RU2316091C1 - Method for generating electromagnetic radiation pulse for its delivery to equipment, laser, method and system for laser control - Google Patents

Abstract

FIELD: quantum physics; lasing systems built around associative photogenerators.

SUBSTANCE: proposed method includes generation of convergent shock wave and divergent shock wave with leading edge coaxial to convergent shock wave front. Electromagnetic radiation pulse is generated in shock wave convergence region in the form of thin-walled cylinder for its next conversion into annular-section pulse. Laser has additional explosive material charge in the firm of hollow cone with remote-control receiver at its vertex installed inside and coaxially to truncated cone of main explosive material charge. Proposed method for laser control includes generation of electromagnetic radiation parallel beam, its collimation, and conversion into annular-section beam. Control signals are supplied with time delay relative to each other. Laser control system has parallel electromagnetic radiation beam source, main collimator, three flat mirrors, semi-reflecting mirror, additional collimator, and two electrooptic gates.

EFFECT: enhanced power density of electromagnetic radiation.

7 cl, 2 dwg

Description

The proposed technical solution relates to the field of quantum physics and can be used to create laser systems based on photodissociation generators.

Known methods for generating a pulse of electromagnetic radiation based on photodissociation quantum generators. The control systems of the generators include electromagnetic radiation sources connected to the control unit (see RF Pat. No. 2241285 and 2241286, IPC 7 H01S 3/03, 3/0937, publ. 2004).

The closest technical solution (prototype) to the proposed solution is a method of generating a pulse of electromagnetic radiation when it is delivered to an object, including creating a converging shock wave with a cylindrical leading edge to affect the working environment (see US Pat. No. 2240634, IPC 7 H01S 3/03, 3/0937, publ. 2004).

A quantum generator for implementing the method comprises a working chamber with two output windows filled with a working medium, and the main explosive charge (explosive) in the form of a hollow truncated cone with remote control receivers at its larger end face located in the working chamber opposite the output windows.

A method for controlling a quantum generator includes forming a parallel beam of electromagnetic radiation, collimating the formed parallel beam of electromagnetic radiation, and then converting it into a beam of circular cross section to supply a control signal to the remote control receivers of the main explosive charge.

A device for controlling a quantum generator contains a source of a parallel beam of electromagnetic radiation connected to a control unit, a main collimator installed at the output of a source of a parallel beam of electromagnetic radiation and optically coupled through an axicon with remote control receivers of the main explosive charge, and three flat mirrors.

The disadvantage of the technical solutions is the reduced power density of electromagnetic radiation delivered to the object.

The technical result from the use of the proposed technical solution is to increase the power density of electromagnetic radiation delivered to the object.

In accordance with the proposed technical solution, the indicated technical result is achieved by the fact that in the method of generating a pulse of electromagnetic radiation when it is delivered to an object, which includes generating a converging shock wave with a leading front of cylindrical shape to further influence the working medium, additionally inside a converging shock wave with a leading front of cylindrical the forms form a diverging shock wave with a leading front, coaxial to the front of the converging shock wave, getting in the region of convergence of the shock wave pulse of electromagnetic radiation in the form of a thin-walled cylinder for subsequent conversion to a pulse of electromagnetic radiation annular cross section, tapered along the conical surface with the vertex located in the region of the object.

In a quantum generator for generating a pulse of electromagnetic radiation, containing a working chamber with two output windows, filled with a working medium, and placed in the working chamber opposite the output windows, the main explosive charge in the form of a hollow truncated cone with remote control receivers at its larger end contains additional explosive charge in the form of a hollow cone with a remote control receiver at its apex, installed inside and coaxially to the truncated cone of the main explosive charge, while gly taper cones basic and additional explosive charges are equal, their tops are deployed in opposite directions, and the first outlet port of the working chamber arranged opposite the narrow end of the truncated cone of the main charge explosive is configured with a thickness that increases from the periphery toward the center towards the apex of said truncated cone.

In addition, the first exit window of the working chamber is made conical in shape.

In addition, the second output window of the working chamber is made with a mirror annular zone located opposite the lumen between the base of the hollow cone of the additional explosive charge and the smaller end of the truncated cone of the main explosive charge.

In addition, the mirror annular zone of the second window of the working chamber is made on its inner surface.

In the method of controlling a quantum generator, including the formation of a parallel beam of electromagnetic radiation, collimating the formed parallel beam of electromagnetic radiation and then converting it into a beam of circular cross section to supply a control signal to the remote control receivers of the main explosive charge, a part of the radiation is isolated from the formed parallel beam of electromagnetic radiation for subsequent collimating and supplying a control signal to a remote receiver managing additional explosive charge, thus supplying control signals to the remote control receivers of the main and additional explosive charges is performed with a delay relative to each other.

