CN116009231B - Calibrating device for laser optical sighting telescope - Google Patents

Abstract

The invention relates to the technical field of optical sighting telescope, in particular to a calibrating device for a laser optical sighting telescope, which comprises a sighting telescope main body, a laser transmitter, a calibrating component and an adjusting component, wherein the front side and the rear side of the upper end of an objective lens group are respectively fixedly connected with a calibrating base and an adjusting base, the calibrating component is detachably connected to the calibrating base, the adjusting component is fixedly connected to the adjusting base, and the laser transmitter is detachably connected with the adjusting component; the calibration assembly comprises a calibration table, a sliding block and a calibration side mark; the adjusting component comprises an adjusting cylinder, a connecting column, an adjusting wing piece, an adjusting cavity tube and an arc cavity tube. According to the invention, the calibration side marks in the calibration assembly are used as calibration references, and the calibration side marks are matched with the adjustment assembly to drive the laser transmitter to perform an accurate rotation adjustment process, so that the calibration adjustment of the deflection angle between the beam axis of the laser transmitter and the axis of the objective lens group is realized.

Description

Calibrating device for laser optical sighting telescope

Technical Field

The invention relates to the technical field of optical sighting telescope, in particular to a calibrating device for a laser optical sighting telescope.

Background

The most important function of the optical sighting telescope is to use an optical lens for imaging, and the target image and the sighting line are overlapped on the same focusing plane, so that the sighting point is not affected even if eyes are slightly deviated. Typically, optical sighting telescope can magnify the image, with or without magnification. The magnifying sighting telescope can be divided into two types, namely, a fixed magnification or an adjustable magnification, for example, 4 x 28 refers to a sighting telescope with the diameter of an objective lens of 28 mm, the fixed magnification of 4 mm, 3-9 x 40 refers to a sighting telescope with the magnification of 40 mm, and the magnification can be adjusted from 3 mm to 9 mm.

When the laser transmitter is assembled, the connecting seat is assembled on the lens cone at present, the laser transmitter is assembled and connected with the connecting seat in a sliding fit mode, and finally locking and fixing are carried out, and in the use process of the optical sighting telescope, the laser transmitter can cause unavoidable deviation between a laser beam and the axis of the lens cone and cannot be kept in parallel due to external force factors such as stress vibration, so that the sighting precision is influenced, and therefore, a calibrating device for the laser optical sighting telescope is needed.

Disclosure of Invention

The invention aims to provide a calibration device for a laser optical sighting telescope, and aims to solve the technical problems.

The aim of the invention can be achieved by the following technical scheme:

the utility model provides a calibrating device for laser optical sighting telescope, includes sighting telescope main part, laser emitter, calibration subassembly and adjusting part, the sighting telescope main part is including eyepiece group, focusing lens group and the objective group that connects gradually the setting, the front and back side of objective group upper end is fixedly connected with calibration base and regulation base respectively, calibration part can dismantle and connect on the calibration base, adjusting part fixed connection is on the regulation base, laser emitter can dismantle with adjusting part and be connected;

the calibration assembly comprises a calibration table, a sliding block and a calibration side mark, wherein the calibration table is slidably arranged on a calibration base, a lifting chute is arranged in the calibration table, the sliding block is slidably arranged in the lifting chute, the top end of the sliding block is fixedly connected with the calibration side mark, a damping rotating rod is rotatably arranged in the calibration table, an adjusting gear is fixedly sleeved on the damping rotating rod, a lifting rack is arranged on one side, close to the adjusting gear, of the sliding block, and the adjusting gear is in toothed joint with the lifting rack;

