RU78375U1 - LASER RADIATOR - Google Patents

Abstract

The utility model relates to optical instrumentation, in particular to devices for generating stimulated radiation, and can be used to create lasers. The objective of the utility model is to increase the resistance of the laser emitter to mechanical stress. The essence of the utility model is that in a laser emitter including a pump lamp installed in the first housing and an active element optically coupled to the resonator mirrors in frames and a polarizer, the laser emitter further comprises a second housing with a flange, through which it is connected to the first housing, which has a through cavity in which a frame with a resonator mirror and a polarizer are installed, while the second body and the frame with a mirror are made with minimal gaps in a single unit. New is the design and execution form of laser emitter parts. 4 Fig.

Description

The utility model relates to optical instrumentation, in particular to devices for generating stimulated radiation, and can be used to create lasers.

Known laser emitter "Arzni-207" [1], which includes installed in the illuminator body of the pump lamp and the active element located in the laser cavity.

The laser resonator contains an optically coupled output mirror in the form of a stack of plane-parallel leucosapphire plates and a dull mirror in the form of a rotating prism of total internal reflection fixed in a frame and used to modulate laser radiation.

The Arzni-207 laser generates radiation pulses with a duration of about 20 ns and a radiation wavelength λ of 0.69 μm.

A laser emitter (IL) [2], which is the closest in technical essence and the achieved result, has a more convenient design for use.

The IL contains a base on which the first casing (illuminator casing) is fixed with screws, including a pump lamp installed in it and an active element optically coupled to the cavity mirrors in the frames and the polarizer.

The frame for the mirror is made in the form of a rectangular plate with an internal seat for the mirror. The frame with the mirror is installed separately from the first building.

The polarizer is also installed in a separate node of the polarizer separately from the first housing and from the frame with a mirror.

The disadvantage of this IL is its low resistance to mechanical stress (shock, vibration, shaking).

The objective of the utility model is to increase the resistance of IL to mechanical stress.

The essence of the utility model lies in the fact that the laser emitter, which includes a pump lamp and an active element optically coupled to the resonator mirrors in frames and a polarizer, in contrast to the prototype, further comprises a second housing with a flange, through which it is connected to the first housing having a through cavity in which a frame with a resonator mirror and a polarizer are mounted, wherein the through cavity of the second body includes a first circular straight cylindrical cavity coaxial to them, the diameter is larger than the diameter of the resonator mirror, a straight round truncated conical cavity, the smaller base of which is the base of the first round straight cylindrical cavity, and a second round straight cylindrical cavity, the diameter of which is equal to or greater than the diameter of the larger base of the first straight circular truncated conical cavity, and made to the outer the surface of the second body is a cavity with an internal thread, the diameter of which is less than the diameter of the second round straight cylindrical cavity, the frame of the mirror the onator has an external lateral surface including the lateral surface of the first round straight cylinder from one edge, and from the other edge including a coaxially located truncated spherical surface whose diameter is larger than the diameter of the first round straight cylinder, and the frame with the resonator mirror is installed in the through cavity of the second case so that its spherical surface is pressed against the lateral surface of the round straight truncated conical cavity of the second body by means of a ring with an external re boy forming a threaded connection with internal threads in the second housing, wherein the inner surface of the outer threaded ring includes

the lateral surface of the second round straight cylinder and the adjacent side surface of the truncated round straight cone expanding towards the edge of the ring and touching the spherical surface of the resonator mirror frame, the diameter of the second round straight cylinder being larger than the diameter of the first round straight cylinder of the resonator mirror frame, but smaller than the diameter of the spherical the surface of this frame.

The presence of a second housing with a flange in the IL, through which it is connected to the first housing, having a through cavity in which a frame with a resonator mirror and a polarizer are mounted, allows the first housing and the second housing to be compactly mounted and jointly fixed, which increases the mechanical resistance of the IL.

The presence of a through cavity of the second body, including a first circular straight cylindrical cavity coaxial with a diameter larger than the diameter of the resonator mirror, a straight circular truncated conical cavity, the smaller base of which is the base of the first circular circular cylindrical cavity, and a second circular circular cylindrical cavity, whose diameter is equal to or more than the diameter of the larger base of the first straight circular truncated conical cavity, and a cavity with internal thread, the diameter of which is less than the diameter of the second round straight cylindrical cavity, allows you to set a frame with a resonator mirror in the specified through cavity.

