CN106053418A - Noncontact type oil-in-water sensor - Google Patents
Noncontact type oil-in-water sensor Download PDFInfo
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- CN106053418A CN106053418A CN201610594565.6A CN201610594565A CN106053418A CN 106053418 A CN106053418 A CN 106053418A CN 201610594565 A CN201610594565 A CN 201610594565A CN 106053418 A CN106053418 A CN 106053418A
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N21/00—Investigating or analysing materials by the use of optical means, i.e. using sub-millimetre waves, infrared, visible or ultraviolet light
- G01N21/62—Systems in which the material investigated is excited whereby it emits light or causes a change in wavelength of the incident light
- G01N21/63—Systems in which the material investigated is excited whereby it emits light or causes a change in wavelength of the incident light optically excited
- G01N21/64—Fluorescence; Phosphorescence
Abstract
The invention discloses a noncontact type oil-in-water sensor. The noncontact type oil-in-water sensor comprises an outer shell, a guide pipe and a sensing testing device, wherein the inner surface of the guide pipe is smooth, and the guide pipe extends into the outer shell; the sensing testing device comprises a base and a double-light-path signal detector, and the double-light-path signal detector is connected with a light trap and comprises an inner shell and a light source generator, a beam splitter, a reference light path detector and a measuring light path detector which are arranged in the inner shell; the measuring light path detector comprises a measuring light path incidence channel and a measuring light path channel, a measuring cavity is arranged at the intersection of the measuring light path incidence channel and the measuring light path channel, a position, close to the measuring cavity, in the measuring light path incidence channel is provided with a first optical window, and a positon, close to the measuring cavity, in the measuring path channel is provided with a second optical window. The noncontact type oil-in-water sensor is novel in design, capable of achieving noncontact detection, capable of monitoring water oil content in a real-time and online manner and free of pollution.
Description
Technical field
The invention belongs to sensor technical field, be specifically related to oil sensor in a kind of contactless water.
Background technology
More serious with water contamination phenomenon, water quality detection is paid close attention to by the most widely, wherein mineral oils material
Become can not be ignored to water pollution.Therefore, fast monitored mineral oil in water class content of material, reflects current water real-time and accurately
Matter situation, has Great significance, the most more for aspects such as the monitoring management of water resource environment and sewage disposals
In common water oil detection method mainly include infrared spectrophotometer, NDIR (Non-Dispersive Infrared) photometry, ultraviolet spectrophotometry with
And ultraviolet fluorescence method, wherein, the detecting step ratio of infrared spectrophotometer, NDIR (Non-Dispersive Infrared) photometry and ultraviolet spectrophotometry
Cumbersome, just can test after being required to liquid to be measured is extracted, it is impossible to accomplish real time on-line monitoring;And ultraviolet fluorescence method is less dense
Although the real-time monitoring of oil content in water can be realized in the range of degree, but existing market only has the related detection device of contact, deposits
Cleaning the defect of difficulty, therefore, nowadays lack that a kind of simple in construction, volume be little, low cost, reasonable in design, can exist in real time
Oil sensor in the contactless water of line detection water quality, can be passed through conduit by water quality to be measured and be realized by double light path signal sensor
Non-contact detection water quality, changes or cleans simple, uses double-deck shading housing, can avoid by light source, external environment and light
The interference that test result is produced by energy hunting, low-power consumption, detection process pollution-free.
Summary of the invention
The technical problem to be solved is for above-mentioned deficiency of the prior art, it is provided that a kind of contactless
Oil sensor in water, it is novel in design rationally, can realize oil content in non-contact detection real time on-line monitoring water, continuous work
As time there is higher stability and sensitivity, pollution-free, low-power consumption, it is simple to promote the use of.
