CN203732444U - Laser-induced breakdown spectroscopy analyzer - Google Patents

Abstract

The utility model relates to a portable laser-induced breakdown spectroscopy analyzer. The analyzer comprises a solid-state laser, an optical path unit and a data processing unit, wherein the optical path unit comprises a dichroscope, a first focusing lens, a second focusing lens, an optical fiber and a multi-channel spectrograph; laser emitted by the solid-state laser is projected to a sample through the dichroscope and the first focusing lens sequentially; a radiation signal emitted by the sample sequentially enters an entrance end of a beam-splitting optical fiber through the first focusing lens, the dichroscope and the second focusing lens and enters the multi-channel spectrograph from multiple optical fiber branches; the data processing unit comprises a data acquisition unit connected with the spectrograph and a processor connected with the data acquisition unit. The radiation signal is generated through a laser-induced sample and is collected and analyzed through the optical path unit and the data processing unit, and then the elementary composition and concentration of the sample are obtained.

Description

Laser-induced Breakdown Spectroscopy analyser

Technical field

The utility model belongs to spectrum detection technique field, relates in particular to a kind of Laser-induced Breakdown Spectroscopy analyser.

Background technology

Laser-induced Breakdown Spectroscopy method (Laser Induced Breakdown Spectroscopy, LIBS) is a kind of conventional Atomic Emission Spectral Analysis technology, is directly to test a kind of method that sample element set becomes.The method use is a branch of produces laser induced plasma compared with strong pulse laser focusing in the surface of sample.This plasma is the potpourri that the material that is stripped from out in sample is at high temperature dissociated into excited atom.These excited atoms return by the transition of high-energy state the wavelength characteristic spectral line that low-yield state launches to characterize every kind of element kind.A part for characteristic spectral line is collected, and is sent to spectrometer, and this spectrometer provides the spectral analysis to characteristic spectral line according to the relation of spectral strength and wavelength, indicates the element of this sample to form and content.

For quantitatively detecting the technological means of micro heavy, mainly contain x-ray fluorescence analysis (X-ray) at present, atomic absorption spectroscopy (AAS), inductively coupled plasma atomic emission spectrum technology (ICP-AES), inductively coupled plasma transmitting mass spectroscopy (ICP-MS) and spark emission spectroscopic method (OES) etc.Wherein X-ray method can realize fast detecting, but its sensitivity is lower, and needs contact type measurement, and two large inferior positions make its use limited; The technology for detection precision of AAS, ICP-AES, ICP-MS and OES is high, good stability, but due to apparatus expensive, sample pre-treatments is time-consuming, is difficult to widely apply.

Compare with these traditional spectral analysis techniques, LIBS technology has unrivaled advantage, without sample pretreatment, analyze easy, be applicable to real-time, quick, harmless multielement composition determination and analysis, and the in-situ micro area analysis of components that can realize solid (conductor or nonconductor are as high-hardness metal material, plastic products, mineral etc.), liquid, gas and the biological tissue of various forms, spatial resolution can reach 1-100 micron.

Laser-induced Breakdown Spectroscopy (LIBS) technology is widely used in the fields such as geologic prospecting, environmental pollution monitoring, industrial products detection, food quality detection, archaeology analysis and biological medicine, such as rock, soil, water body, alloy, fruit and vegetable, pigment, antique historical relic and medicine etc. are carried out to ultimate analysis.That LIBS has is contactless, telemeasurement, harmless, real-time analysis feature fast almost, and these irreplaceable advantages, make it replace gradually traditional detection method and have extensive prospect in industry.

At present, high-resolution Laser-induced Breakdown Spectroscopy analyser is generally than relatively large, expensive on the market, is unfavorable for Site Detection application, and more small-sized Laser-induced Breakdown Spectroscopy analyser is except expensive, and its analysis result is also unstable.The above analyser is foreign technology monopolization, domesticly there is no this type of patented claim.The utility model will be small-sized from instrument, portable, system high-speed is integrated and analysis result high s/n ratio aspect is improved Laser-induced Breakdown Spectroscopy analyser, to obtain better effect.

