RU2498467C2 - Diode pumped optical amplifier head - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: diode pumped optical amplifier head has, in a housing, an active element in form of a rod, arrays of diode lasers placed on holders along the active element, and a cooling system having a glass tube encircling the active element to form a radial channel δ. Damping elements are placed at both ends of the glass tube. Cooling channels with inlet and outlet pipes, which form a double-loop cooling system, are placed in the housing, holders and arrays of diode lasers.

EFFECT: high laser radiation output energy and achieving stability of output energy parameters at pulse repetition frequency of up to 100 Hz.

2 cl, 7 dwg

Description

The invention relates to diode-pumped solid-state lasers, in particular, to pump elements and their cooling systems and can be used in the manufacture of laser technology.

A device for optical pumping of an amplification medium is known, comprising a housing in which an active element is placed in the form of a rod, laser diode arrays located on holders along the active element, and a cooling system with a glass tube enclosing the active element. The device also contains a cooling unit for the matrix of laser diodes in the form of a sleeve surrounding the matrix of laser diodes, and the holders are made in the form of segments of the ring (US patent No. 5521936, H01S 3/091, 1995).

In this device, the heat removal from laser diodes is quite simply organized: the use of additional internal cooling channels is not required, the heat is removed from the heated structural elements by the flow of refrigerant.

However, it is necessary to ensure good waterproofing of the laser diodes from the refrigerant. A negative factor with this cooling method is that it is possible to form stagnation zones in the coolant flow near the walls of the liner. This reduces the heat removal efficiency, therefore, negatively affects the spectral-lasing characteristics of the laser diodes of the pump elements.

The closest analogue of the claimed invention, selected as a prototype, is an optical amplifier with diode pumping, consisting of a rod located in the active element body, laser diode arrays located in holders along the active element, and a cooling system containing a glass tube covering active element with the formation of a radial channel, damping elements mounted on both ends of the glass tube, and a network of cooling channels located in the housing, holding models and matrices of laser diodes, with input and output nozzles. The matrix of laser diodes is made in the form of blocks of lines of laser diodes and is located at an angle of 90 ° to the axis of the active element, gaskets are used as damping elements (US patent No. 6101208, H01S 3/0941, 1997).

In this device, the cooling of the active element and the matrix of laser diodes occurs by maintaining a high flow rate of the coolant. Also, the implementation of constant monitoring of the temperature of the coolant allows you to extend the life of the diodes and provide constant and stable output parameters of the optical amplifier head.

However, uneven and incomplete filling of the active medium with light leads to the formation of isolated excitation regions, the appearance of thermal stresses inside the active element, which can lead to its failure. The uneven illumination of the active element also leads to a decrease in the pump efficiency and output laser beam power. The location of the cooling channels in the blocks of rulers of laser diodes is not optimal, since the distance from the cooled surface of the line of laser diodes to the cooling channels is not minimal, as a result of this, the efficiency of heat removal from the heated surface of the line of laser diodes decreases and an increase in the speed of the refrigerant is required. This can lead to a decrease in the quality of cooling of laser diodes and a drop in the power of the output laser beam.

The technical result obtained by using the proposed technical solution is to increase the output energy of laser radiation, achieving stability of the output energy parameters at a pulse repetition rate of up to 100 Hz.

The specified technical result is achieved in that in an optical amplifier head with diode pumping, consisting of a rod placed in the active element body, laser diode arrays located on the holders along the active element, and a cooling system containing a glass tube enclosing the active element with the formation radial channel δ, damping elements mounted on both ends of the glass tube, and a network of cooling channels located in the housing, holders and matrices of laser diodes, with inlet and outlet nozzles, the feature is that the housing is made in the form of a hexagon, on the outer surface of each face of which a hole is made to accommodate the holder, on the edge of which, facing the active element, the laser diode arrays are installed, the cooling system is made in the form of two independent circuits, cooling channels of one circuit - cooling of the active element connect additional inlet and outlet pipes to the radial channel δ through damping elements made in the form of bellows s, and the other cooling circuit - comprises a matrix of laser diodes formed in the housing and connected to the inlet and outlet collectors of the input and output of which are located coolant channels connected to the channels provided in each holder and laser diode arrays.