In a system for controlling a quantum generator containing a source of a parallel beam of electromagnetic radiation connected to a control unit, a main collimator installed at the output of a source of a parallel beam of electromagnetic radiation and optically coupled through an axicon to remote control receivers of the main explosive charge, and three flat mirrors, additionally a translucent mirror, an additional collimator and two electro-optical shutters, while a translucent mirror is mounted on the output The source of a parallel beam of electromagnetic radiation is placed obliquely to its optical axis and is optically coupled through successively mounted first, second and third flat mirrors with a remote control receiver for additional explosive charge, an additional collimator is installed between the second and third flat mirrors, and electro-optical shutters are mounted in front of the main and additional collimators and are connected to the control unit.

Figure 1 presents a quantum generator for generating a pulse of electromagnetic radiation, figure 2 is a system for controlling a quantum generator.

The quantum generator (see Fig. 1) contains a working chamber - 1, filled with a gaseous working medium - 2. In the chamber - 1 the main explosive charge in the form of a hollow truncated cone - 3 and the additional explosive charge in the form of a hollow cone - 4 are installed inside cone - 3 and coaxial to the latter, while the vertices of cones - 3 and 4 are turned in opposite directions relative to each other and are made with a taper angle α = arcsinV1 / V2, where V1 is the propagation velocity of the shock wave in the working chamber, and V2 is the burning velocity of the explosive (this condition is necessary to ensure partite straightness sectional front shock wave fronts arising after ignition BB). At the larger end of the truncated cone - 3 and on the top of the cone - 4 there are explosive ignition devices in the form of remote control receivers - 5, and in the chamber - 1 there is an exit transparent window - 6 with a mirror annular zone - 7 located on its inner surface opposite the lumen between the base of the cone - 4 and the smaller end of the truncated cone - 3, and opposite the last there is an output transparent window - 8 with a thickness increasing from the periphery to the center in the direction of the top of the truncated cone - 3 (window - 8 can be made with zhnoy surface of the conical or parabolic shape).

The method of generating a pulse of electromagnetic radiation when it is delivered to an object is as follows.

When a control signal is supplied in the form of electromagnetic radiation (not conventionally shown in Fig. 1) simultaneously to the remote control receivers - 5 explosive charges in the form of a hollow cone - 4 and a truncated hollow cone - 3, the latter are ignited, resulting in two cylindrical coaxially arranged and shock waves directed towards each other with front converging — I and diverging — II fronts. In the region of convergence of these shock waves as a result of their impact on the working medium - 2, an electromagnetic radiation pulse is formed in the form of a thin-walled cylinder with a diameter D _cf (with a height equal to the height of the cones - 3 and 4), propagating in two opposite directions in the direction of the windows - 6 and 8. One part of the radiation pulse falling onto the mirror zone - 7 of the window - 6, is reflected from the last, is summed with the second part of the pulse and is fed to the transparent window - 8 of conical shape. The total impulse, passing through the window - 8 (wedge-shaped in axial section), is refracted and, in the form of a pulse narrowing along the conical surface, is fed to the point - F, which is the apex of the above conical surface and, at the same time, the region of the object.

It should be noted that by forming the fronts - I and II with a delay of one relative to the other (which will be described below), it is possible to obtain pulses in the form of a thin-walled cylinder within the entire zone - 9 from the diameter D _min to D _max (cross is shaded in Fig. 1 -cross) with the convergence point of electromagnetic radiation located on the optical axis of the generator in the interval from the points - F ₁ to F ₂ , depending on the location of the object.

The control system of the quantum generator contains a sequentially installed source of parallel electromagnetic radiation, for example, in the form of a laser - 10 connected to the control unit - 11, an inclined translucent mirror - 12, a delay device for the radiation supply in the form of a first electro-optical shutter - 13 connected to the control unit - 11, and the main collimator - 14, optically coupled through a conical axicon - 15 with remote control receivers - 5 of the main explosive charge in the form of a truncated cone - 3. a transparent mirror - 12 through a flat mirror - 16, a second electro-optical shutter - 17, connected to the control unit - 11, a flat mirror - 18, an additional collimator - 19 and a flat mirror - 20 are optically coupled to the remote control receiver - 5 additional explosive charge in the form hollow cone - 4.

The method of controlling a quantum generator, according to the above diagram, is as follows.

