CN1595112A - On-line oil monitoring sensor based on double light paths - Google Patents
On-line oil monitoring sensor based on double light paths Download PDFInfo
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- CN1595112A CN1595112A CN 200410013354 CN200410013354A CN1595112A CN 1595112 A CN1595112 A CN 1595112A CN 200410013354 CN200410013354 CN 200410013354 CN 200410013354 A CN200410013354 A CN 200410013354A CN 1595112 A CN1595112 A CN 1595112A
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Abstract
This invention relates to a oil monitoring sensor based on double light path on-line oil monitor sensor, which is characterized by the following: the Y shape light fiber coupler 2 input end is connected with light source 1 through light fiber; the output ends of the Y shape light fiber coupler into two paths which are separately connected with the ends of two incidence light fiber ; the other end of the incidence light fiber is connected with focus lens 3 and the other end of the other incidence light fiber is connected with self-focus lens 5 which locates on the front of the reference oil pool 7 and the self-focus lens 6 locates in the back of the reference oil pool 7; one end of the emergent light fiber 12 is connected with self-focus lens 6 and the other end of the emergent light fiber 12 is connected with light detector 9 which is connected with computer through data line; the reference oil liquid level locates inside the reference oil pool 7.
Description
Technical field
The present invention relates to the online oil liquid monitoring sensor of a kind of optical fiber.
Background technology
The oil liquid monitoring technology is the method for a kind of effective monitoring of working condition and fault diagnosis, it is by the lubricating oil of collecting device or the sample of actuating medium, utilize means such as light, electricity, magnetics, the wearing and tearing and the contaminant particle of the physical and chemical index of analytic sample and the equipment friction pair that carries, qualitative and describe the state of wear (comprising position, form, degree) of equipment quantitatively, find out risk factor, and the prediction development trend.The oil liquid monitoring technology mainly comprises physical and chemical performance and state analysis two parts of wear particle analytical technology and fluid itself in the fluid.
Traditional oil liquid monitoring technology mainly is to adopt the analytical approach of off-line sampling.The off-line sample analysis needs expensive exact instrument (as precise electronic balance, microscope and automatic particle collector etc.), and detection time is long.
Online oil liquid monitoring technology is by being installed in the sensor in the fluid pipeline (bypass), utilize the lubricating oil of means collecting devices such as light, electricity, magnetics or the status information of actuating medium, wearing and tearing and the contaminant particle and the contamination index of the equipment friction pair that carries of analytic sample, qualitative and describe the state of wear (comprising position, form, degree) of equipment quantitatively, find out risk factor, and the prediction development trend.
Online oil liquid monitoring technology mainly comprises the information acquiring technology and the information processing technology.The information acquisition part of online oil liquid monitoring technology mainly is made up of the core sensor and the analysis and processing unit of on-line monitoring.Comprise following content:
1) selection of monitoring parameter: the equipment that monitor is analyzed, and selected concrete monitoring parameter is as temperature, pressure, dustiness etc.;
2) signal obtains: will reflect by sensor that the status information (as light, electric harmony etc.) of fluid converts to can be for the electric signal of gathering;
3) transmission of signal: by sensor acquisition and the signal that spreads out of generally is fainter, therefore needs to adopt signal amplifier that signal is amplified;
4) conversion of signal: need adopt the information handling system of digital signal to some, also need use A/D converter that the analog signal conversion of sensor acquisition is become digital signal.
Fluid to plant equipment carries out on-line monitoring, is one of effective measures of plant equipment maintenance and fault early diagnosis and prevention.Online oil liquid monitoring carries out the diagnosis of analysis and judgement and wear-out failure by being collected in contained relevant status information in the lubricating oil to the mechanical movement situation.The key of on-line monitoring system is the selection of sensor, according to the principle of work difference of sensor, but fluid on-line monitoring method is divided into following a few class: pressure reduction and flow analysis method, electrical method, magnetic methods, optical means, acoustic method and other method.
Optical means:
Laser Fraunhofer's diffraction phenomenon will occur when inciding the particle with certain particle size distribution.When illumination was mapped to suspending liquid, a part was absorbed, and scattering then takes place another part, and the remaining fluid that directly passes is received by photosensitive receiving element, when the light intensity one of incident light regularly, can draw the dustiness of fluid by the light intensity of Measurement and analysis output.