For solving above-mentioned technical problem, the technical solution used in the present invention is: oil sensor in a kind of contactless water, its
It is characterised by: include that shell body and inner surface are smooth and extend into for guiding the conduit of water quality to be measured inside shell body, and
The sensing testing device being arranged in shell body, described sensing testing device include double light path signal sensor and with described pair of light
The base that road signal sensor matches, described double light path signal sensor connects and has with described double light path signal sensor even
Logical light trapping, described double light path signal sensor includes inner housing and the light source generator being arranged in inner housing and institute
State the beam splitter of light source generator connection, be arranged on described beam splitter side and the reference light perpendicular with described light source generator
Road detector and the optical path detector being arranged on described beam splitter opposite side, described optical path detector includes measuring light
Road incidence channel and the optical path passage perpendicular with described optical path incidence channel, described optical path incidence channel with
The described optical path passage position that crosses is provided with the measurement cavity of hollow structure, described conduit with measure the top of cavity even
Logical, light trapping connects with the position that crosses of described optical path incidence channel and described optical path passage, described measurement light
In the incidence channel of road, the position measuring cavity is provided with the first optical window, near measuring in described optical path passage
The position of cavity is provided with the second optical window.
Oil sensor in above-mentioned contactless water, it is characterised in that: described light source generator includes light source incidence channel
And the light source being arranged in described light source incidence channel and be arranged on the first convex lens on rear side of light source, light source is LED light source,
Being connected to power interface on described LED light source, one end of power interface enters with described light source in extending into described light source incidence channel
Penetrating the fixing connection of passage, the other end of power interface is exposed on the outer surface of shell body.
Oil sensor in above-mentioned contactless water, it is characterised in that: described reference light paths detector includes that reference reflects
Passage and be successively set on the second convex lens in described reference reflection channel, the 3rd convex lens and reference photodetector,
Second convex lens is installed near beam splitter side, and reference photodetector is connected to reference signal output interface, and reference signal is defeated
One end of outgoing interface is fixing with described reference reflection channel in extending into described reference reflection channel to be connected, and reference signal output connects
The other end of mouth is exposed on the outer surface of shell body.
Oil sensor in above-mentioned contactless water, it is characterised in that: the first optics in described optical path incidence channel
The front end of window is provided with the 4th convex lens, and the primary optical axis of the 4th convex lens and the primary optical axis of the first convex lens overlap.
Oil sensor in above-mentioned contactless water, it is characterised in that: the second optical window in described optical path passage
Rear side is disposed with the 5th convex lens, the 6th convex lens, optical filter and measurement photodetector, measures and connects on photodetector
There is a measurement signal output interface, measure one end of signal output interface and extend in described optical path passage and described measurement light
Paths is fixing to be connected, and the other end measuring signal output interface is exposed on the outer surface of shell body.
Oil sensor in above-mentioned contactless water, it is characterised in that: described power interface, reference signal output interface and
Measure signal output interface and be sub-miniature A connector;Described light source incidence channel, described reference reflection channel, described optical path enter
Penetrate passage, described optical path passage and described inner housing processing and fabricating to be integrated.
Oil sensor in above-mentioned contactless water, it is characterised in that: described base is fixedly mounted on shell body medial surface
On, base is provided with the through hole of the bottom connection measuring cavity, shell body and inner housing are black shading housing.
Oil sensor in above-mentioned contactless water, it is characterised in that: described light trapping is black Cornu Bovis seu Bubali formula light trapping.
Oil sensor in above-mentioned contactless water, it is characterised in that: described beam splitter is pellicle beamsplitter.
The present invention compared with prior art has the advantage that
1, the present invention is by arranging shell body and inner housing bilayer shading housing, can avoid by light source, external environment and
The interference that test result is produced by light energy fluctuation, it is simple to promote the use of.
2, the present invention is by arranging light trapping, and the homology that optical path detector is brought by weakening light source largely is done
Disturbing, reliable and stable, using effect is good.
3, the present invention is by arranging double light path signal sensor, the pulse signal warp with fixed frequency sending light source
After crossing beam splitter process, obtaining the optical signal of two-way same frequency, a road optical signal is directly changed by reference light paths detector
For current signal;Separately lead up to and be converted to current signal, optical path detector by optical path detector after liquid to be measured
In optical path incidence channel and optical path passage on be respectively provided with optical window, it is ensured that the maximum printing opacity of light source, keep away
Exempting from the absorption to light source of the impurity in air, reduce the error of contrast, using effect is good.
4, the present invention is novel in design rationally, and volume is little, can realize oil-containing in non-contact detection real time on-line monitoring water
Amount, it is simple to promote the use of.