Utility model content

For the deficiencies in the prior art, first object described in the utility model is to provide a kind of portable laser induced breakdown spectroscopy analyser, they can contactless (several-tens cm distance), real non-destructive is analyzed unknown sample, the multiple element in sample are formed and concentration is carried out express-analysis especially simultaneously.

For this reason, the technical scheme that Laser-induced Breakdown Spectroscopy analyser described in the utility model adopts is as follows:

A Laser-induced Breakdown Spectroscopy analyser, comprises solid-state laser, optical path unit and data processing unit, wherein,

Described optical path unit comprises dichroic mirror, the first condenser lens, the second condenser lens, optical fiber, multi-channel spectrometer based, and the laser that described solid-state laser sends is incident upon on sample by described dichroic mirror, the first condenser lens successively; The radiation signal that this sample sends enters the upstream end of described optical fiber successively by described the first condenser lens, dichroic mirror, the second condenser lens, from a plurality of fiber optic taps of described optical fiber, enter described multi-channel spectrometer based;

Described data processing unit comprises the data acquisition unit being connected with described multi-channel spectrometer based and the processor being connected with described data acquisition unit.

Preferably, described solid-state laser is Wind-cooling type All-Solid laser instrument.

Further, multi-channel spectrometer based has a plurality of passages, each branch of light splitting optical fiber connects each passage, and in described multi-channel spectrometer based, each passage is provided with entrance slit, collimating mirror, grating, focus lamp and the ccd array detector being connected with described fiber optic tap.

Preferably, described data acquisition unit comprises delay unit, integral unit and the synchronous data sampling unit connecting successively.

Further, also comprise display and host computer, described display is connected with described data processing unit respectively with host computer.

Compared with prior art, the beneficial effects of the utility model are utility model:

The utility model produces radiation signal by induced with laser sample, through optical path unit and data processing unit, collects after radiation signal, analysis, show that the element of sample forms and concentration.

In addition, spectroanalysis instrument global design miniaturization described in the utility model, practical portable.Especially adopt the spectrometer composite design of air-cooled semiconductor pumped solid-state laser, the many CCD of many gratings, the high-speed computation data processing unit that cooperation can be highly integrated.

And, the utility model also overcomes prior art defect, adopt the spectrometer combination of the many CCD of many gratings, by the coupling of FPGA and ARM chip, abandon the data acquisition unit carrying in traditional C CD, the unification of data acquisition control function is transferred to FPGA management, due to can the walk abreast synchronous acquisition of a plurality of CCD module datas of FPGA, time trigger error and the Data Integration problem of data acquisition unit have been avoided carrying in a plurality of CCD of multi collect, realize the high-speed AD synchronous data collection of hyperchannel variable threshold CCD electric signal, storage and usb data transmission, the height of simultaneously realizing system is integrated.Utilize the pulse laser of the high-repetition-rate of DPSS, in conjunction with the sample mean technology of Boxcar, adopt high-speed AD acquisition and area integral technology laser power monitoring to change, realize high s/n ratio and high efficiency digital signal processing.

Accompanying drawing explanation

Fig. 1 is the structural representation of Laser-induced Breakdown Spectroscopy analyser one embodiment described in the utility model;

Fig. 2 is the structural representation of spectrometer in Laser-induced Breakdown Spectroscopy analyser one embodiment described in the utility model;

Fig. 3 is the structural representation of data acquisition unit in Laser-induced Breakdown Spectroscopy analyser one embodiment described in the utility model;

Fig. 4 is the process flow diagram of Laser-induced Breakdown Spectroscopy analytical approach one embodiment described in the utility model;

In figure:

10: solid-state laser; 20: optical path unit; 21: dichroic mirror;

22: the first condenser lenses; 23: sample; 24: the second condenser lenses;

25: multi-channel spectrometer based; 251: passage; 2511: entrance slit;

2512: collimating mirror; 2513: grating; 2514: focus lamp;

2515:CCD detector array; 26: optical fiber; 261: fiber optic tap;

30: data processing unit; 31: display; 32: data acquisition unit;

321: delay unit; 322: integral unit; 323: synchronous data sampling unit;

40: host computer.

