an arrow. Visible to the eye, the radiation from objects on the ground passes through lens 2, enters the prism 19 and is reflected from the dichroic coating portion 24 along with the radiation beam of channel 28. In the examples of FIGS. 1-4, the radiation reflected by portion 24 enters the telescope wrapping system 1 in Fig.1-3, prism 5, Fig.4 lens system 6 and is formed last in a direct image of the terrain on the grid 3. In the example embodiment of Fig.5, used at dusk or night time, reflected by section 24, the radiation is formed inverted image areas of the photocathode electron-optical converter 8 sighting device 7 is amplified luminance and a direct image formed on its screen. When translating the retractable mirrors 10 and 11 to the position shown in FIG. 6 by the dotted line, the rangefinder operates as the above embodiment in FIG. 5, and when moving to the starting position shown by the solid line as the foregoing example in FIG. four. In the embodiment of Figs. 7-9, the radiation reflected by section 24 is generated in the sighting device 7 into an inverted image of the terrain on the second photodetector 14, by the signal from the output of which on the monitor 15 a direct image of the terrain and sighting mark is formed. In Fig. 8, the electrical signal from the output of the device 14 is transmitted to the transmitter 16, where it is converted into radio waves, which the receiver 17 inversely converts into an electrical signal fed to the input of the monitor 15. The electrical signal modulated in the electronic unit 46 is supplied to the probing channel 25 to the source input 27 of laser radiation, the optical system 26 forms a probe beam of modulated infrared radiation with a small angle of divergence. The operator, observing in the eyepiece 4 or on the monitor 15 (Fig. 9) an image of the terrain and the aiming mark, combines the latter with the target. Preliminary axial movement along the arrow "x" eyepiece 4 is set according to the eye of the operator. In the examples of Figures 5 and 7, when aiming, the operator is pressed against the elastic eyecup 48, the latter is compressed and the Y-shaped spring 52 opens the petals 50 and 51, the diaphragm 49 opens. When the operator takes his face away from the eyecup 48, the spring element 52 brings the petals 50 and 51 together, the diaphragm 49 closes and the radiation from the electron-optical converter 8 or monitor 15 is closed. The infrared radiation of the probe channel 25 or the additional probe channel 43 reflected from the target passes through the lens 2, the prism 19, the dichroic coated portion 24, the optical wedge 21 and the lens system 22 are formed on the photodetector 23. In FIG. 1, the beam path of the reflected infrared rays is shown single arrow with a circle. From the photodetector device 23, the electric signal enters the electronic unit 46, where the distance to the target is determined by the time the infrared radiation travels from the source 27 or 44 to the target and vice versa, to the photodetector device 23, and the corresponding signal is sent to the channel range indicator 30. In the examples 1, 3, 5-9, according to the signal from block 46 on the LED strip 30, the “zero” range LED turns off and the LED that turns on determines the aiming angle taking into account the distance to the center measured in block 46 and. That is, in the field of view of the operator, the image of the aiming mark is automatically shifted depending on the distance to the target. The operator combines the image of the “shifted” reticle with the image of the target. In the examples of Figures 3 and 7, the operator, depending on the wind speed or the speed of horizontal movement of the target, introduces lateral correction by moving the LED bar 39 along the arrow "Z", that is, introduces a lateral displacement of the reticle. In the examples of FIGS. 2 and 4, the signal from the block 46 on the indicator 30, made in the form of an LED matrix, turns on the LEDs, forming a number corresponding to the value of the measured distance to the target. The operator enters the correction corresponding to the distance by shifting along the arrow “Y” (in FIGS. 2 and 4 parallel to the sheet) of the LED 39 and, if necessary, side correction of the aiming mark by shifting the LED 40 along the arrow “Z” and aligns the image of the aiming mark with the image of the target.

When performing the probing channel 25 forming a radiation spot on the object in the form of a point or circle, after turning on the power of the rangefinder sight, the “zero” range LED on the LED line 30 is turned on (Fig. 1, 3, 5-9), or LED 39 and LED 47 backlight grid 3 (figure 2 and 4). In this case, combining the reticle with the target, the operator starts the process of measuring the distance to the target in block 46 and works with the rangefinder as described above. The course of the rays is shown by an arrow with a circle.

When performing the probing channel 25, forming a spot in the form of a narrow vertical slit on the object, after turning on the power of the rangefinder sight, the range indicator 30, LED 39 and LED 47 of the grid 3 backlight are off. The operator scans (rotates) the terrain (object) with a rangefinder and, when a slit spot of the probing channel 25 hits an optical system, for example, an optical sight, the flux of infrared radiation incident on the photodetector 23 sharply increases, the signal from which the process of measuring the distance to the target is turned on and the range indicator 30 and the LEDs 39 and 47 are turned on, and the operator works with the rangefinder scope as described above. The course of the rays is shown by an arrow with a crossbeam.