The most representative in the sensor of employing optical means exploitation is the LaserNet Fines optics wear particle monitoring instrument of the optical technology portion exploitation of research institute of USN.This system can be used for off-line analysis, also can be used for online monitoring.A kind of utilization " integrating sphere " oil contamination on-line monitoring instrument that also has HIAC/ROYCO photoelectric type abrasive particle on-line monitoring instrument produced in USA and Japan to produce in addition.
The single channel measurement structure that optical means is traditional partly is made up of as shown in Figure 1 light source, fibre-optical probe, lens, photo-detector, data acquisition and signal Processing etc.
In Fig. 1, by the luminous flux I of light source generation
0, by light transmitting fiber and lens optical alignment is introduced measured zone, promptly be arranged in the sample area on the light path.Quartz glass is housed as watch window in the fluid pipeline, is not assembled by lens, export to detector unit, promptly on the photosurface of photoelectric receiving tube through second optical fiber by the part emergent light of particle scattering and absorption.Utilize photoelectric signal amplifier can measure the luminous flux of carrying information.
In single channel system, direct measuring light amount of flux; But the single channel measuring method is to be difficult to obtain to use in practice.Incident intensity I
0In fact refer to clean oil by the time light intensity, could be and must measure this value according to formula (Bouguer-Lambert absorption law: I=I
0e
-τ L) obtain the reflection contamination level of oil liquid parameter.Because oil sample difference in the scene, or owing to the exciting current difference causes intensity of light source difference, different incident intensity I appears promptly
0On the other hand for on-line detecting system, the incident intensity I when always having particle to exist promptly can't to measure no particle in the fluid pipeline
0Value, and the glass sheet of sample cell is very easily polluted and is changed incident intensity.
Measure analysis of Influential Factors:
Adopt intensity modulation mode single channel sensor measurement contamination level of oil liquid need consider following some factor:
(1) incident intensity is measured difficulty
Generally adopt the monochromatic light paths to measure at present intensity modulation sensor.But realize online continuous monitoring, then must obtain incident intensity, and be actually the size that is difficult to obtain incident intensity.
(2) influence of fluid color
Because optical measurement is subjected to the influence of fluid color bigger,, cause measuring error so the unevenness of color may cause the fluctuation of data in the working sample.
Except that above-mentioned some factor, the interference such as vibration of the power-supply fluctuation of light source, extraneous parasitic light and optical fiber coupling place also will cause the instability of measurement result.Therefore, this paper proposes a kind of optical fiber oil liquid monitoring sensor with reference path.
Summary of the invention
The object of the present invention is to provide a kind of online oil liquid monitoring sensor of contamination level of oil liquid on-line monitoring based on double light path.
To achieve these goals, technical scheme of the present invention is: based on the online oil liquid monitoring sensor of double light path, it comprises light source 1, GRIN Lens 3, measure oil sump 8, GRIN Lens 4, photo-detector 10, incident optical, outgoing optical fiber, one end of incident optical is connected with light source 1, the other end of incident optical 11 contacts with GRIN Lens 3, GRIN Lens 3 is positioned at the place ahead of measuring oil sump 8, GRIN Lens 3 with measure oil sump 8 and be connected by optical fiber, GRIN Lens 4 is positioned at the rear of measuring oil sump 8, GRIN Lens 4 with measure oil sump 8 and be connected by optical fiber, one end of outgoing optical fiber contacts with GRIN Lens 4, the other end of outgoing optical fiber links to each other with photo-detector 10, and photo-detector 10 is connected with computing machine by data line; It is characterized in that: the input end of y-type optical fiber coupling mechanism 2 is linked to each other with light source 1 by optical fiber, the output terminal of y-type optical fiber coupling mechanism 2 is divided into two the tunnel, end with two road incident opticals 11 links to each other respectively, the other end of one road incident optical 11 contacts with GRIN Lens 3, the other end of another road incident optical 11 contacts with GRIN Lens 5, GRIN Lens 5 is positioned at the place ahead with reference to oil sump 7, GRIN Lens 5 be connected by optical fiber with reference to oil sump 7, GRIN Lens 6 is positioned at the rear with reference to oil sump 7, GRIN Lens 6 be connected by optical fiber with reference to oil sump 7, one end of outgoing optical fiber 12 contacts with GRIN Lens 6, the other end of outgoing optical fiber 12 links to each other with photo-detector 9, photo-detector 9 is connected with computing machine by data line, and reference fluid is positioned at reference to oil sump 7.