the adjusting component comprises an adjusting cylinder, a connecting column, adjusting fins, an adjusting cavity tube and an arc cavity tube, wherein the adjusting cylinder is fixedly connected to an adjusting base and is perpendicular to an objective lens group, a laser emitter is sleeved and installed on the outer side of the connecting column, a rotating shaft is connected to the bottom of the connecting column, the connecting column is coaxially matched with the adjusting cylinder in a rotating mode, the adjusting fins are symmetrically arranged on two sides of the rotating shaft, arc grooves for adjusting the fins to swing left and right are formed in the adjusting cylinder, two arc cavity tubes and an adjusting cylinder center point are used as symmetry centers to form center symmetry, an adjusting piston rod is arranged in the adjusting cavity tube in a sliding mode, a movable block is arranged in the arc cavity tube in an adaptive mode, the movable block is connected with one end of an arc push rod, and the other end of the arc push rod penetrates through the arc cavity tube to extend into the arc grooves and is connected with the corresponding adjusting fins.

As a further scheme of the invention: the calibration assembly further comprises a photoelectric sensing piece and a photoelectric sensing strip, wherein the photoelectric sensing piece is arranged at the center point of the calibration side mark, and the photoelectric sensing strip is arranged on the X axis of the cross center of the calibration side mark.

As a further scheme of the invention: the first indicator light and the second indicator light are installed on one side of the calibration side mark, the first indicator light is electrically connected with the photoelectric sensing strip, and the second indicator light is electrically connected with the photoelectric sensing sheet.

As a further scheme of the invention: the adjusting assembly further comprises an inner threaded pipe and an adjusting screw rod, the inner threaded pipe is coaxially connected with one end of the adjusting cavity pipe, the adjusting screw rod is rotatably installed in the inner threaded pipe in a threaded mode, one end, close to the adjusting screw rod, of the adjusting piston rod is provided with a rotating connector, and the adjusting screw rod is in running fit with the adjusting piston rod through the rotating connector.

As a further scheme of the invention: the two arc push rods are symmetrical with the center point of the adjusting cylinder as a symmetrical center, one end of one arc push rod is connected with one side of the adjusting wing piece, and one end of the other arc push rod is connected with one side opposite to the other adjusting wing piece.

As a further scheme of the invention: be provided with the pilot hole on the laser emitter, evenly be connected with the locating strip on the pilot hole inner wall, evenly be provided with the constant head tank on the spliced pole lateral wall, spliced pole and the coaxial cooperation of pilot hole, just the locating strip adaptation block is in the constant head tank of one-to-one.

As a further scheme of the invention: the top of the connecting column is provided with a limiting blocking cover, and the bottom of the laser transmitter is extended and provided with a protective housing.

As a further scheme of the invention: the calibrating base upper end is provided with spacing draw runner, the calibrating platform bottom is provided with the spacing spout with spacing draw runner looks adaptation.

The invention has the beneficial effects that:

(1) According to the invention, the calibration side mark in the calibration component is used as a calibration reference, the height position of the calibration side mark is adjusted to enable the beam axis of the laser transmitter and the calibration side mark to be positioned at the same height, and then the adjusting component drives the laser transmitter to realize left-right swing adjustment until the laser beam emitted by the laser transmitter is emitted to the central position of the calibration side mark, so that the parallel state between the beam axis of the laser transmitter and the axis of the objective lens group is determined, and the calibration adjustment of the deflection angle between the beam axis of the laser transmitter and the axis of the objective lens group is realized;

(2) According to the invention, the screw thread rotation motion of the adjusting screw in the internal screw thread pipe is converted into the linear motion process of the adjusting piston rod in the adjusting cavity pipe, the linear motion of the adjusting piston rod in the adjusting cavity pipe can cause the air pressure change in the adjusting cavity pipe, the air pressure change process can be directly fed back into the arc cavity pipe to enable the movable block to slide along the arc cavity pipe, and the air pressure is used as power to carry out tiny rotation motion, so that the accurate rotation adjusting process is realized;

(3) The invention utilizes the two arc push rods which are symmetrical in center, and can apply thrust to the two adjusting wings simultaneously when the two arc push rods synchronously rotate in the same direction, and the force application direction and the force application point are also symmetrical in center, so that the stress balance of the adjusting wings is uniform, and the rotation adjusting process can be carried out more stably.

