RU2807949C1 - Method and device for checking the integrity of optical and electrical circuits in laser initiation systems for energy materials - Google Patents

Abstract

FIELD: measuring technology.

SUBSTANCE: invention can be used in products for defence, special and civil purposes. The claimed method for checking the integrity of optical and electrical circuits in laser initiation systems for energy materials consists in using one laser diode, one optical fibre between the laser diode and the laser initiation unit for initiation and verification modes of the optical circuit, and a laser diode power supply having two independent current sources: a low current source and a high current source, which receive control commands from the controller. When checking the integrity of the laser diode and the optical path, a low current source is turned on, the laser diode operates at low currents, compared to the initiation mode, low-power radiation propagates along the optical path to the divider and is divided, after which part of the radiation propagates to the reflective coating in the laser initiation unit, is reflected from the specified coating and enters the first photodetector through the same optical path, and the other part of the radiation after the splitter goes directly to the second photodetector, after which the signals received from these photodetectors are transmitted to the controller to check the integrity of the optical circuits in laser initiation systems. When checking the operability of the power source itself, a high current source is turned on, to which the electrical equivalent of the laser diode is connected, whereas the laser diode is first turned off, the signal from the equivalent of the laser diode is transmitted to the controller to check the integrity of electrical circuits in laser initiation systems.

EFFECT: increasing the reliability of the laser initiation system by using the integrity control means that make up the system of optical and electrical circuits.

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Description

The invention relates to the field of measurement technology in terms of monitoring the integrity of optical circuits, as well as checking adjacent electrical circuits, and can be used in systems for laser initiation of pyrotechnic means. These systems are used in products of rocket and space, aviation, naval, special equipment, as well as in the mining and coal mining industries, seismic exploration, oil production during well perforation and in construction. In such applications, fiber-optic laser initiation systems require repeated use and, therefore, such systems require monitoring and verification of the integrity of the optical path and the functionality of adjacent electronics.

Current inventions for monitoring the integrity of hybrid (fiber optic and electrical) circuits have a number of disadvantages, most of them due to the need to use external testing devices. This external test method is described in the publication “Optical pyrotechnology for launchers and satellites” (ICSO 2014; DOI: 10.1117/12.2304215). This method of checking integrity requires temporary external installation in the system and the presence of additional optical connectors. Such interference can lead to displacement or damage to circuit components, and also complicates the inspection procedure and increases the size of the system.

There is a verification method described in the publication “Optical Built-in-Test (BIT) for Laser Initiation Systems / Built-in optical test for laser initiation systems” (2002-3797. 38th AIAA/ASME/SAE/ASEE Joint Propulsion Conference & Exhibit. July 2002. DOI: 10.2514/6.2002-3797). The publication describes the integrated testing of the optical components of such systems by measuring the levels of reflected radiation recorded by a photodetector, for which the system uses a radiation source, two fibers to transmit and reflect the radiation, and a laser initiation assembly with two lenses and a reflective coating. The disadvantage of this method is the lack of checking the electronics, as well as incomplete checking of the optical part (one of the two gradient lenses in the laser initiation unit is checked).

An invention called “Method of initiating a multi-channel laser initiation system”, No. 2752408 (IPC F42B 3/113, published 08/05/2020) is also known. This method consists of monitoring the optical path of the system and involves the initiation of igniting compositions. The control unit supplies an electrical signal to laser emitters, which generate a laser pulse propagated along the optical path. The path has two fibers going to the laser igniters for each channel. Control and initiation pulses are delivered along the first fiber; control and initiation pulses reflected from the laser igniter are propagated through the second fiber in the mode of checking optical circuits and the state of the system as a whole (initial, activated). In this case, the control and initiating pulses are identical in amplitude and differ in duration. The path between the laser emitter and the laser igniter contains an optical switch. The optical switch is a drum with light filters (to attenuate the radiation of the control pulse) and empty windows (for the passage of radiation to initiate the laser igniter; RU2691381, published 06/13/2019). When the drum is turned using an electromechanical device, the light filter is changed to the window. The movement of the light filter in the optical switch determines two positions: open or closed. In the open state, the optical switch ensures the transmission of an optical pulse from the laser emitter with minimal optical losses, and in the closed state - with maximum optical losses. Control of the optical path is carried out with the initial closed optical switch, which absorbs most of the laser energy, by first delivering control and then initiating pulses, which are reflected from the laser igniter. The reflected pulses enter the second fiber and arrive at the photodetector. To initiate, the optical switch is moved to the “open” position, after which the optical path is controlled by applying a control pulse and recording the reflected pulse with a photodetector. After monitoring the optical path, an initiating pulse with a long duration is supplied to the ignition device. After initiation, the activation of the initiating device is checked with a control pulse.