In sum, the present invention is novel in design rationally, can realize oil-containing in non-contact detection real time on-line monitoring water
Amount, running hours has higher stability and sensitivity, pollution-free, low-power consumption, it is simple to promote the use of.
Below by drawings and Examples, technical scheme is described in further detail.
Accompanying drawing explanation
Fig. 1 is the structural representation of the present invention.
Description of reference numerals:
1 shell body;2 bases;3 inner housings;
4 beam splitters;5 first convex lenss;6 light sources;
7 power interfaces;8 snap rings;9 second convex lenss;
10 the 3rd convex lenss;11 reference photodetectors;12 the 4th convex lenss;
13 first optical windows;14 measure cavity;15 light trappings;
16 second optical windows;17 the 5th convex lenss;18 the 6th convex lenss;
19 optical filters;20 measure photodetector;
21 reference signal output interfaces;22 measure signal output interface.
Detailed description of the invention
As it is shown in figure 1, the present invention includes that shell body 1 and inner surface are smooth and extend into that shell body 1 is internal to be treated for guiding
Surveying the conduit of water quality, and the sensing testing device being arranged in shell body 1, described sensing testing device includes double light path signal
Detector and the base 2 matched with described double light path signal sensor, described double light path signal sensor connects and has and institute
State the light trapping 15 of double light path signal sensor connection, in described double light path signal sensor includes inner housing 3 and is arranged on
Beam splitter 4 that light source generator in housing 3 is connected with described light source generator, be arranged on described beam splitter 4 side and with institute
State the perpendicular reference light paths detector of light source generator and be arranged on the optical path detector of described beam splitter 4 opposite side,
Described optical path detector includes optical path incidence channel and the measurement light perpendicular with described optical path incidence channel
Paths, described optical path incidence channel and the described optical path passage position that crosses is provided with the measurement chamber of hollow structure
Body 14, described conduit connects with the top measuring cavity 14, light trapping 15 and described optical path incidence channel and described measurement
The position connection that crosses of path channels, is provided with the near the position measuring cavity 14 in described optical path incidence channel
One optical window 13, is provided with the second optical window 16 near the position measuring cavity 14 in described optical path passage.
As it is shown in figure 1, described base 2 is fixedly mounted on shell body 1 medial surface, base 2 is provided with measurement cavity 14
Bottom connection through hole, it is preferable that shell body 1 and inner housing 3 are black shading housing, and black housing does not reflect light,
Ensure that the light source of described light source generator does not detracts.
It should be noted that have, on the side of the shell body 1 of mounting seat 2, the apopore connected with described through hole, real
During border uses, the connection of described conduit is equipped with the measuring cell of water quality to be measured, and the water quality to be measured in measuring cell is worn successively through described conduit
Crossing described double light path signal sensor, base and shell body 1 to flow out, described catheter inside surface is smooth is in order to avoid water quality to be measured
Flow into deformation when measuring cavity 14, be flowed into the water column and the first optical window 13 and the second optical window 16 measured in cavity 14
Between all have gap, it is achieved non-contact detection water quality to be measured.
In the present embodiment, described light source generator, beam splitter 4, described reference light paths detector and described optical path are visited
Surveying device to be arranged in inner housing 3, inner housing 3 is arranged in shell body 1, in described conduit extend into shell body 1 and simultaneously with
Measurement cavity 14 in inner housing 3 connects, and the setting of the black shading housing of shell body 1 and inner housing 3 bilayer is in order to ensure
State the interference by external light source and light energy fluctuation, test result not produced of the water quality measurement environment to be measured that conduit guides.
As illustrated in fig. 1, it is preferred that described beam splitter 4 is pellicle beamsplitter.
It should be noted that beam splitter 4 is inclined and mounted on described light source generator and described reference light paths detector, and
Described light source generator and the described perpendicular laying of reference light paths detector, the angle that beam splitter 4 tilts ensures that described light source is sent out
Raw the device light path sent and the light path reflecting into described reference light paths detector are perpendicular, it is achieved in described reference light paths detector
Optical power loss is minimum.