Embodiment

Below in conjunction with accompanying drawing and preferred embodiment, utility model is described in further details, but the utility model is not limited in following embodiment.

Referring to Fig. 1, Fig. 1 is the structural representation of Laser-induced Breakdown Spectroscopy analyser one embodiment described in the utility model.In the embodiment shown in Fig. 1, the Laser-induced Breakdown Spectroscopy analyser of this structure, comprises solid-state laser 10, optical path unit 20 and data processing unit 30.Solid-state laser 10 is for generation of laser, especially the laser of specific wavelength.Optical path unit 20 is connected with solid-state laser 10, for the laser conduction that solid-state laser 10 is produced, to sample 23, induces sample 23 to produce plasma.This plasma is the potpourri that the material that is stripped from out in sample 23 is at high temperature dissociated into excited atom.These excited atoms return by the transition of high-energy state the characteristic spectral line that low-yield state launches to characterize every kind of element wavelength.

In the embodiment shown in Fig. 1, described optical path unit 20 comprises dichroic mirror 21, the first condenser lens 22, the second condenser lens 24, optical fiber 26 and multi-channel spectrometer based 25, and wherein, described optical fiber 26 has a plurality of fiber optic taps 261.The laser that described solid-state laser 10 sends is incident upon on sample 23 by described dichroic mirror 21, the first condenser lens 22 successively.Laser, after dichroic mirror 21, focuses on after the first condenser lens 22 on sample 23.As noted before, sample 23 can produce with its element set and become corresponding characteristic radiation signal under the induction of laser.Partial radiation signal is successively by described the first condenser lens 22, dichroic mirror 21, the second condenser lens 24 and optical fiber 26.Enter radiation signal in dichroic mirror 21 and be reflected and enter in the second condenser lens 24, these radiation signals are focused on and are collected by the second condenser lens 24.The radiation signal spreading out of in described the second condenser lens 24 enters from the upstream end of described optical fiber 26, from a plurality of fiber optic taps 261 of described optical fiber 26, spreads out of, and enters in described multi-channel spectrometer based 25.

Radiation signal through after focusing on, finally enters in multi-channel spectrometer based 25 and processes, and changes the electric signal corresponding with radiation signal into and process.The light path design of this optical path unit 20 is easy to be clear, volume miniaturization, especially use the spectrometer of the many CCD of many gratings, each passage represents an independently spectrometer, export the spectrum of a certain wave band, measure spectrum scope is wider, and greatly reduce detection time, its spectral range is 200-980nm, and wavelength resolution can reach 0.1nm.

In addition, described data processing unit 30 comprises the data acquisition unit 32 being connected with described multi-channel spectrometer based 25 and the processor (not shown) being connected with described data acquisition unit 32.Data acquisition unit 32, for data are carried out to time delay sampling, is then delivered to processor and carries out data processing.After the characteristic spectral line that processor obtains sample 23 through data processing, compare the characteristic atomic spectral line that existing spectra database analyzes sample 23, in identification sample 23, element forms, and according to the information such as its spectrum peak area and intensity, composite measurement concentration of element.

Wherein, some preferred embodiment in, described solid-state laser 10 is Wind-cooling type All-Solid laser instrument 10(DPSS Laser).The semiconductor pumped solid-state laser 10 of Wind-cooling type can provide laser pulse and a synchronizing signal of 1064nm wavelength, and this synchronizing signal can be transferred into data processing unit 30.Because DPSS Laser volume is little, non-maintaining, high-level efficiency, life-span is long, power stability, and mode purity is good, low in energy consumption and can be portable etc. absolute predominance make it aspect various scientific research fields and commercial Application, there is extensive prospect, than traditional Laser-induced Breakdown Spectroscopy, select the refrigeration of xenon flash lamp pumping water circulation to adjust Q Nd:YAG laser instrument, this type of Optical Maser System volume is little, is easy to carry.