The presence of the frame of the resonator mirror having an external side surface including the side surface of the first round straight cylinder from one edge, and from the other edge including a coaxially located truncated spherical surface whose diameter is larger than the diameter of the first round straight cylinder, and the frame with the resonator mirror is set to the through cavity of the second body so that its spherical surface is pressed against the side surface

round straight truncated conical cavity of the second body by means of a ring with an external thread, forming a threaded connection with an internal thread in the second body, while the inner surface of the ring with an external thread includes the side surface of the second round straight cylinder and the adjacent side surface of the ring expanding to the edge a truncated round straight cone, touching the spherical surface of the frame of the resonator mirror, and the diameter of the second round straight cylinder is larger than the diameter The diameter of the first round straight cylinder of the resonator mirror frame, but smaller than the diameter of the spherical surface of this frame, allows, firstly, due to the small area of contact of the spherical surface of the frame with the resonator mirror and the side surface of the straight round truncated conical cavity of the second case, it is easy to change the angular position of the frame with the resonator mirror in the second case when adjusting the IL without changing the position of the resonator mirror on the longitudinal axis of the through cavity of the second case, secondly, fix the floor If the resonator mirror is on the longitudinal axis of the through cavity of the second case, thirdly, press the ring of the resonator mirror onto the second case with an external thread without touching the first round straight cylinder of the frame with the resonator mirror.

Thus, the creation of the design of the IL having high resistance to mechanical stress is ensured.

The utility model is illustrated by drawings.

The figure 1 presents IL - front view in section of a plane of symmetry.

The figure 2 presents the second body - front view in section of a plane of symmetry.

The figure 3 presents the frame with a mirror resonator IL - front view in section of a plane of symmetry.

The figure 4 presents the ring with an external thread - front view in section of a plane of symmetry.

IL (Fig. 1) contains a first housing 1 (illuminator housing) and a second housing 2 with a flange 3, through which it is connected to the first housing 1 by screws (not shown) passing through the flange 3 (Figs. 1, 2).

In the first housing 1, there is a pump lamp 4, which was used as an INP3-3 / 45 gas discharge lamp, and an active element 5, optically connected to the polarizer 6 and to the resonator mirrors 7 and 8 installed in the frames 9 and 10, respectively.

The mirror 7 of the resonator in the frame 9 is installed in the first body 1 or can be installed outside it, the mirror 8 of the resonator in the frame 10 is installed in the second body 2.

The mirrors 7 and 8 of the resonator are made of K8 glass with dielectric coatings deposited on them and are exposed parallel to each other. The mirror 7 of the resonator serves as the output for the radiation of the IL, the mirror 8 is deaf for the radiation of the IL.

The polarizer 6 is made in the form of a thin transparent plate made of K8 glass with plane-parallel working faces and is installed between the active element 5 and the mirror 8. In the laser resonator, the polarizer 6 is located so that it is normal to the plane-parallel working faces with the optical axis of the laser resonator, close to the corner of Brewster.

The second housing 2 (Fig.1, 2) has a through cavity 11 in which the mirror 8 of the resonator in the frame 10 and the polarizer 6 mounted on a separate rack (not shown) are placed.

The frame 10 with the mirror 8 of the resonator is installed in the through cavity 11 of the second body 2 and pressed to it by means of a ring 12 (Fig. 1) with an external thread 13 (Fig. 4).

The second housing 2 (figure 2) has a through hole 14 for propagating a beam of radiation IL.

The through cavity 11 of the second body 2 (figure 2) includes coaxial:

- the first round straight cylindrical cavity 15 having a diameter larger than the diameter of the mirror 8 of the resonator;

- a straight circular truncated conical cavity 16, the smaller base of which is the base of the first round straight cylindrical cavity 15;

- the second round straight cylindrical cavity 17, the diameter of which is equal to or greater than the diameter of the larger base of the first straight circular truncated conical cavity 16;

- cavity 18 made up to the outer surface of the second body 2 with an internal thread 19, the diameter of which is less than the diameter of the second round straight cylindrical cavity 17.