Described light source 1 is the good light emitting diode of monochromaticity.
Described Y type coupling mechanism 2 is 1: 1 a coupling mechanism.
Described housing with reference to oil sump 7, measurement oil sump 8 is a quartz glass.Described is all consistent oil sumps of material, specification, manufacture craft with reference to oil sump 7 with measuring oil sump 8.
The present invention only uses a light source, and the light intensity of light source can be regulated by the variable resistor of light source driving circuit.The light that is sent by light source is divided into equicohesive two-beam by Y type coupling mechanism 2 with light, wherein one road light is coupled into reference to oil sump 7 by GRIN Lens 3, the light that transmits from reference oil sump 7 converts thereof into current signal by the photo-detector 9 of reference signal, transfer signals in computing machine or the Signal Measurement System by signal amplification and transmission system, finish the collecting work of reference signal signal.
Meanwhile, another road light is coupled into by GRIN Lens 3 and measures oil sump 8, convert thereof into current signal from measuring light that oil sump 8 transmits by the photo-detector 10 of measuring-signal, transfer signals in computing machine or the Signal Measurement System by signal amplification and transmission system, finish the collecting work of measuring-signal, by signal processing system, can draw the amount that characterizes contamination level of oil liquid at last.
Present intensity modulation sensor generally adopts the monochromatic light road to measure.But realize online continuous monitoring, then must obtain incident intensity, but be actually the size that is difficult to obtain incident intensity.Therefore native system adopts the measuring method of double light path, by detection fiber by measuring oil sump light intensity and with reference to the light intensity of oil sump, the correlativity of analyzing two paths of signals obtains effective information.Adopt the metering system of band reference path also to eliminate light source fluctuation and the element temperature is floated, the time influence of floating.
The invention has the beneficial effects as follows, the online fluid on-line monitoring of double light path optical fiber sensor need not measured the intensity of incident intensity, can overcome owing to the exciting current difference causes the different problem of the intensity of light source, simultaneously can overcome the influence different of different fluid colors to the optical transmission rate, can directly insert in the lubricating system, realize on-line monitoring contamination level of oil liquid.
Description of drawings
The present invention is further described below in conjunction with drawings and Examples.
Fig. 1 is existing single channel measurement structure figure
Fig. 2 is a schematic diagram of the present invention
Fig. 3 is an on-line monitoring measuring system structural drawing
Fig. 4 is the measuring sonde structural drawing of sensor
Fig. 5 is light source led driving circuit figure of the present invention
Fig. 6 is the photodiode circuit figure of photodetection circuit of the present invention
Fig. 7 is the pre-amplification circuit figure of photodetection circuit of the present invention
Fig. 8 is the low-pass filter circuit figure of photodetection circuit of the present invention
Among the figure: 1. light source, 2.Y type fiber coupler, 3. GRIN Lens, 4. GRIN Lens, 5. GRIN Lens, 6. GRIN Lens, 7. with reference to oil sump, 8. measure oil sump, the 9. photo-detector of reference signal, 10. the photo-detector of measuring-signal, 11. incident optical, 12. outgoing optical fiber, 13. probing shell, 14. pond bodies.
