ONLINE DETECTION DEVICE AND METHOD FOR UNDERWATER ELEMENTS BASED ON LIBS TECHNOLOGY

Abstract

An online detection device underwater elements includes an LIBS system in a sealing pressure chamber and an external airflow control system. The airflow control system has a gas probe bin and a gas source. An opening is formed at one end of the gas probe bin while the other end and the sealing pressure chamber are hermetically partitioned through a glass window. A laser in the LIES system outputs laser to an underwater object surface to be detected for generating plasma spectra. A spectrometer collects plasma spectra returned along an original optical path. When the device operates in water, the balance gas storage tank produces gas with the same pressure as underwater. A flow model is invoked according to the current water pressure to accurately control the air flow rate to form a stable gas environment in the gas probe, which improves the plasma excitation and collection efficiency.

Claims

1. An online detection device for underwater elements based on LIB S technology, characterized by comprising a sealing pressure chamber (1), an LIBS system arranged in the sealing pressure chamber and an external airflow control system (2); the LIB S system is used for exciting and collecting laser induced breakdown spectroscopy signals; and the airflow control system (2) is used for generating an underwater gaseous detection optical path.

2. The online detection device for underwater elements based on LIBS technology according to claim 1, characterized in that the airflow control system (2) and the sealing pressure chamber (1) are hermetically partitioned through a glass window (26).

3. The online detection device for underwater elements based on LIBS technology according to claim 1, characterized in that the airflow control system (2) comprises a gas probe bin (21) and a gas source (22); the gas source (22) is connected with the gas probe bin (21) through a gas source pipeline; an opening (2101) at one end of the gas probe bin (21) is used for laser output and water vapor discharge; and a gaseous environment is formed within a range from the front end of an LIBS detection system to a detection object; the gas source (22) contains an airbag (2201) and a piston (2202); seawater pushes the piston (2202) to make the internal air pressure of the airbag (2201) identical with external water pressure, and high pressure gas is drawn out through an air pump (2203); and the pressure sensor (2204) is used for monitoring the internal pressure of the airbag (2201) in real time.

4. The online detection device for underwater elements based on LIBS technology according to claim 1, characterized in that the airflow control system (2) further comprises a pressure sensor (25) arranged outside the gas probe bin (21), and a flow control valve (23) arranged on the gas source pipeline; the pressure sensor (25) is used for detecting water pressure outside the gas probe bin (21), and the flow control valve (23) is used for controlling the flow of the gas source (22); a controller (1201) monitors current water pressure and invokes a prefabricated flow model to accurately control the opening of the flow control valve (23).

5. The online detection device for underwater elements based on LIBS technology according to claim 1, characterized in that the LIBS system comprises an optical path unit (11) and an excitation and acquisition control unit (12); the excitation and acquisition control unit (12) is used for triggering an internal laser (1202) to output laser light to pass through an optical path assembly of the optical unit (12), the glass window (26), the opening (2101) at one end of the gas probe bin (21) and an underwater object surface to be detected successively to generate plasma spectra, and the spectrometer (1203) in the excitation and acquisition control unit (12) collects plasma spectra.

6. The online detection device for underwater elements based on LIBS technology according to claim 5, characterized in that the excitation and acquisition control unit (12) comprises a controller (1201), and a laser (1202), a spectrometer (1203) and a time sequence controller (1204) which are connected with the controller; the controller (1201) outputs a signal for controlling the laser (1202) to output laser light and controlling the spectrometer (1203) to collect the plasma spectra; and the time sequence controller (1204) is used for controlling a working time sequence of the laser (1202) and the spectrometer (1203).

7. The online detection device for underwater elements based on LIBS technology according to claim 5, characterized in that the optical path unit (11) comprises a focusing lens (1102) arranged in the incidence direction of a laser optical path, so that the laser is focused on the object surface to be detected outside the opening (2101) at one end of the gas probe bin (21), and the plasma spectra excited on the object surface to be detected return along the optical path, are reflected by a dichroscope (1101), pass through a collection lens (1103), and then converge into the spectrometer (1203); the focusing lens (1102) is arranged on a linear module (1104); a motor on the linear module (1104) is connected with the controller (1201); and the motor rotates to drive the focusing lens (1102) to move along the direction of the optical path on the linear module (1104), so as to change focal length and focus the laser light on the object surface to be detected.