From the control unit - 11 give a command to start the laser - 10 to form a parallel beam of control electromagnetic radiation. In this case (with open shutters - 13 and 17), the main beam of radiation passes through a translucent mirror - 12, the electro-optical shutter - 13, is expanded by a collimator - 14 and through a conical axicon - 15 is converted into a beam of annular cross-section and fed to receivers - 5 for igniting the main charge An explosive in the form of a truncated cone - 3. At the same time, a part of the radiation is released from the main beam of electromagnetic radiation with the help of an inclined translucent mirror - 12, which through the mirror is 16, the electro-optical shutter is 17 and the mirror is 18 expansion to the collimator - 19, followed by feeding through the mirror - 20 to the receiver - 5 to ignite an additional explosive charge in the form of a hollow cone - 4. As a result, after the simultaneous ignition of the main and additional explosive charges, two shock waves are formed with cylindrical coaxially located leading edges, moving towards each other. As a result of the impact of shock waves on the working medium - 2 in the region of their convergence (on the diameter - D _cf ), an electromagnetic radiation pulse is formed, which, after passing through the window - 8 of a conical shape, is collected (focused) at the point - F of the object location.

It should be noted that with a relative delay in the supply of control signals (by sending the appropriate commands to the electro-optical shutters - 13 and 17 from the control unit - 11) to the receivers - 5 of the main - 3 and additional - 4 charges, it is possible to form an electromagnetic radiation pulse at different diameters of the zone - 9, focusing the radiation at any point of the segment from the point - F ₁ to F ₂ depending on the location of the object (see figure 1).

From the above it follows that the proposed technical solution has an advantage over the known one, namely, due to the compression of a larger volume of the working medium (compression occurs along a cylindrical surface, and not along the line), the radiation power density in the delivery region increases significantly.

Therefore, the proposed technical solution when used gives a positive technical result - increases the power density in the field of radiation delivery.

Based on the application materials, the enterprise has currently carried out theoretical studies and modeling of physical processes, confirming the achievement of the specified technical result.

Claims (7)

1. A method of generating a pulse of electromagnetic radiation when it is delivered to an object, including generating a converging shock wave with a leading front of cylindrical shape, for influencing the working medium, characterized in that a diverging shock wave is formed inside the converging shock wave with a leading front of cylindrical shape with leading front, coaxial to the front of the converging shock wave, receiving in the region of convergence of the shock waves a pulse of electromagnetic radiation in the form of a thin-walled cylinder for after transforming it into a pulse of electromagnetic radiation of a circular section tapering along a conical surface with a vertex located in the region of the object. 2. A quantum generator containing a working chamber with two output windows, filled with a working medium, and placed in the working chamber opposite the output windows, the main explosive charge in the form of a hollow truncated cone with remote control receivers at its larger end, characterized in that it contains an additional explosive charge in the form of a hollow cone with a remote control receiver at its apex, mounted inside and coaxially to the truncated cone of the main explosive charge, while the taper angles of the main cones and additional explosive charges are equal, their vertices are turned in opposite directions, and the first exit window of the working chamber, located opposite the smaller end of the truncated cone of the main explosive charge, is made with a thickness increasing from the periphery to the center toward the apex of the truncated cone. 3. The quantum generator according to claim 2, characterized in that the first output window of the working chamber is conical in shape. 4. The quantum generator according to claim 2 or 3, characterized in that the second output window of the working chamber is made with a mirror annular zone located opposite the lumen between the base of the hollow cone of the additional explosive charge and the smaller end face of the truncated cone of the main explosive charge. 5. The quantum generator according to claim 4, characterized in that the mirror annular zone of the second window of the working chamber is made on its inner surface. 6. A method for controlling a quantum generator made according to claim 2, including forming a parallel beam of electromagnetic radiation, collimating the formed parallel beam of electromagnetic radiation with its subsequent transformation into a beam of circular cross section for supplying a control signal to the remote control receivers of the main explosive charge, characterized in that from the formed parallel beam of electromagnetic radiation, a part of the radiation is isolated for subsequent collimation and supply its signal to the remote control receiver supplementary explosive charge, thus supplying control signals to the remote control receivers of the main and additional explosive charges is performed with a delay relative to each other. 7. The control system of the quantum generator, made according to claim 2, containing a source of a parallel beam of electromagnetic radiation connected to the control unit, a main collimator installed at the output of the source of a parallel beam of electromagnetic radiation and optically coupled through an axicon with remote control receivers of the main explosive charge, and three flat mirrors, characterized in that it further comprises a translucent mirror, an additional collimator and two electro-optical shutters, while a transparent mirror is mounted at the output of a parallel electromagnetic radiation source, placed obliquely to its optical axis and optically coupled through successively mounted first, second and third flat mirrors with a remote control receiver for additional explosive charge, an additional collimator is installed between the second and third flat mirrors, and electro-optical the gates are mounted in front of the primary and secondary collimators and connected to the control unit.

Images