Embodiment
As Fig. 2, Fig. 3, shown in Figure 4, online oil liquid monitoring sensor based on double light path, it is mainly by light source 1, y-type optical fiber coupling mechanism 2, GRIN Lens 3, GRIN Lens 4, GRIN Lens 5, GRIN Lens 6, with reference to oil sump 7, measure oil sump 8, photo-detector 9, photo-detector 10, incident optical 11, outgoing optical fiber 12 constitutes, the input end of y-type optical fiber coupling mechanism 2 is linked to each other with light source 1 by optical fiber, the output terminal of y-type optical fiber coupling mechanism 2 is divided into two the tunnel, end with two road incident opticals 11 links to each other respectively, the other end of one road incident optical 11 contacts with GRIN Lens 3, GRIN Lens 3 is positioned at the place ahead of measuring oil sump 8, GRIN Lens 3 with measure oil sump 8 by optical fiber be connected (two ends of optical fiber respectively with the rear of GRIN Lens 3, the place ahead housing of measuring oil sump 8 contacts, the housing of measuring oil sump 8 is a quartz glass, as Fig. 1, Fig. 2, the left side is the place ahead.), GRIN Lens 4 is positioned at the rear of measuring oil sump 8, GRIN Lens 4 is connected by optical fiber with measurement oil sump 8, and (two ends of optical fiber contact with the place ahead of GRIN Lens 4, the rear housing of measurement oil sump 8 respectively,), one end of outgoing optical fiber 12 contacts with GRIN Lens 4, the other end of outgoing optical fiber links to each other with photo-detector 10, and photo-detector 10 is connected with computing machine by data line; The other end of another road incident optical 11 contacts with the place ahead of GRIN Lens 5, GRIN Lens 5 is positioned at the place ahead with reference to oil sump 7, GRIN Lens 5 with reference to oil sump 7 by optical fiber be connected (two ends of optical fiber respectively with the rear of GRIN Lens 5, the place ahead housing with reference to oil sump 7 contacts,), GRIN Lens 6 is positioned at the rear with reference to oil sump 7, GRIN Lens 6 with reference to oil sump 7 by optical fiber be connected (two ends of optical fiber respectively with the place ahead of GRIN Lens 6, rear housing with reference to oil sump 7 contacts,), one end of outgoing optical fiber 12 contacts with the rear of GRIN Lens 6, the other end of outgoing optical fiber 12 links to each other with photo-detector 9, and photo-detector 9 is connected with computing machine by data line.During use, reference fluid is positioned at reference to oil sump 7, is closed state with reference to oil sump 7; Measuring oil sump 8 is open state.As shown in Figure 4, GRIN Lens 3, GRIN Lens 4, GRIN Lens 5, GRIN Lens 6 are separately fixed on the probing shell 13, two the tunnel penetrate optical fiber 11, outgoing optical fiber 12 lays respectively in the optic fibre hole of probing shell 13, with reference to oil sump 7, measure oil sump 8 and be located at side by side on the pond body 14.
The circuit of photo-detector 9, photo-detector 10---the photodetection receiving circuit mainly is made up of photodiode, pre-amplification circuit and filtering circuit, two tunnel outgoing optical fiber 12 contact with corresponding photodiode separately respectively, photodiode directly is connected across two input ends of the amplifier of pre-amplification circuit, the output terminal of pre-amplification circuit is connected with Butterworth quadravalence active low-pass filter, and the output terminal of Butterworth quadravalence active low-pass filter is connected with computing machine by data line.GRIN Lens 5 advances one tunnel optically-coupled with reference to oil sump 7, and transmitted light will be coupled into photo-detector 9 with reference to the measuring light of oil sump 7 by GRIN Lens 6 then, can obtain the size of reference light thus.GRIN Lens 3 advances to measure oil sump 8 with one tunnel optically-coupled, and the transmitted light measuring light that will measure oil sump 8 by GRIN Lens 4 is coupled into photo-detector 10 then, can obtain the size of measuring light thus.
Described light source 1 is the good light emitting diode of monochromaticity.
Described Y type coupling mechanism 2 is 1: 1 a coupling mechanism (multimode).
Described housing with reference to oil sump 7, measurement oil sump 8 is a quartz glass.Described is all consistent oil sumps such as material, specification, manufacture craft with reference to oil sump 7 with measuring oil sump 8.
Signal output of the present invention can directly be connected with computing machine by data line, and by Computer Processing, the present invention also can be by the direct picked up signal size of analog signal detection device.With reference to oil sump 7, measure oil sump 8 can also " series connection " in the fluid pipeline, the pollution situation that lubricates the fluid in system such as (or hydraulic pressure) is carried out on-line monitoring.