The rim 10 (Fig. 3) of the resonator mirror 8 has an outer side surface including the side surface of the first round straight cylinder 20 from one edge, and from the other edge including a coaxially located truncated spherical surface 21, the diameter of which is larger than the diameter of the first round straight cylinder 20 In this case, the frame 10 with the mirror 8 of the resonator is installed in the through cavity 11 of the second housing 2 (Fig.2) so that its spherical surface 21 (Fig.3) is pressed against the side surface of a round straight truncated conical polo 17 of the second body 2 (FIG. 2) by means of a ring 12 (FIG. 4) with an external thread 13 forming a threaded connection with an internal thread 19 in the second body 2 (FIG. 2).

Ring 12 with an external thread 13 (FIG. 4) has an inner surface including a side surface of a second round straight cylinder 22 and an adjacent side surface 23 of a truncated round straight cone extending to the edge of the ring 12 and touching (FIG. 1) with a spherical surface 21 (figure 3) of the frame 10 with the mirror 8 of the resonator, and the diameter of the second round straight cylinder 22 (figure 4) is larger than the diameter of the first round straight cylinder 20 (figure 3)

frames 10 with a mirror 8 of the resonator, but less than the diameter of the spherical surface 21 of this frame.

IL works as follows.

The resonator mirror 8 (FIG. 1) is set to the required position by changing the angular position of the frame 10 and is pressed against the second body 2 by a ring 12 with an external thread 13 (FIG. 4).

The resonator mirror 7 is aligned parallel to the mirror 8.

In the future, it is possible to remove and without subsequent adjustment to put back and fix the second body 2, with the resonator mirror 8 installed in it and the polarizer 6.

A storage capacitor of a laser power source with a discharge pulse energy of 6-7 J and a duration of about 100 μs is discharged to the pump lamp of the collected IL. In this case, an IL with an active element from the SHW generates a polarized output radiation with a wavelength of λ = 1.067 μm and a pulse energy of about 60 mJ.

In connection with the compactness of the IL, the installation of optical elements in the second case and the connection of the second case with the first case, an increase in the resistance of the IL to mechanical stress is achieved.

Information sources.

1 Bayborodin Yu.V., Kriksunov L.Z., Litvinenko O.N., Edited. Handbook of laser technology. - Kiev. Technics, 1978.- P.81.

2 http://www.solarlaser.com / SOLAR Lasers Systems OPO SYSTEMS 4 / Pulsed Nd: YAG laser LQ 529. User's Manual. - C.9-11, 42-46 - prototype.

Claims (1)

A laser emitter including a pump lamp installed in the first housing and an active element optically coupled to the resonator mirrors in frames and a polarizer, characterized in that it further comprises a second housing with a flange, through which it is connected to the first housing having a through cavity in which the mount is mounted with a resonator mirror and a polarizer, while the through cavity of the second body includes coaxial first circular straight cylindrical cavity having a diameter larger than the diameter of the mirror resonator a, a straight round truncated conical cavity, the smaller base of which is the base of the first round straight cylindrical cavity, and a second round straight cylindrical cavity, the diameter of which is equal to or greater than the diameter of the larger base of the first straight circular truncated conical cavity, and a cavity with internal thread, the diameter of which is less than the diameter of the second round straight cylindrical cavity, the frame of the resonator mirror has an external lateral surface, including which includes the lateral surface of the first round straight cylinder from one edge, and from the other edge including a coaxially located truncated spherical surface whose diameter is larger than the diameter of the first round straight cylinder, and the frame with the resonator mirror is installed in the through cavity of the second case so that its spherical the surface is pressed against the lateral surface of the round straight truncated conical cavity of the second body by means of a ring with an external thread, forming a threaded connection with the inside thread in the second case, while the inner surface of the ring with an external thread includes the side surface of the second round straight cylinder and its adjacent side surface of the truncated round straight cone expanding to the edge of the ring, touching the spherical surface of the frame of the resonator mirror, the diameter of the second round a straight cylinder is larger than the diameter of the first round straight cylinder of the mirror frame of the resonator, but less than the diameter of the spherical surface of this frame.