8. The online detection device for underwater elements based on LIBS technology according to claim 1, characterized in that a video acquisition camera (24) is also arranged in the sealing pressure chamber (1) for observing image pictures inside a gaseous optical path and uploading to the controller (1201).

9. The online detection device for underwater elements based on LIBS technology according to claim 8, characterized by further comprising: the controller (1201) forwards the collected plasma spectral data to an upper computer, or analyzes the collected plasma spectral data to obtain the type and relative content of chemical elements in current underwater solid or water to be detected.

10. An underwater online detection method based on LIBS technology for the online detection device for underwater elements based on LIBS technology of claim 1, characterized in that the underwater online detection method based on LIBS technology shall comprise the following steps: the step of establishing the flow model: placing an overall system in a high-pressure laboratory module under a laboratory environment; changing water pressure; monitoring the current water pressure by the pressure sensor (25); regulating the air supply by controlling the flow control valve (23); observing underwater bubbles that emerge through the video acquisition camera (24); and establishing an underwater stable flow model of water pressure and control valve opening under the condition that the bubbles are stable and a few bubbles are discharged; the step of air blowing and water drainage: detecting a current water pressure value by the pressure sensor (25) in real time; opening the air pump (2203) and the flow control valve (23), supplying gas into the gas probe bin (21) through the gas source (22), and draining the water in the gas probe (21) by the gas through a vent hole (2101) in the front end of the probe; the step of stabilizing an air pressure environment: monitoring water pressure outside the gas probe bin (21) by the controller (1201) through the pressure sensor (25), invoking a prefabricated flow model and regulating the air supply by controlling the opening of the flow control valve (23) according to the current water pressure so that a stable air pressure environment is maintained in the gas probe bin (21); the step of excitation and acquisition: controlling, by the controller (1201) in the sealing pressure chamber (1), the laser (1202) to output laser light to pass through the optical path of the optical unit (11), the glass window (26), the opening (2101) at one end of the gas probe bin (21) and the irradiated underwater object surface to be detected, and controlling the spectrometer (1203) to collect plasma spectral data into the controller (1201).

Description

DESCRIPTION OF DRAWINGS

[0027] FIG. 1 is a structural schematic diagram of a device of the present invention;

[0028] FIG. 2 is a flow chart of a method of the present invention.

[0029] Wherein 1 sealing pressure chamber; 11 optical path unit; 1101 dichroscope; 1102 focusing lens; 1103 collection lens; 1104 linear module; 12 excitation and acquisition control unit; 1201 controller; 1202 laser; 1203 spectrometer; 1204 time sequence controller; 2 airflow control system; 21 gas probe bin; 22 gas source; 2201 airbag; 2202 piston; 2203 air pump; 2204 air pressure sensor; 23 flow control valve; 24 video acquisition camera; 25 pressure sensor; 26 glass window.

DETAILED DESCRIPTION

[0030] To make the purpose, the technical solution and the beneficial effects of the present invention more clear, the present invention will be further described below in detail in combination with the examples. It should be understood that specific embodiments described herein are only used for explaining the present invention, not used for limiting the present invention. The present invention will be described in detail below in combination with the drawings.

[0031] In view of the existing technical problems, the present invention provides an online detection device and method for underwater elements based on LIBS technology.

[0032] The device comprises a sealing pressure chamber 1 and an airflow control system 2. An LIBS system in the sealing pressure chamber 1 is used for exciting and collecting laser induced breakdown spectroscopy signals; and the airflow control system 2 is used for generating an underwater gaseous detection optical path. The LIBS system comprises an optical path unit 11 and an excitation and acquisition control unit 12; a laser in the excitation and acquisition control unit 12 outputs laser light to pass through the optical path assembly of the optical unit 12, the glass window 26, the opening 2101 at one end of the gas probe bin 21 and an underwater object surface to be detected successively to generate plasma spectra, and the spectrometer in the excitation and acquisition control unit 12 collects plasma spectra returned along an original optical path. The excitation and acquisition control unit 12 comprises a controller 1201, and a laser 1202, a spectrometer 1203 and a time sequence controller (1204) which are connected with the controller. The optical path unit 11 comprises a dichroscope and a focusing lens 1102 arranged successively in the incidence direction of the laser optical path, so that the laser is focused on the object surface to be detected outside the opening 2101 at one end of the gas probe bin 21, and the plasma spectra excited on the object surface to be detected return along the optical path, are reflected by the dichroscope, pass through a collection lens 1103, and then converge into the spectrometer 1203. The focusing lens 1102 is arranged on a linear module 1104; a motor on the linear module 1104 is connected with the controller 1201; and the motor rotates to drive the focusing lens 1102 to move along the direction of the optical path on the linear module 1104, so as to change focal length and focus the laser light on the object surface to be detected. The airflow control system 2 comprises a gas probe bin 21 and a gas source 22; the gas source 22 is connected with the gas probe bin 21 through a gas source pipeline; an opening 2101 is formed at one end of the gas probe bin 21, and the other end and the sealing pressure chamber 1 are hermetically partitioned through a glass window 26. A flow control valve 23 is arranged on the gas source pipeline. The flow control valve 23 is connected with the controller 1201, and a pressure sensor 25 is arranged outside the gas probe bin 21, which is connected with the controller 1201. The gas source 22 contains an airbag 2201, a piston 2202, an air pump 2203 and an air pressure sensor 2204. A video acquisition camera 24 is also arranged in the sealing pressure chamber (1). A power module, or a power supply connected to the outside are also arranged in the sealing pressure chamber. The pressure sensor 25 is connected with the controller 1201 in the sealing pressure chamber 1 through a watertight cable. The gas supply pipeline is a pressure-proof gas pipe. The power module is connected with the external power supply through the watertight cable.