Drawings

The invention is further described below with reference to the accompanying drawings.

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view of the structure of an objective lens assembly according to the present invention;

FIG. 3 is a schematic view of the calibration assembly of the present invention;

FIG. 4 is a schematic view of the installation of a laser transmitter in the present invention;

FIG. 5 is a schematic view of the structure of the adjustment cylinder of the present invention;

FIG. 6 is a schematic view of the structure of the accommodating lumen in the present invention;

fig. 7 is a schematic view of the structure of the arc-shaped lumen in the present invention.

In the figure: 1. an eyepiece group; 2. focusing lens group; 3. an objective lens group; 4. calibrating a base; 401. a limit slide bar; 5. adjusting the base; 6. a calibration assembly; 601. a calibration stand; 6011. limiting sliding grooves; 6012. lifting sliding grooves; 602. a slide block; 603. calibrating a side mark; 604. damping the rotating rod; 605. an adjusting gear; 606. lifting the rack; 607. a photoelectric sensing sheet; 608. a photoelectric sensing strip; 609. a first indicator light; 610. a second indicator light; 7. an adjustment assembly; 701. an adjustment cylinder; 7011. an arc-shaped groove; 702. a connecting column; 7021. a positioning groove; 703. a rotating shaft; 704. adjusting the wing panel; 705. adjusting the lumen; 706. adjusting a piston rod; 707. connecting the cavity tube; 708. an arc-shaped lumen; 709. a movable block; 710. an arc push rod; 711. an internally threaded tube; 712. adjusting a screw; 8. a laser emitter; 801. a fitting hole; 802. a positioning strip; 803. a protective cover; 9. and a limit blocking cover.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1 and 2, the present invention is a calibration device for a laser optical sighting telescope, including a sighting telescope main body, a laser emitter 8, a calibration assembly 6 and an adjusting assembly 7, where the sighting telescope main body includes an eyepiece set 1, a focusing lens set 2 and an objective lens set 3 which are sequentially connected, the front and rear sides of the upper end of the objective lens set 3 are respectively and fixedly connected with a calibration base 4 and an adjusting base 5, the calibration assembly 6 is detachably connected to the calibration base 4, the adjusting assembly 7 is fixedly connected to the adjusting base 5, and the laser emitter 8 is detachably connected to the adjusting assembly 7.

Specifically, the calibration base 4 and the adjustment base 5 are fixedly connected with the objective lens group 3 through countersunk screws, corresponding connecting hole sites are formed in a lens barrel of the objective lens group 3, and after the calibration base 4 is fixedly connected with the adjustment base 5, the calibration base 4 and the adjustment base are located in the same vertical plane and are perpendicular to the objective lens group 3, so that the calibration component 6 and the adjustment component 7 can calibrate and correct the deflection angle between the laser transmitter 8 and the objective lens group 3 in the same vertical plane.

As shown in fig. 3, the calibration assembly 6 includes a calibration stand 601, a sliding block 602 and a calibration side mark 603, the calibration stand 601 is slidably mounted on the calibration base 4, a lifting chute 6012 is provided in the calibration stand 601, the sliding block 602 is slidably mounted in the lifting chute 6012, the top end of the sliding block 602 is fixedly connected with the calibration side mark 603, a damping rotating rod 604 is rotatably mounted in the calibration stand 601, an adjusting gear 605 is fixedly sleeved on the damping rotating rod 604, a lifting rack 606 is provided on one side of the sliding block 602 close to the adjusting gear 605, and the adjusting gear 605 is in toothed engagement with the lifting rack 606.

Specifically, a plurality of calibration marks are arranged on the calibration side marks 603 at equal intervals, and the specific position of the laser beam on the calibration side marks 603 is determined by observing the calibration marks, so that a guiding reference is provided for specific calibration operation; by rotating the damping rotating rod 604, the adjusting gear 605 is driven to rotate, and the sliding block 602 slides up and down in the lifting sliding groove 6012 by utilizing the meshing transmission of the adjusting gear 605 and the lifting rack 606, so that the height position of the calibration side mark 603 is adjusted until the horizontal axis of the calibration side mark 603 and the laser beam are positioned on the same horizontal height.