Described reference light paths detector and described optical path detector are separately positioned on the both sides of beam splitter 4, through light splitting
Light after device 4 reflection enters described reference light paths detector, and the light after beam splitter 4 transmission enters described optical path and visits
Surveying device, described optical path detector includes optical path incidence channel and the survey perpendicular with described optical path incidence channel
Amount path channels, it is clear that the light path after beam splitter 4 transmission is bigger than the light path after beam splitter 4 reflects, optical path incidence is led to
Road and optical path passage exist gas interference, easily absorbs the light source that described light source generator sends, at described measurement light
In the incidence channel of road, the position measuring cavity 14 is provided with the first optical window 13, leans in described optical path passage
The nearly position measuring cavity 14 is provided with the second optical window 16, it is ensured that the light after beam splitter 4 transmission is maximum
Passing through, reduce the loss of energy in propagation path of light, the light that optical path incidence channel is incident simultaneously is radiated at measurement cavity
On water quality water column to be measured in 14, excite oil in water quality to be measured to send fluorescence, this fluorescence as secondary light source through optical path
Channel measurement.
As illustrated in fig. 1, it is preferred that described light trapping 15 is black Cornu Bovis seu Bubali formula light trapping.
Light trapping 15 connects with the position that crosses of described optical path incidence channel and described optical path passage, uses
Light trapping 15 is in order to light is at the water quality to be measured by described optical path incidence channel, measured in cavity 14 and described measurement light
During paths, path changes, it is to avoid light is through entering water quality to be measured with water quality back reflection to be measured, to described optical path
Light in passage brings homology to disturb, thus brings measurement error.
As it is shown in figure 1, described light source generator includes light source incidence channel and is arranged in described light source incidence channel
Light source 6 and be arranged on the first convex lens 5 on rear side of light source 6, light source 6 is LED light source, described LED light source is connected to power supply and connects
Mouth 7, one end of power interface 7 is fixing with described light source incidence channel in extending into described light source incidence channel to be connected, and power supply connects
The other end of mouth 7 is exposed on the outer surface of shell body 1.
It should be noted that during the light source device of described light source generator is chosen, by spectrofluorophotometer,
Water quality to be measured is analyzed in advance experiment, determines maximum excitation wavelength and the fluorescence of this water quality to be measured according to experimental result
Wavelength, the experimental result of spectrofluorophotometer is that choosing of light source provides foundation.
In the present embodiment, the light source incidence channel of described light source generator is installed light source 6 and the first convex lens successively
5, preferred light source 6 uses LED light source, power interface 7 can connect a power supply with impulse modulation function, by having
The power supply of the power supply of impulse modulation function, light source 6 can send the pulsed optical signals of fixed frequency, by the first convex lens 5
The optical signal of multiple convergences reaches beam splitter 4, and being disposed to of the first convex lens 5 strengthens the optical signal that sends of light source 6, subtracts
The light source dissipated less.
As it is shown in figure 1, described reference light paths detector includes reference reflection channel and to be successively set on described reference anti-
Penetrating the second convex lens the 9, the 3rd convex lens 10 and reference photodetector 11 in passage, the second convex lens 9 is near beam splitter 4 one
Side is installed, and reference photodetector 11 is connected to reference signal output interface 21, and one end of reference signal output interface 21 is stretched into
Fixing with described reference reflection channel in described reference reflection channel and be connected, the other end of reference signal output interface 21 exposes
On the outer surface of shell body 1.
In the present embodiment, in described reference reflection channel, it is disposed with the second convex lens the 9, the 3rd convex lens 10 and reference
Photodetector 11, the light after beam splitter 4 reflects there will be scattering, arranges the second convex lens 9 and the 3rd convex lens 10 liang
Level collective optics is in order to the road reference signal sent by light source 6 farthest converges, and by reference photodetector
11 convert optical signals to signal of telecommunication output, it is simple to the acquisition process of follow-up reference signal.
As it is shown in figure 1, the front end of the first optical window 13 is provided with the 4th convex lens in described optical path incidence channel
12, the primary optical axis of the 4th convex lens 12 and the primary optical axis of the first convex lens 5 overlap.
It should be noted that the signal the most linearly propagated, the primary optical axis of the 4th convex lens 12 and the first convex lens 5
It is to obtain light after beam splitter 4 transmission for maximum magnitude that primary optical axis overlaps, if the primary optical axis of the 4th convex lens 12
Misplacing with the primary optical axis of the first convex lens 5, inevitably cause the loss of optical signal, employing the 4th convex lens 12 can be by institute
State the light collection of optical path incidence channel inscattering.