The advantage of this method is control of the optical path before initiation, checking the functionality of the laser and associated electronics, control of operation after initiation, as well as the presence of an optical switch, which acts as an additional barrier in the optical path between the laser emitter and the laser igniter to increase the safety of the system.

The disadvantages of this method include the complexity of the optical switch design. The presence of moving parts reduces the reliability of the system and requires a complex system of angular positioning and fixation of the drum relative to the laser emitter. Electronic errors due to electromagnetic interference or other factors can lead to incorrect position of the optical switch. As a result, the verification procedure is complicated: first, the closed state of the optical switch is checked with a control pulse, then an initiating pulse is applied to check the optical path, which is also a disadvantage, because During this time, the optical switch may open (drum displacement) and lead to unauthorized initiation. Another disadvantage is the possibility of degradation of the radiation resistance of the filter when laser pulses are repeatedly passed through it. In addition, the disadvantages include the use of two fibers for delivering and reflecting optical radiation. This can reduce the manufacturability of joining fibers with a laser igniter, and also increases the size and reduces the reliability of the laser initiation system, in particular, it can lead to false negative test results (for example, in the case when the first fiber is intact, but there is a break in the second).

The claimed invention “Method for checking the integrity of optical and electrical circuits in laser initiation systems for energetic materials” is aimed at solving the problem of checking hybrid circuits in laser initiation systems by means of a built-in test, which makes it possible to increase the reliability of the operation of such systems. The built-in test has a number of advantages compared to external tests: it does not require additional connectors for connection, it is built into the system, and allows testing immediately before initiation.

The effectiveness of the verification by the claimed method is achieved by conducting a comprehensive check of the units and components of the initiation system - checking the laser diode and its power source, checking the optical components that deliver laser radiation to the laser initiation unit, and checking the volumetric optics of the initiation unit. This also occurs by using a single laser diode in two high/low optical power modes to initiate/test fiber systems for their integrity and by using a single fiber to initiate and test the optical path from the laser source to the laser initiation node.

Increasing the safety of testing laser initiation systems is achieved by disconnecting the laser diode from the high current power source during testing, as well as by eliminating electromechanical devices and an additional optical path from the optical circuit, which makes it possible to implement a simpler, compared to the prototype, circuit diagram for checking the integrity of optical and electrical circuits.

The submitted application uses 4 drawings, a brief description of which is presented below.

In FIG. Figure 1 shows a block diagram of a method for checking the integrity of optical and electrical circuits.

In FIG. Figure 2 shows a block diagram of the power source for the laser diode.

In FIG. Figure 3 shows an enlarged image of the laser initiation unit, with a schematic plot of the ray path in a gradient lens, on the output surface of which a reflective coating is applied.

In FIG. Figure 4 shows an enlarged image of the laser initiation unit using additional protective glass, on the output surface of which a reflective coating is applied. Schematic diagram of the ray path in such a system: gradient lens - coated glass.

A method for checking the integrity of optical and electrical circuits in laser initiation systems for energetic materials (Figure 1) consists of a power source for laser diode 1, laser diode 2. During testing, the diode operates in low-power mode, i.e. The current consumption from power supply 1 is at the milliamp level. The output optical power of the laser diode in this mode is at the microwatt level, is clearly visible by control photodetectors 3, 4 and is several orders of magnitude less than that required to initiate a sample of the igniter composition. Laser diode 2 is connected to the fiber divider 5 via fiber 6. The output fiber 7 of the divider 5 is supplied to the laser initiation unit 8. At the fiber outputs 9 and 10 of the divider there are photodetectors 3 and 4, which transmit the received signals to the controller 11.