As shown in fig. 4-7, the adjusting assembly 7 includes an adjusting cylinder 701, a connecting column 702, adjusting fins 704, an adjusting cavity tube 705 and an arc cavity tube 708, the adjusting cylinder 701 is fixedly connected to the adjusting base 5 and is perpendicular to the objective lens group 3, the laser emitter 8 is sleeved and mounted on the outer side of the connecting column 702, a rotating shaft 703 is connected to the bottom of the connecting column 702, the connecting column 702 is coaxially and rotatably matched with the adjusting cylinder 701 through the rotating shaft 703, the adjusting fins 704 are symmetrically arranged on two sides of the rotating shaft 703, arc grooves 7011 for the left and right swinging of the adjusting fins 704 are arranged in the adjusting cylinder 701, two arc cavity tubes 708 are symmetrically formed by taking the center point of the adjusting cylinder 701 as a symmetry center, an adjusting piston rod 706 is slidably arranged in the adjusting cavity tube 705, a movable block 709 is slidably arranged in the arc cavity tube 708, and the movable block 709 is connected with one end of the arc push rod 710, and the other end of the arc push rod 710 penetrates through the arc cavity tube 708 to extend into the arc grooves 7011 and is connected with the corresponding adjusting fins 704.

Specifically, the linear movement of the adjusting piston rod 706 in the adjusting cavity tube 705 can cause the air pressure change in the adjusting cavity tube 705, and because the adjusting cavity tube 705 is communicated with the arc cavity tube 708 through the connecting cavity tube 707, the air pressure change process of the adjusting cavity tube 705 can be directly fed back into the arc cavity tube 708 to enable the movable block 709 to slide along the arc cavity tube 708, thereby driving the arc push rod 710 to rotate by taking the rotating shaft 703 as a central shaft, further driving the adjusting fins 704 on two sides to swing, enabling the connecting column 702 to drive the laser transmitter 8 to swing left and right in the horizontal plane, using the central position of the laser transmitter 8 to shoot a calibration cursor as a calibration reference, and realizing the calibration adjustment of the deflection angle between the beam axis of the laser transmitter 8 and the axis of the objective lens group 3.

As shown in fig. 5, besides the arc-shaped groove 7011, a rotation hole position matched with the rotating shaft 703 is arranged at the center of the adjusting cylinder 701 along the axial direction, and meanwhile, an adapting installation hole position corresponding to the adjusting cavity tube 705, the connecting cavity tube 707 and the arc-shaped cavity tube 708 is arranged inside the adjusting cylinder 701.

As shown in fig. 3, the calibration assembly 6 further includes a photo sensor 607 and a photo sensor strip 608, where the photo sensor 607 is disposed at a center point of the calibration side mark 603, and the photo sensor strip 608 is disposed on an X-axis of the cross center of the calibration side mark 603.

Specifically, the photo-sensing strip 608 coincides with the cross axis of the cross center of the calibration side mark 603, so that it is convenient to determine whether the beam axis of the laser transmitter 8 is located at the same height as the calibration side mark 603, and the photo-sensing piece 607 is used for calibrating the beam axis of the laser transmitter 8 to be parallel to the axis of the objective lens set 3.

Further, a first indicator lamp 609 and a second indicator lamp 610 are installed on one side of the calibration side mark 603, the first indicator lamp 609 is electrically connected with the photoelectric sensing strip 608, and the second indicator lamp 610 is electrically connected with the photoelectric sensing piece 607.