Referring to Fig. 2, Fig. 2 is the structural representation of multi-channel spectrometer based 25 in Laser-induced Breakdown Spectroscopy analyser one embodiment described in the utility model.In the embodiment shown in Fig. 2, in described multi-channel spectrometer based 25, have several passages 251, each passage 251 is provided with entrance slit 2511, collimating mirror 2512, grating 2513, focus lamp 2514 and the ccd array detector 2515 being connected with described fiber optic tap 261 successively.Described ccd array detector 2515 can be the linear silicon ccd array of 2048 pixels.Wherein, each passage 251 is equivalent to an independently spectrometer, exports the spectrum of a certain wave band, and after multi-channel spectrometer based 25 associatings, its spectral range is 0.1nm from 200nm-980nm, wavelength resolution.

Referring to Fig. 3, Fig. 3 is the structural representation of data acquisition unit 32 in Laser-induced Breakdown Spectroscopy analyser one embodiment described in the utility model.In the embodiment shown in Fig. 3, described data acquisition unit 32 comprises delay unit 321, integral unit 322 and synchronous data sampling unit 323 successively.In this Induction Process, radiation signal has very strong continuous radiation to disturb in early days, causes atomic radiation to be flooded by background.Through delay unit 321, in a predetermined time delay rear backdrop radiation, decline rapidly, radiation signal is now obvious.In addition, integral unit 322 can carry out integration collection to radiation signal, and preferred, this integral unit 322 is that thresholding is controlled, and the beginning based on integration and termination time can be controlled, thereby can be according to the most effective spectral signal of thresholding collection of preliminary election.In actual applications, data processing unit 30 can be connected with laser instrument, for example electric signal connects.When laser instrument starts Emission Lasers, provide synchronizing signal, log-on data processor carries out respective handling, carries out time delay and gathers electric signal the Integral Processing that radiation signal changes.In some preferred implementations, data processing unit 30 can be used field programmable gate array (FPGA) to realize, the data acquisition unit that the electric signal that multi-channel spectrometer based 25 converts to carries without a plurality of CCD, through FPGA, realize high speed, the multi-channel data synchronous acquisition of controlling AD, carry out being repeatedly transferred to processor after sample mean (BOXCAR technology) and carry out data processing, wherein, processor can be on ARM chip, to move some correlation computer instructions to realize.

Can overcome prior art defect like this, adopt the spectrometer combination of the many CCD of many gratings, by the coupling of FPGA and ARM chip, abandon the data acquisition unit carrying in traditional C CD, the unification of data acquisition control function is transferred to FPGA management, due to can the walk abreast synchronous acquisition of a plurality of CCD module datas of FPGA, time trigger error and the Data Integration problem of data acquisition unit have been avoided carrying in a plurality of CCD of multi collect, realize the high-speed AD synchronous data collection of hyperchannel variable threshold CCD electric signal, storage and usb data transmission, the height of simultaneously realizing system is integrated.Utilize the pulse laser of the high-repetition-rate of DPSS, in conjunction with the sample mean technology of Boxcar, adopt high-speed AD acquisition and area integral technology laser power monitoring to change, realize high s/n ratio and high efficiency digital signal processing.

In addition, in the embodiment shown in Fig. 1, also comprise display 31 and host computer 40, described display 31 is connected with described data processing unit 30 respectively with host computer 40.After data processing, draw the curve of spectrum and show on display 31, wherein, display 31 can be small-scale liquid crystal display screen.For complex sample 23, because data volume is excessive, be difficult to computational analysis, spectroscopic data can be preserved and is transferred to host computer 40 and be further processed.