In the examples of FIGS. 6 and 8, both of the above-described functions of the rangefinder are used when the probing and additional probing channels 25 and 43 are alternately turned on.

Information sources

1. Laser sight of the LPR-1 reconnaissance: Technical specifications for the laser reconnaissance device of the LPR G. 36.48.069TU.

2. RF patent No. 2088883, 08.27.97.

Claims (17)

1. A laser rangefinder sight, comprising a probing channel with an optical system and a laser radiation source, a combined receiving and sighting channel with a beam splitter, a telescope, including a lens with an internal lens, and a photodetector optically paired with the lens, a range indication channel with a range indicator , a lens and an electronic unit, the outputs of which are connected to the inputs of the laser source and the range indicator, and the input to the output of the photodetector, the optical axes being probed of the first channel and the telescope objective are arranged in parallel, characterized in that the range indication channel is provided with a first reflective prism with a metal coating, the specular reflecting surface of which is mounted at an angle of 45 ° to the optical axes of the telescope objective and the distance indication lens and intersecting them, maximum size projection of which onto a plane perpendicular to the optical axis of the lens does not exceed 1/3 of the light diameter of the inner lens of the lens, the receiving-sighting channel is equipped with a prize oh BU-45 °, one of the faces of which is made with a mirror coating, an optical wedge glued with a face with a mirror coating of the BU-45 ° prism, and a lens system sequentially installed between the lens and the photodetector, while the beam splitter is made on the area of the face with a mirror coated with a BU-45 ° prism in the form of a dichroic coating, the telescope is made in the form of a Kepler telescope with a grid and a wraparound system, and the BU-45 ° prism is located between the lens and the wraparound system of the telescope, and range and mesh telescope mounted in optically conjugate planes. 2. The rangefinder sight according to claim 1, characterized in that the first reflective prism is glued to one of the refracting faces either to the inner surface of the telescope objective or to the edge of the prism BU-45 °. 3. The rangefinder sight according to claim 1, characterized in that it is provided with a transparent plane-parallel plate glued between two lenses and a BU-45 ° prism, the glued edges of which are made at an angle to the optical axis of the lens, mirror-shaped on one of the faces a reflecting surface, while the end face of the plate opposite the mirror-reflecting surface is polished. 4. The rangefinder sight according to any one of claims 1 to 3, characterized in that the range indicator is made in the form of an LED ruler mounted to move in a direction perpendicular to the direction of placement of the LEDs in the ruler. 5. The rangefinder sight according to any one of claims 1 to 3, characterized in that the range indication channel is equipped with an LED and a translucent mirror mounted on the optical axis of the lens, the LED being mounted with the ability to move in two mutually perpendicular directions in a plane perpendicular to the optical axis lenses and optically conjugated to the telescope grid, and the range indicator is made in the form of an LED matrix. 6. The rangefinder sight according to claim 2, characterized in that the lens of the range indicating channel is made in the form of a spherical or aspherical surface on the first along the rays of the refracting face of the reflective prism glued to the BU-45 ° prism. 7. The rangefinder sight according to claim 2, characterized in that the range indication channel is provided with a second reflective prism, the reflective face of which is glued to the reflective face of the first reflective prism glued to the inner surface of the lens, and the lens of the indication channel is made in the form of a spherical or aspherical surface on one or both of the refracting faces of the second reflective prism. 8. The rangefinder sight according to claim 7, characterized in that it is equipped with an additional probing channel with a second laser radiation source and a second optical system, the optical axis of which is mounted at an angle to the reflective face of the first reflective prism, the reflective face of the second reflective prism being made opaque for laser radiation of the second source, and its projection onto a plane perpendicular to the optical axis of the lens is made no less than any projection onto the same plane of the reflecting surface n first reflective prism. 9. A laser rangefinder sight, comprising a probing channel with an optical system and a laser radiation source, a combined receiving and sighting channel with a beam splitter, a sighting device including a lens with an internal lens and an eyepiece, and a photodetector optically paired with the lens, a range indication channel with range indicator and lens and an electronic unit, the outputs of which are connected to the inputs of the laser source and the range indicator, and the input to the output of the photodetector, and optically the axes of the probe channel and the lens of the sighting device are arranged in parallel, characterized in that the range indication channel is provided with a reflective prism with a metal coating, the mirror-reflecting surface of which is mounted at an angle of 45 ° to the optical axes of the sighting device lens and the lens of the range indication channel and intersecting them, maximum size the projection of which onto a plane perpendicular to the optical axis of the lens does not exceed 1/3 of the light diameter of the inner lens of the lens, the receiver-target camera The nal is equipped with a BU-45 ° prism, one of the faces of which is made with a mirror coating, an optical wedge glued with a mirror-coated face of the BU-45 ° prism, and a lens system sequentially installed between the lens and the photodetector, the sighting device is equipped with an electron-optical a transducer with image wrap, the screen of which is located in the objective plane of the eyepiece, the beam splitter is made on the face with a mirror coating of the prism BU-45 ° in the form of a dichroic coating, and the prism BU-45 ° races it is placed between the lens and the electron-optical converter of the sighting device, and the range indicator and the photocathode of the electron-optical converter are installed in optically conjugated planes. 