[0033] During work, firstly, an underwater manipulator controls the detection system, so that the front end of the gas probe bin 21 is attached to the surface of the target to be detected. The external pressure of the gas probe bin 21 is detected by the controller 1201 through the pressure sensor 25, and a prefabricated flow model is invoked to accurately control the opening of the flow control valve 23 so that a stable gas environment is formed in the gas probe. The controller 1201 controls the laser 1202 to emit high energy pulse laser light, and the laser light passes through the optical path assembly in the optical path unit 11, penetrates through the glass window and the gas probe bin 21, and converges on the surface of the target to be detected to generate plasma. The plasma emission light enters the optical path in the optical path unit 11 through the gas probe bin 21 and is coupled to the spectrometer by an internal lens group. The linear module 1104 is used for adjusting the convergence focal length; the time sequence controller 1204 is used for controlling interval time between the laser 1202 and the spectrometer 1203; the video acquisition camera 24 is used for observing the detecting situation. The spectral line data collected by the spectrometer 1203 is uploaded to a remote data server by the controller 1201 for analysis, so as to realize the in-situ online detection of underwater target element components.

[0034] As shown in FIG. 1, the online detection device for underwater elements based on LIBS technology provided by the present invention comprises: [0035] the sealing pressure chamber 1 which is made of titanium alloy and has an appearance of a cylindrical structure to prevent water corrosion and withstand high pressure. A quartz optical window 26 is arranged outside the pressure chamber and connected with the gas probe bin 21 for exciting plasma and collecting spectral signals. At the same time, a waterproof cable interface is arranged outside the pressure chamber 1 for connecting an external sensor with water equipment for communication and power supply. The controller 1201 is arranged in the sealing pressure chamber 1. The controller 1201 is a device such as an industrial personal computer used for control, calculation and data communication. The industrial personal computer can directly analyze the spectral data and upload the analysis results to the remote server. A CPU thereof is a quad Core processor, and the main frequency should be higher than 1.8 GHz. The system memory should be higher than 4G. A pulse laser 1202 is arranged in the sealing pressure chamber 1 for plasma excitation. An optical fiber laser with minimal divergence angle is selected as the laser, and has characteristic parameters: output wavelength of 1064 nm, single pulse energy of 1-3 mJ, and frequency of 10-40 KHz. The time sequence controller 1204 is arranged in the sealing pressure chamber 1, and can be used to precisely control opening time between the pulse laser 1202 and the spectrometer 1203. The time range comprises 1 μs-10 μs, and the time control accuracy is 10 ns. The spectrometer 1203 is arranged in the sealing pressure chamber 1. The spectrum collection range of the spectrometer 1203 should be between 160 nm and 1200 nm, and the incident light ray is directly coupled into the slit of the spectrometer or imported through an optical fiber. The linear module 1104 is arranged in the sealing pressure chamber 1, and can quickly adjust the focal length of the lens group inside the optical path unit 11, so that the pulse laser light is focused on the analysis surface of the target to be detected. Due to the beneficial effects of this patent, no precise focusing is required, focusing accuracy is 0.1 mm, and focusing speed is less than 10 seconds. The power module is arranged in the sealing pressure chamber 1, and can output 5V and 24V DC voltage stably with total power output of 1000 W, or is connected with an external DC power supply.