When the laser beam emitted by the laser emitter 8 falls on the photoelectric sensing strip 608, the photoelectric sensing strip 608 senses the beam signal and feeds back to the first indicator lamp 609 to enable the first indicator lamp to be lighted, when the laser beam emitted by the laser emitter 8 falls on the photoelectric sensing sheet 607, the photoelectric sensing sheet 607 senses the beam signal and feeds back to the second indicator lamp 610 to enable the second indicator lamp to be lighted, and a person can conveniently perform calibration operation by observing whether the first indicator lamp 609 and the second indicator lamp 610 are lighted.

As shown in fig. 4 and 6, the adjusting assembly 7 further includes an internal threaded tube 711 and an adjusting screw 712, the internal threaded tube 711 is coaxially connected with one end of the adjusting cavity tube 705, the adjusting screw 712 is rotatably installed in the internal threaded tube 711, one end of the adjusting piston rod 706, which is close to the adjusting screw 712, is provided with a rotating connector, and the adjusting screw 712 is in running fit with the adjusting piston rod 706 through the rotating connector.

Specifically, the rotation of the adjusting screw 712 in the internal threaded pipe 711 is converted into the linear motion of the adjusting piston rod 706 in the adjusting cavity pipe 705 by rotating the connector, in this embodiment, the thread pitch of the adjusting screw 712 is very small, and the rotation is continuous meshing motion, so that the arcuate push rod 710 can realize the linear fine rotation adjustment process, and the calibration accuracy is greatly improved. And when the spiral lift angle is smaller than the equivalent friction angle between tooth surfaces, the spiral transmission has good self-locking performance, and when the adjusting screw 712 stops rotating, the rotating angle of the adjusting wing 704 is also determined, and the adjusting wing 704 cannot easily rotate due to the action of external force due to the mechanical self-locking of the adjusting screw 712, so that the service time of the sighting telescope main body after calibration is prolonged, and the Fan Yong performance is improved.

As shown in fig. 7, two arc-shaped push rods 710 are symmetrical about the center of symmetry of the adjustment cylinder 701, one end of one arc-shaped push rod 710 is connected to one side of the adjustment flap 704, and one end of the other arc-shaped push rod 710 is connected to the opposite side of the other adjustment flap 704.

Specifically, by using the two arc push rods 710 with central symmetry, when the two arc push rods synchronously rotate in the same direction, the thrust can be applied to the two adjusting fins 704 at the same time, and the force application direction and the force application point are also central symmetry, so that the stress balance of the adjusting fins 704 is uniform, and the rotation adjusting process can be performed more stably.

As shown in fig. 2, the laser transmitter 8 is provided with an assembly hole 801, the inner wall of the assembly hole 801 is uniformly connected with positioning strips 802, the side wall of the connecting column 702 is uniformly provided with positioning grooves 7021, the connecting column 702 is coaxially matched with the assembly hole 801, and the positioning strips 802 are adaptively clamped in the positioning grooves 7021 in a one-to-one correspondence.

Specifically, laser emitter 8 passes through mounting hole 801 and spliced pole 702 assembly connection, and wherein location strip 802 and constant head tank 7021 cooperation can be fast carry out accurate positioning to laser emitter 8, plays the spacing effect of constraint simultaneously to laser emitter 8, avoids taking place relative rotation between laser instrument and the spliced pole 702.

In this embodiment, a limiting cover 9 is disposed on top of the connection column 702, and a protective casing 803 is disposed at the bottom of the laser emitter 8.

Specifically, the limiting blocking cover 9 is used for axially limiting and blocking the laser generator and preventing the laser generator from axially displacing relative to the connecting column 702; the protective cover 803 covers the top periphery of the adjustment cylinder 701, thereby covering and closing the upper opening of the adjustment cylinder 701, and effectively preventing dust and impurities from entering the interior of the adjustment cylinder 701.

As shown in fig. 2 and 3, a limit slide 401 is disposed at the upper end of the calibration base 4, and a limit chute 6011 adapted to the limit slide 401 is disposed at the bottom of the calibration stand 601.