In order to improve the incident light intensity, light emitting diode is equipped with light-concentrating material, improves to incide light intensity in the fluid protection diode.
Consider the sensitivity of having relatively high expectations, adopt the optical fiber correlation parameter to be: internal diameter 62.5 μ m, the multimode silica fibre of external diameter 125 μ m.Silica fibre is at 850nm, and the decay at 1300nm and 1550nm place is near theoretical minimum value, so silica fibre low-loss transmission window is 850nm, 1300nm and 1550nm.
The diameter of optical fiber about about 1.7mm, can provide about 2mm greatly
2The visual field is fine basically for the abrasive particle of monitoring 10~500 μ m in the fluid.
What as shown in Figure 5, the present invention used is led light source.LED is a kind of self-emission light source, and luminous diameter surpasses 50um, can only effectively be coupled with multimode optical fiber.In order to guarantee the stability of drive current, the driving circuit of LED shown in Figure 5 adopts feedback control loop, and wherein the elementary cell of current stabilization adopts OP177.OP177 is high performance operational amplifier, regulates resistance R
0The input current of LED can be changed, thereby the Output optical power of LED can be adjusted; Resistance R
3In circuit, play metering function, as will further protecting to LED, the diode of can on LED, connecting.
The design of photodetection receiving circuit:
The circuit of photo-detector 9, photo-detector 10---the photodetection receiving circuit mainly is made up of photodiode, pre-amplification circuit and filtering circuit.Photodiode receives the light signal that transmits and is converted into current signal then from fluid; Pre-amplification circuit amplifies the low current signal that photodiode transmits, and amplifies by again signal being carried out secondary behind the filtering circuit then.The cable that photodiode links to each other with prime amplifier is tried one's best short and is used teflon insulation.
As shown in Figure 6, photodiode is selected Zero-bias working (photovoltaic mode) work for use.Photodiode is usable zero offset operation (photovoltaic mode) both, and photovoltaic mode can realize the most accurate linear work, and guided optical mode then can be realized higher switch speed, but will sacrifice linearity.
As shown in Figure 7, pre-amplification circuit, PIN diode directly is connected across two input ends of amplifier.C
1Equivalent Distributed electric capacity for amp.in; R
2Be feedback resistance; C
2The distributed capacitance at feedback resistance two ends.Used resistance is selected temperature characterisitic and frequency characteristic low noise resistance preferably in the circuit, and electric capacity is selected low noise electric capacity as far as possible.
PIN diode is always operating under the anti-phase bias voltage, when not having illumination, still has dark current to flow through, and along with the increase of anti-phase bias voltage, dark current also will increase.The dark current of the diode of general PIN should reduce dark current in the nA magnitude as far as possible.In order to reduce anti-phase bias voltage, in side circuit, the PIN pipe is connected on the inverting input of operational amplifier, utilize the characteristics of operational amplifier, bias voltage is approximately zero, and dark current also will be reduced to minimum.
Operational amplifier has played the effect of core in preceding putting, its performance index such as open-loop gain, input bias current, offset current and offset voltage, frequency response and noiseproof feature all exert an influence to preceding putting.Side circuit uses be AD795 as amplifier, have effect preferably.
As shown in Figure 8, prime amplifier has been finished the detection of signal and rough handling, has obtained and relevant voltage signal, can be covered by noise but this signal also can contain some AC noise useful signals.Design a low-frequency active wave filter, as shown in Figure 8.This circuit is a Butterworth quadravalence active low-pass filter.
Be connected with computing machine by data line,, or, can obtain characterizing the amount of contamination level of oil liquid thus by the direct picked up signal size of analog signal detection device by Computer Processing.
Computing machine is by to Signal Processing, but size up from 5 μ m to the wear particle concentration more than the 100 μ m.Obtain the information of the lubricated and state of wear of machine, qualitative and describe the state of wear of equipment quantitatively, find out risk factor, estimate the operating mode of machine and predict its fault, and the technology of definite failure cause, type.