The principle of operation of the claimed invention (Fig. 1): in the circuit test mode, the controller 11 issues a command +U _{control 1} to turn on the small current source 101 (Fig. 2), located in the power source 1. The power source supplies a small electric current to the laser diode 2 , which starts working in low-power mode. The radiation passes along fiber 6 through a fiber splitter 5, in the divider it is divided with a given division ratio between two output fibers 7 and 10; then through the output fiber 7 of the divider 5 it enters the laser initiation unit 8. Inside the laser initiation unit 8 (Fig. 3) a focusing gradient lens 801 is installed, which is a glass cylinder in which the radiation incident on the input surface propagates along the cylinder and is focused on the output surface lens on which a reflective coating 802 is applied. The focusing gradient lens 801 is installed close to the sample of the igniter composition 803. The fiber 7, located in the ceramic ferrule 804, is brought close coaxially to the lens 801. The radiation leaves the fiber 7 and enters the lens 801, the lens focuses radiation onto the reflective coating 802. The radiation partially reflected from the coating falls back into the fiber 7. Next, the reflected radiation passes through the fiber splitter 5 (Fig. 1) and propagates along the fiber 9, which is connected to the photodetector 3. The photodetector 3 supplies the received signal to the controller 11. Direct radiation from the laser diode 2 from the divider 5 through the fiber 10 is supplied to the photodetector 4. The controller 11 compares the value of the reflected radiation from the photodetector 3 with the value of the direct radiation of the laser diode coming from the photodetector 4. The resulting difference between the two signals determines the presence or violation of the integrity of the optical circuit, as well as the performance of the laser diode itself 2.

Photodetector 3 receives reflected radiation from the laser initiation unit. The integrity of the optical circuit is checked by the level of the electrical signal at the photodetector. Photodetector 4 receives direct radiation directly from laser diode 2. The functionality of the laser diode is checked by the level of the electrical signal at the photodetector.

After checking the optical part, the controller 11 proceeds to checking the high current source 102 (Fig. 2), which is part of the power source 1. The high current source is intended for the mode of initiating a portion of igniter compositions. To perform the test, instead of a laser diode, an electrical equivalent 103 is connected to the high current source 102 as a load. From the controller 11, the +U _{control 2} command is issued to turn on the high current source 102. Next, the necessary measurements are carried out, the results of which determine the operability of the current source.

Options for manufacturing a reflective coating 802 for the laser initiation unit 8 (Fig. 3):

1.1 translucent dielectric coating. In the test mode, low-power radiation is partially reflected from the coating and directed into fiber 7; in the initiation mode, high-power radiation is mainly transmitted to a sample of igniter composition 803;

1.2 opaque metallic coating. In the test mode, low-power radiation is mainly reflected from the coating and directed into fiber 7; in the initiation mode, high-power radiation melts a section of the coating and is mainly passed onto a sample of igniter composition 803.

Additionally, a protective glass 805 can be installed in the laser initiation unit (Fig. 4) between the gradient lens 801 and the igniter composition sample 803, which protects the gradient lens during a sharp increase in pressure at the moment of initiation of the igniter composition sample. In this process, coating 802 is applied to the exit surface of the glass. The thickness of the glass 805 and the length of the gradient lens 801 are selected so that the transmitted radiation is focused on the output surface of the glass 805, and the radiation reflected from the coating 802 falls back into the fiber 7.

Claims (3)

1. A method for checking the integrity of optical and electrical circuits in laser initiation systems for energetic materials, which consists in using one laser diode, one optical fiber between the laser diode and the laser initiation unit for initiation and optical circuit testing modes, and a laser diode power supply, incorporating two independent current sources: a low current source and a high current source, receiving control commands from the controller; in this case, in the mode of checking the integrity of the laser diode and the optical path, a low current source is turned on, then the laser diode operates at low currents, compared to the initiation mode, low-power radiation propagates along the optical path to the divider, is divided, after which part of the radiation propagates to the reflective coating in the laser initiation unit, is reflected from the specified coating and along the same optical path hits the first photodetector, and the other part of the radiation after the divider goes directly to the second photodetector, after which the signals received from the specified photodetectors are transmitted to the controller to check the integrity of the optical circuits in laser initiation systems; in the mode of checking the functionality of the power source itself, a high current source is turned on, to which the electrical equivalent of a laser diode is connected, while the laser diode is first turned off, the signal from the laser diode equivalent is transmitted to the controller to check the integrity of electrical circuits in laser initiation systems. 2. A method for checking the integrity of optical and electrical circuits according to claim 1, characterized in that the reflective coating in the laser initiation unit is made in the form of a translucent dielectric coating or an opaque metal coating. 3. A method for checking the integrity of optical and electrical circuits according to claim 1, characterized by the presence in the laser initiation unit of glass with a reflective coating, which is located between the gradient lens and a sample of the igniter composition, which acts as a protective element for the gradient lens during the initiation mode, while the dimensions of the lens and the glass is selected in such a way that the transmitted radiation is focused on the output surface of the glass with a reflective coating.

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