Referring to Fig. 4, Fig. 4 is the process flow diagram of Laser-induced Breakdown Spectroscopy analytical approach one embodiment described in the utility model.In the embodiment shown in Fig. 4, this Laser-induced Breakdown Spectroscopy analytical approach, comprising:

Step S401: laser, after dichroic mirror 21, the first condenser lens 22 focus on, is incident upon on sample 23;

Step S402: also through the time delay of a Preset Time section;

Step S403: obtain again the electric signal corresponding with described radiation signal, collect described sample 23 radiation signal that produce, that focus on through the first condenser lens 22, dichroic mirror 21, the second condenser lens 24, change described radiation signal into electric signal.In this Induction Process, radiation signal has very strong continuous radiation to disturb in early days, causes atomic radiation to be flooded by background.Through delay unit 321, in a predetermined time delay rear backdrop radiation, decline rapidly, radiation signal is now obvious.

Step S404: carry out time delay, sample mean and process the atomic spectrum that obtains described radiation signal;

Step S405: described atomic spectrum is contrasted in atomic spectrum information database, analyze the characteristic atomic spectral line of sample 23, thereby the element of identification sample 23 forms.

Wherein, in described atomic spectrum is contrasted in atomic spectrum information database, also element long according to the spike of described characteristic atomic spectral line and intensity identification sample forms and concentration.

Above-mentioned analyser and method can be widely used at various solid and gas liquid material (ore minerals, metal, iron and steel, gold, alloy, jewel, pottery, glass, crystal, biologics, ecologic environment etc.) element forms and the portable detection of concentration, wherein for ore mineral, metal, iron and steel, gold, alloy, jewel, pottery, glass, crystal, biologics, ecologic environments etc. have wide application prospect, also at metal, alloy, quality control in glass and Ceramic production, the quality monitoring that precious metal is produced, metal, in the productions such as waste reclamation of plastics and other material and sphere of life, there is obvious actual utility, there is high performance-price ratio, high stability, high reliability, the features such as portable and antijamming capability is strong.The utility model not only has huge commercial market and application prospect widely at home and abroad, and has huge social benefit at aspects such as improving the security of work, agricultural production and daily life environment and comfortableness.

Should be appreciated that, the utility model is not limited to above-mentioned embodiment, every various changes of the present utility model or modification are not departed to spirit and scope of the present utility model, if these are changed and within modification belongs to claim of the present utility model and equivalent technologies scope, the utility model also means and comprises these changes and modification.

Claims (5)

1. a Laser-induced Breakdown Spectroscopy analyser, is characterized in that it comprises: solid-state laser, optical path unit and data processing unit;

Described optical path unit comprises: dichroic mirror, the first condenser lens, the second condenser lens, optical fiber, multi-channel spectrometer based, and the laser that described solid-state laser sends is incident upon on sample by described dichroic mirror, the first condenser lens successively; The radiation signal that this sample sends enters the upstream end of described optical fiber successively by described the first condenser lens, dichroic mirror, the second condenser lens, from a plurality of fiber optic taps of described optical fiber, enter described multi-channel spectrometer based;

Described data processing unit comprises the data acquisition unit being connected with described multi-channel spectrometer based and the processor being connected with described data acquisition unit, wherein said data processing unit is realized by field programmable gate array (FPGA) circuit, and described processor is ARM chip.

2. Laser-induced Breakdown Spectroscopy analyser as claimed in claim 1, is characterized in that: described solid-state laser is Wind-cooling type All-Solid laser instrument.

3. Laser-induced Breakdown Spectroscopy analyser as claimed in claim 1, it is characterized in that: multi-channel spectrometer based has a plurality of passages, each branch of light splitting optical fiber connects each passage, and in described multi-channel spectrometer based, each passage is provided with entrance slit, collimating mirror, grating, focus lamp and the ccd array detector being connected with described fiber optic tap.

4. portable induced breakdown spectroscopy analyser as claimed in claim 1, is characterized in that: described data acquisition unit comprises delay unit, integral unit and the synchronous data sampling unit connecting successively.

5. portable induced breakdown spectroscopy analyser as claimed in claim 1, is characterized in that: also comprise display and host computer, described display is connected with described data processing unit respectively with host computer.