Specifically, the sighting telescope main body is in normal use, the calibration assembly 6 is not required to be assembled, and when the beam axis of the laser transmitter 8 is required to be calibrated, the positioning and the installation of the quick calibration platform 601 can be realized through the cooperation of the limiting sliding strip 401 and the limiting sliding groove 6011, and meanwhile, the position accuracy of the calibration assembly 6 after the installation is also ensured.

The working principle of the invention is as follows: when calibration is carried out, the calibration table 601 is rapidly positioned and installed through the limiting sliding groove 6011, through rotating the damping rotating rod 604, the adjusting gear 605 is driven to rotate, the adjusting gear 605 is utilized to be in meshed transmission with the lifting rack 606, the sliding block 602 vertically slides in the lifting sliding groove 6012, the height position of the calibration side mark 603 is adjusted, until laser beams emitted by the laser emitter 8 fall on the photoelectric sensing strip 608, the first indicator 609 is lightened, the rotation of the damping rotating rod 604 is stopped, at the moment, the beam axis of the laser emitter 8 and the calibration side mark 603 can be located at the same height, then the adjusting screw 712 is slowly rotated, the adjusting piston rod 706 is pushed to conduct linear motion in the adjusting cavity tube 705, the air pressure change process of the adjusting cavity tube 705 is directly fed back into the arc cavity tube 708 to enable the movable block 709 to slide along the arc cavity tube 708, the arc push rod 710 is driven to rotate by taking the rotating shaft 703 as a central shaft, the adjusting fins 704 on two sides are driven to swing, the connecting column 702 can drive the laser emitter 8 to swing in the horizontal plane, the left swing direction, the laser emitter 8 is enabled to be located at the same height as the laser beam, the laser emitter 8 can be gradually swings, the laser emitter 8 falls on the photoelectric sensing strip is enabled to be located on the photoelectric sensing optical sensing strip 8, and the laser sensor is parallel to the laser emitter 8, the laser sensor is enabled to be located between the laser emitter 8 and the laser sensor is parallel to the laser sensor 8, and the laser sensor is enabled to be located on the photoelectric sensor 8, and the laser sensor has the state can be located in the state.

The foregoing describes one embodiment of the present invention in detail, but the description is only a preferred embodiment of the present invention and should not be construed as limiting the scope of the invention. All equivalent changes and modifications within the scope of the present invention are intended to be covered by the present invention.

Claims (8)

1. The utility model provides a calibrating device for laser optical sighting telescope, includes sighting telescope main part, laser emitter (8), calibration subassembly (6) and adjusting part (7), its characterized in that, sighting telescope main part is including eyepiece group (1), focusing lens group (2) and objective group (3) that connect gradually, the front and back side of objective group (3) upper end is fixedly connected with calibration base (4) and adjusting part (5) respectively, calibration subassembly (6) detachable connection is on calibration base (4), adjusting part (7) fixed connection is on adjusting part (5), laser emitter (8) detachable connection with adjusting part (7);

the calibrating assembly (6) comprises a calibrating table (601), a sliding block (602) and a calibrating side mark (603), wherein the calibrating table (601) is slidably installed on a calibrating base (4), a lifting sliding groove (6012) is formed in the calibrating table (601), the sliding block (602) is slidably installed in the lifting sliding groove (6012), the top end of the sliding block (602) is fixedly connected with the calibrating side mark (603), a damping rotating rod (604) is rotatably installed in the calibrating table (601), an adjusting gear (605) is fixedly sleeved on the damping rotating rod (604), a lifting rack (606) is arranged on one side, close to the adjusting gear (605), of the sliding block (602), and the adjusting gear (605) is in toothed connection with the lifting rack (606);