To reduce light losses during illumination of the active element and to increase the pump intensity, an antireflection coating is applied to the surface of the glass tube.

The implementation of the cooling system from two independent cooling circuits: for the active element and the matrix of laser diodes located around the optical axis of the active element in increments of 60 °, it was possible to regulate and maintain the required temperature, as well as organize more efficient heat removal from the heated surfaces, and minimize losses pump radiation power. As a result, the pumping efficiency of the active medium was increased, the energy stored in the population inversion in the volume of the active medium was increased, which led to an increase in the output energy of laser radiation and the stability of the output energy parameters at a pulse repetition rate of up to 100 Hz.

When conducting analysis of the prior art, including searching by patent and scientific and technical sources of information, and identifying sources containing information about analogues of the claimed invention, no analogues were found that are characterized by signs that are identical to all the essential features of this invention. The definition from the list of identified analogues of the prototype as the closest in the set of essential features of the analogue allowed us to identify the set of essential distinguishing features in relation to the applicant's technical result in the claimed device set forth in the claims.

Therefore, the claimed invention meets the condition of "novelty."

To verify the conformity of the claimed invention with the condition "inventive step", the applicant conducted an additional search for known solutions in order to identify signs that match the distinctive features of the claimed device from the prototype. As a result of the search, no technical solutions with these characteristics were identified. On this basis, we can conclude that the claimed invention meets the condition of "inventive step".

Figure 1 shows a longitudinal section of an optical amplifier head with diode pumping, made along the axis of the active element.

Figure 2 shows a cross section of an optical amplifier head with diode pumping, made at half its length.

Figure 3 shows the holder with matrices.

In figure 4. shows a section aa of Fig.3.

Figure 5 shows the cooling system of the active element in the assembly without flexible hoses.

Figure 6 shows a side view of an optical amplifier head with diode pumping, without side covers.

Figure 7 shows a General view of the proposed optical amplification head with diode pumping.

The optical amplifier head with diode pumping contains a housing 1 made in the form of a hexagon, in which an active element 2 YAG: Nd is installed in the form of a rod. On the outer surface of each face of the housing 1 there is a technological hole 3 in which a holder 4 for the matrices 5 of laser diodes is placed. On the face of each holder 4, which faces the active element, there is a seating surface k for fixing the matrices 5 of laser diodes. For a more uniform illumination of the active element on each holder 4, two arrays of 5 laser diodes are installed located around the optical axis of the active element 2 with a step of 60 ° (Figs. 1-4).

The cooling system is made in the form of two independent circuits: the cooling circuit of the active element 2 and the cooling circuit of the matrices 4 of the laser diodes with input and output pipes 6. The cooling system contains a network of cooling channels a, c, d, e located in the housing 1, holders 4 and matrices of 5 laser diodes.

The cooling circuit of the active element contains a glass tube 7, damping elements in the form of bellows 8 mounted on both ends of the glass tube 7, flanges 9, additional inlet and outlet pipes 10 with inlet flexible hoses 11. The glass tube 7 covers the active element 2, forming a radial channel δ for the passage of refrigerant. The cooling channels a of this circuit, formed by flanges 9 and an active element 2, connect additional inlet and outlet pipes 10 with a radial channel δ through bellows 8. Flanges 9 and bellows 8 form a single assembly to which pipes 10 with flexible hoses 11 are attached (Fig. 5).

The cooling circuit of the laser diode arrays comprises square-shaped annular collectors 12 made in the housing 1, which are divided into cooling channels from the housing 1, connected to the channels d made in each holder 4, connected to the channels e made in each matrix 5 of the laser diodes, and the inlet and outlet nozzles 6 with flexible hoses 13. The collectors 12 are connected to the inlet and outlet nozzles 6 (figure 1).

Optical amplification head also contains spring holders 14, intended for fastening the cooling system assembly with the active element 2 to the housing 1 (Fig.6).

The optical amplifier head contains an electrical connector for connecting a power supply (not shown in Fig.), A casing 15 and side covers 16 that are attached to the housing 1 (Fig.7).