10. The rangefinder sight according to claim 9, characterized in that the sighting device is equipped with a reversible lens system, the optical axis of which is parallel to the axis of the electron-optical converter, the first and second retractable flat mirrors at an angle to the axis of the electron-optical converter its sides, and two flat mirrors located on opposite sides of the lens wraparound system at an angle to its optical axis, with one flat mirror parallel to the first retractable mirror , the other is parallel to the second retractable mirror, and the front and rear focal planes of the lens wraparound system are aligned with the rear focal plane of the lens and the objective plane of the eyepiece, respectively. 11. The rangefinder sight of claim 10, characterized in that the first and second retractable mirrors are kinematically connected. 12. A laser rangefinder sight, comprising a probing channel with an optical system and a laser radiation source, a combined receiving and sighting channel with a beam splitter, a sighting device including a lens with an internal lens and an eyepiece, and a first photodetector optically paired with the lens, a range indication channel with a range indicator, a lens and an electronic unit, the outputs of which are connected to the inputs of the laser radiation source and the range indicator, and the input - with the output of the first photodetector, m the optical axis of the probing channel and the sighting device’s lens are parallel, characterized in that the range indicating channel is provided with a reflective prism with a metal coating, the mirror-reflecting surface of which is installed at an angle of 45 ° to the optical axes of the sighting device and the lens of the range indicating channel and intersecting them, the maximum projection size of which onto a plane perpendicular to the optical axis of the lens does not exceed 1/3 of the light diameter of the inner lens of the lens, receiving the viewing channel is equipped with a BU-45 ° prism, one of the faces of which is made with a mirror coating, an optical wedge glued with a mirror-coated face of the BU-45 ° prism, and a lens system sequentially installed between the lens and the first photodetector, the sighting device is equipped with a video monitoring device a device with a second photodetector and a monitor, the screen of which is located in the objective plane of the eyepiece, while the beam splitter is made on the edge with a mirror-coated prism BU-45 ° in the form of dichroic of the coating, and the BU-45 ° prism is located between the lens and the second photodetector, the output of which is connected to the input of the monitor, and the input is connected to the output of the electronic unit, and the range indicator and the second photodetector are installed in optically paired planes. 13. The rangefinder scope of claim 12, wherein the monitor of the video monitoring device and the eyepiece of the sighting device are made either as a separate observation unit or a removable observation unit. 14. The rangefinder sight according to item 13, wherein the video monitoring device is equipped with a wireless information transmission system with a transmitter and a receiver, the input of the transmitter connected to the output of the second photodetector and the output of the receiver connected to the input of the monitor. 15. Laser sight-range finder, comprising a probing channel with an optical system and a laser radiation source, a combined receiving and sighting channel with a beam splitter, a sighting device including a lens, and the first photodetector optically paired with the lens, a range indication channel with a range indicator, a lens and an electronic unit, the outputs of which are connected to the inputs of the laser radiation source and the range indicator, and the input is connected to the output of the first photodetector, the optical axes being probed about the channel and the lens of the sighting device are arranged in parallel, characterized in that the range indication channel is equipped with a reflective prism with a metal coating, the mirror-reflecting surface of which is set at an angle of 45 ° to the optical axes of the sighting device lens and the lens of the range indication channel and intersecting them, the maximum projection size which on a plane perpendicular to the optical axis of the lens does not exceed 1/3 of the light diameter of the inner lens of the lens, the receiving-sighting channel is equipped with a prize oh BU-45 °, one of the faces of which is made with a mirror coating, an optical wedge glued with a face with a mirror coating of the BU-45 ° prism, and a lens system sequentially installed between the lens and the first photodetector, the sighting device is equipped with a video monitoring device with a second photodetector a device and a monitor, while the beam splitter is made on the face with a mirror coating of the prism BU-45 ° in the form of a dichroic coating, and the prism BU-45 ° is located between the lens and the second photodetector ohms, whose output is connected to an input of the monitor and input - with the output of the electronic unit, a display range and a second photodetector mounted in optically conjugate planes. 16. The rangefinder scope of claim 15, wherein the monitor of the video monitoring device is made in the form of a separate monitoring unit. 17. The rangefinder sight according to clause 16, wherein the video monitoring device is equipped with a wireless information transmission system with a transmitter and a receiver, the input of the transmitter being connected to the output of the second photodetector and the output of the receiver connected to the input of the monitor.

Images