the adjusting component (7) comprises an adjusting cylinder (701), a connecting column (702), adjusting fins (704), an adjusting cavity tube (705) and an arc cavity tube (708), wherein the adjusting cylinder (701) is fixedly connected to an adjusting base (5) and is perpendicular to an objective lens group (3), a laser emitter (8) is sleeved and arranged on the outer side of the connecting column (702), a rotating shaft (703) is connected to the bottom of the connecting column (702), the connecting column (702) is coaxially and rotatably matched with the adjusting cylinder (701) through the rotating shaft (703), the adjusting fins (704) are symmetrically arranged on two sides of the rotating shaft (703), arc grooves (7011) for the left and right swing of the adjusting fins (704) are formed in the adjusting cylinder (701), the arc cavity tube (708) is provided with two arc grooves and is formed with the center point of the adjusting cylinder (701) as a symmetrical center, an adjusting piston rod (706) is arranged in the adjusting cavity tube (705), a movable block (709) is arranged in an adaptive sliding mode in the arc cavity tube (708), and the movable block (709) is connected with one end of the pushing rod (710) in a sliding mode, and the other end of the pushing rod (710) penetrates through the arc groove (710) to the arc groove (7011);

the adjusting cavity tube (705) is communicated with the arc cavity tube (708) through the connecting cavity tube (707), the linear movement of the adjusting piston rod (706) in the adjusting cavity tube (705) can cause the air pressure change in the adjusting cavity tube (705), and the air pressure change process of the adjusting cavity tube (705) can be directly fed back into the arc cavity tube (708) so that the movable block (709) slides along the arc cavity tube (708).

2. The calibration device for a laser optical sighting telescope according to claim 1, characterized in that the calibration component (6) further comprises a photoelectric sensing piece (607) and a photoelectric sensing strip (608), the photoelectric sensing piece (607) is arranged at the center point position of the calibration side mark (603), and the photoelectric sensing strip (608) is arranged on the X-axis of the cross center of the calibration side mark (603).

3. The calibration device for the laser optical sighting telescope according to claim 2, characterized in that a first indicator lamp (609) and a second indicator lamp (610) are installed on one side of the calibration side mark (603), the first indicator lamp (609) is electrically connected with the photoelectric sensing strip (608), and the second indicator lamp (610) is electrically connected with the photoelectric sensing piece (607).

4. The calibrating device for the laser optical sighting telescope according to claim 1, characterized in that the adjusting component (7) further comprises an inner threaded tube (711) and an adjusting screw (712), the inner threaded tube (711) is coaxially connected with one end of the adjusting cavity tube (705), the adjusting screw (712) is rotatably installed in the inner threaded tube (711) in a threaded manner, a rotary connector is arranged at one end, close to the adjusting screw (712), of the adjusting piston rod (706), and the adjusting screw (712) is rotatably matched with the adjusting piston rod (706) through the rotary connector.

5. The alignment device for a laser optical sighting telescope according to claim 4, characterized in that two of the arc-shaped pushing rods (710) are symmetrical about a center point of symmetry of the regulating cylinder (701), one end of one arc-shaped pushing rod (710) is connected to one side of the regulating wing (704), and one end of the other arc-shaped pushing rod (710) is connected to the opposite side of the other regulating wing (704).

6. The calibrating device for the laser optical sighting telescope according to claim 5, wherein the laser transmitter (8) is provided with an assembly hole (801), positioning strips (802) are uniformly connected to the inner wall of the assembly hole (801), positioning grooves (7021) are uniformly formed in the side wall of the connecting column (702), the connecting column (702) is coaxially matched with the assembly hole (801), and the positioning strips (802) are adaptively clamped in the positioning grooves (7021) in one-to-one correspondence.

7. The calibrating device for the laser optical sighting telescope according to claim 6, characterized in that a limiting blocking cover (9) is arranged at the top of the connecting column (702), and a protective housing (803) is arranged at the bottom of the laser emitter (8) in an extending manner.

8. The calibrating device for the laser optical sighting telescope according to claim 1, wherein a limiting slide bar (401) is arranged at the upper end of the calibrating base (4), and a limiting chute (6011) matched with the limiting slide bar (401) is arranged at the bottom of the calibrating table (601).