Claims (2)
1. based on the online oil liquid monitoring sensor of double light path, it comprises light source (1), GRIN Lens (3), measure oil sump (8), GRIN Lens (4), photo-detector (10), incident optical, outgoing optical fiber, one end of incident optical is connected with light source (1), the other end of incident optical (11) contacts with GRIN Lens (3), GRIN Lens (3) is positioned at the place ahead of measuring oil sump (8), GRIN Lens (3) is connected by optical fiber with measurement oil sump (8), GRIN Lens (4) is positioned at the rear of measuring oil sump (8), GRIN Lens (4) is connected by optical fiber with measurement oil sump (8), one end of outgoing optical fiber contacts with GRIN Lens (4), the other end of outgoing optical fiber links to each other with photo-detector (10), and photo-detector (10) is connected with computing machine by data line; It is characterized in that: the input end of y-type optical fiber coupling mechanism (2) is linked to each other with light source (1) by optical fiber, the output terminal of y-type optical fiber coupling mechanism (2) is divided into two the tunnel, end with two road incident opticals (11) links to each other respectively, the other end of one road incident optical (11) contacts with GRIN Lens (3), the other end of another road incident optical (11) contacts with GRIN Lens (5), GRIN Lens (5) is positioned at the place ahead with reference to oil sump (7), GRIN Lens (5) be connected by optical fiber with reference to oil sump (7), GRIN Lens (6) is positioned at the rear with reference to oil sump (7), GRIN Lens (6) be connected by optical fiber with reference to oil sump (7), one end of outgoing optical fiber (12) contacts with GRIN Lens (6), the other end of outgoing optical fiber (12) links to each other with photo-detector (9), photo-detector (9) is connected with computing machine by data line, and reference fluid is positioned at reference to oil sump (7).
2. the online oil liquid monitoring sensor based on double light path according to claim 1 is characterized in that: described Y type coupling mechanism (2) is 1: 1 a coupling mechanism.
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Family Cites Families (10)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JPH0282139A (en) * | 1988-09-19 | 1990-03-22 | Suzuki Motor Co Ltd | Oil deterioration detector |
DE69032968T2 (en) * | 1989-04-25 | 1999-10-21 | Tatsuta Densen Kk | OPTICAL LIQUID SENSOR, ITS MANUFACTURING METHOD AND MOTOR VEHICLE OIL AND BATTERY TEST |
US5739916A (en) * | 1995-12-04 | 1998-04-14 | University Of Alabama At Huntsville | Apparatus and method for determining the concentration of species in a substance |
CN1136447C (en) * | 2000-07-19 | 2004-01-28 | 中国石油天然气股份有限公司兰州炼化分公司 | In-line analysis method for chromaticity of petroleum product |
DE10105793B4 (en) * | 2001-02-07 | 2010-03-04 | Iav Gmbh Ingenieurgesellschaft Auto Und Verkehr | Method for evaluating lubricant quality |
US7172903B2 (en) * | 2002-03-12 | 2007-02-06 | Exxonmobil Research And Engineering Company | Method for on-line monitoring of lubricating oil using light in the visible and near IR spectra |
CN2570777Y (en) * | 2002-10-11 | 2003-09-03 | 武汉理工大学 | Orthogonal optical fibre on-line oil monitor |
US6933491B2 (en) * | 2002-12-12 | 2005-08-23 | Weatherford/Lamb, Inc. | Remotely deployed optical fiber circulator |
CN2596347Y (en) * | 2002-12-27 | 2003-12-31 | 中国人民解放军总后勤部油料研究所 | Portable oil quality analyzer |
CN1477384A (en) * | 2003-04-16 | 2004-02-25 | 浙江大学绿盾科技有限公司 | On-line quick testing instrument of petroleum product-quality |
-
2004
- 2004-06-25 CN CNB2004100133546A patent/CN1300570C/en not_active Expired - Fee Related
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CN102004079A (en) * | 2010-09-16 | 2011-04-06 | 华南理工大学 | On-line oil particle pollution degree detection sensor based on optical sensing |
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CN106153102A (en) * | 2015-04-09 | 2016-11-23 | 北京中联电科技术有限公司 | A kind of multiparameter integration fluid sensor based on iraser technology |
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