[0036] The external airflow control system 2 comprises a pressure sensor 25, a gas probe bin 21, an air pressure sensor 2204, a flow control valve 23, a gas supply pipeline and a gas source. The detection range of the pressure sensor 25 should be suitable for the detection depth of water, such as detection depth of 6000 m, and the maximum pressure range should be higher than 60 MPa. The flow control valve 23 is used for controlling the flow rate of underwater airflow. In practical detection, the flow rate of the airflow under a steady state is less than 0.5 L/min. The gas source 22 contains an airbag 2201 and a piston 2202, and the internal air pressure is equal to external water pressure. The gas probe bin 21 is a hollow cylindrical structure made of titanium alloy. A rubber guard ring is arranged at the front end to avoid impacting and damaging the detected object.

[0037] During work, firstly, the underwater manipulator holds the detection system, so that the front end of the gas probe bin 21 is attached to the surface of the target to be detected. The advance speed of the manipulator should be not higher than 0.5 m/s. The external pressure of the gas probe bin 21 is detected by the controller 1201 through the pressure sensor 25, and a prefabricated flow model is invoked to accurately control the opening of the flow control valve so that a stable gas environment is formed in the gas probe. The controller module 1201 controls the laser 1202 to emit high energy pulse laser light, and the laser light passes through the optical path assembly of the optical path unit 11, penetrates through the glass window 26 and the gas probe bin 21, and converges on the surface of the target to be detected to generate plasma. The plasma emission light enters the optical path unit 11 through the gas probe bin 21 and is coupled to the spectrometer 1203 by the internal lens group. The linear module 1104 is used for adjusting the convergence focal length; the time sequence controller 1204 is used for controlling interval time between the laser 1202 and the spectrometer 1203; and the video acquisition camera 24 is used for observing the detecting situation. The spectral line data collected by the spectrometer 1203 is uploaded to a remote data server by the controller 1201 for analysis, so as to realize the in-situ online detection of underwater target element components.

[0038] The gas probe bin 21 has pressure resistance, and can keep the structural shape of the internal gaseous optical path unchanged under a high pressure environment. The front end of the probe is provided with a vent hole 2101, to ensure no bubble interference in the detection position. The front end of the probe is provided with a flexible material to avoid damaging the detection target due to impact. The entire interior of the gas probe bin 21 up to the analysis surface of the target to be detected in contact with the front end is in a gas environment state. The types of the supply gas source are gases of helium, neon, argon, nitrogen and air. The pulse laser 1202 can be a conventional laser or an optical fiber laser with minimal divergence angle. The linear module 1104 is arranged in the optical path unit 11, and can quickly adjust the focal length of the lens group inside the optical path unit 11, so that the pulse laser light is focused on the surface of the target to be detected.

[0039] As shown in FIG. 2, the online detection method for underwater elements based on LIBS technology provided by the present invention comprises the following steps: [0040] placing an overall system in a high-pressure laboratory module under a laboratory environment; changing water pressure; monitoring the current water pressure by the pressure sensor (25); regulating the air supply by controlling the flow control valve (23); observing underwater bubbles that emerge through the video acquisition camera (24); and establishing an underwater stable flow model of water pressure and control valve opening under the condition that the bubbles are stable and a few bubbles are discharged; [0041] obtaining a current water pressure value by the pressure sensor 25, opening the flow control valve 23, supplying gas into the gas probe bin 21 through the gas supply device 22, and draining the water in the gas probe bin 21 by the gas through the vent hole in the front end of the probe; [0042] monitoring water pressure outside the gas probe bin (21) by the controller (1201) through the pressure sensor (25), invoking a prefabricated flow model and regulating the air supply by controlling the opening of the flow control valve (23) according to the current water pressure so that a stable air pressure environment is maintained in the gas probe bin (21); [0043] controlling the laser 1202, the spectrometer 1203, etc. by the controller 1201 in the sealing pressure chamber 1 to start underwater in-situ online detection, to obtain LIBS spectral data; [0044] analyzing the obtained LIB S spectral data through the controller 1201 or uploading to a remote data server through the communication cable for analysis, to obtain the type and relative content of the target elements.

[0045] The online detection method for underwater elements based on LIBS technology provided by the present invention can be implemented by those ordinary skilled in the art through other steps. The online detection method for underwater elements based on LIBS technology provided by the present invention in FIG. 2 is only a specific embodiment.