To reduce light losses during illumination of the active element and to increase the pump intensity, a multilayer dielectric antireflective coating is deposited on the surface of the glass tube 7. ^v

The device operates as follows. A voltage is supplied from the power supply to the matrices 5 of the laser diodes, the matrices begin to generate pump radiation, which, passing through the glass tube 7 and the coolant of the active element 2, is absorbed by the active medium, where part of the absorbed pump energy is spent on heat loss. In quasi-continuous operation, the heat dissipation power is quite high, therefore, cooling of the active element is required.

The refrigerant is supplied through a supply hose 11 connected to the inlet pipe 10 to the cooling circuit of the active element 2, enters the bellows 8. Then the refrigerant through the channel a enters the radial channel 5 and passes along the active element 2, contacting and cooling it with its surface. Passing along the active element 2, the refrigerant at its opposite end is discharged from the optical head in a symmetrical design: through the channel, the refrigerant enters the bellows 8, then through the pipe 10 and the flexible hose 11 is discharged from the optical amplification head.

In pump elements made in the form of arrays of 5 laser diodes, part of the electrical energy is spent on heat loss, so the matrices also need to be cooled.

The cooling of the matrices of 5 laser diodes is as follows. The refrigerant is supplied through a supply flexible hose 13 connected to the inlet pipe 6 and enters the square-shaped inlet manifold 12 inside the housing 1. From the manifold 12, the refrigerant enters six cooling channels c, each of which is used to supply refrigerant to the holder 4 of the 5 matrices of 5 laser diodes connected to the channels d located inside each holder 4 and connected to the channels e located inside the matrices 5 of laser diodes. The refrigerant passing through the channels d and e cools all matrices of 5 laser diodes. Further, the refrigerant, having passed each holder of 4 matrices 5 and having taken away excess heat from the matrices 5, enters the system of six channels with a system symmetrical to the refrigerant supply. From each channel, the refrigerant enters the square output manifold 12 located on the opposite side of the housing 1. Next, the heated fluid through the pipe 6 through a flexible hose 13 is discharged from the optical amplifier head.

An advantage of the invention is that by arranging the matrix of laser diodes in the immediate vicinity of the surface of the glass tube, the illuminator is more efficient. Due to the symmetry of the arrangement of the pump elements in the optical head, uniform illumination was achieved over the cross section of the active element, which ensured uniformity over the gain and heat dissipation cross sections. Thus, a weak signal in one pass is amplified 25 times, and the stored energy in the population inversion reaches 1.4 J.

The design of the collectors and the cooling circuit of the laser diode arrays ensures the distribution of refrigerant along the channels of the holders with the same flow rate, which allows for the same cooling mode of all diode pump elements. The design of the channels leading the coolant to the cooling jacket allows for uniform heat removal along the surface of the active element, which, combined with the uniformity of heat generation, determines the symmetry of the temperature distribution over the cross section of the active element. As a result, the optical amplifier head can operate at a pulse repetition rate of up to 100 Hz.

Thus, the data presented indicate that when using the claimed invention, the following combination of conditions:

- a tool embodying the claimed device in its implementation, is intended for use in the electronic and optical-mechanical industry in the manufacture of devices with high power for medicine, technology and other purposes;

- for the claimed device in the form in which it is described in the claims, the possibility of its implementation is confirmed. Therefore, the claimed invention meets the condition of "industrial applicability".

Claims (2)

1. Optical amplifier head with diode pumping, consisting of a rod placed in the active element body, laser diode arrays located on holders along the active element, and a cooling system containing a glass tube enclosing the active element with the formation of a radial channel δ, damping elements mounted on both ends of the glass tube, and a network of cooling channels located in the housing, holders and arrays of laser diodes with input and output tubes, characterized in that the housing is made in the form of a hexagon, on the outer surface of each face of which a hole is made to accommodate the holder, on the edge of which is facing the active element, laser diode arrays are installed, the cooling system is made in the form of two independent circuits, the cooling channels of one circuit - cooling the active element are connected additional inlet and outlet nozzles with a radial channel δ through damping elements made in the form of bellows, another cooling circuit - laser diode matrices contains made in the housing and connected to the inlet and outlet nozzles of the input and output manifolds, from which cooling channels exit connected to the channels made in each holder and matrices of laser diodes. 2. The optical amplification head according to claim 1, characterized in that an antireflective coating is applied to the surface of the glass tube.

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