As it is shown in figure 1, be disposed with on rear side of the second optical window 16 in described optical path passage the 5th convex lens 17,
6th convex lens 18, optical filter 19 and measurement photodetector 20, measurement photodetector 20 is connected to measure signal output and connects
Mouth 22, one end of measurement signal output interface 22 is fixing with described optical path passage in extending into described optical path passage to be connected
Connecing, the other end measuring signal output interface 22 is exposed on the outer surface of shell body 1.
It should be noted that optical filter 19 is selected sends the optical filter that fluorescence is supporting, according to fluorescence spectrophotometry with oil
The excitation wavelength of meter experiment and the result of wavelength of fluorescence, choose the optical filtering that the effective wavelength for the oily fluorescence sent passes through
Sheet.
In the present embodiment, in described optical path passage, the light after the second optical window 16 transmission there will be scattering,
5th convex lens 17 is set and the 6th convex lens 18 two-stage collective optics be another drive test amount signal in order to light source 6 is sent
The convergence of big degree, inevitably there will be noise jamming on the propagation path of light, and arranging optical filter 19 is in order to will relatively
Clutter on big light path filters, it is ensured that effective optical signal passes through, and effective optical signal is by measuring photodetector 20 by light
Signal is converted to signal of telecommunication output, it is simple to the acquisition process of follow-up measurement signal.
During actual installation uses, first convex lens the 5, second convex lens the 9, the 3rd convex lens the 10, the 4th convex lens the 12, the 5th
Convex lens the 17, the 6th convex lens the 18, first optical window the 13, second optical window 16 and optical filter 19 are installed on the various channels
Shi Jun installs by snap ring 8 is movable, it is simple to follow-up dismounting and replacing element, using effect is good.
As it is shown in figure 1, described power interface 7, reference signal output interface 21 and measurement signal output interface 22 are SMA
Joint, sub-miniature A connector is a kind of universal joint, choosing so that input signal is connected with external equipment with output signal of sub-miniature A connector
Convenient;Described light source incidence channel, described reference reflection channel, described optical path incidence channel, described optical path passage
It is integrated with described inner housing 3 processing and fabricating.
The using method of the present invention is: outside reference signal output interface 21 and measurement signal output interface 22 being respectively connected to
In portion's signal condition equipment, described external signal conditioning device can be by reference signal output interface 21 and measurement signal output interface
The signal of telecommunication of 22 outfans carries out luminous power conversion, it is simple to the water oil concentration of measurement of comparison water quality to be measured, water quality to be measured is passed through
In described conduit, being passed through the pulse power of certain frequency for power interface 7, the pulse power is that light source 6 is powered, and light source 6 sends one
Determining the optical signal of frequency, this optical signal propagates to beam splitter 4 through the first convex lens 5 optical signal enhancing, the light that beam splitter 4 will strengthen
Signal is divided into the optical signal that two-way frequency is identical, a road to be that the signal after beam splitter 4 reflects detects vertically into reference light paths
Device, the signal after another Lu Weijing beam splitter 4 transmission enters optical path detector;Enter the optical signal of reference light paths detector
Converge to be radiated on reference photodetector 11 through the second convex lens 9 and the 3rd convex lens 10 and be converted to the reference signal of telecommunication, reference
The signal of telecommunication enters external signal conditioning device by reference signal output interface 21;Enter the optical signal warp of optical path detector
The first maximum printing opacity of optical window 13 is used, it is to avoid in paths, gas is to light after 4th convex lens 12 optically focused
Absorbing, the light after the first optical window 13 excites the water quality to be measured measured in cavity 14 to send fluorescence, and this fluorescence enters institute
State optical path passage, measure the light trapping 15 after the water quality to be measured in cavity 14 and optical signal is played holding effect, it is to avoid light
Through entering water quality to be measured with water quality back reflection to be measured, homology is brought to disturb to the light in described optical path passage, described
The second maximum printing opacity of optical window 16 on optical path passage, light is again through the 5th convex lens 17 and the 6th convex lens
Through optical filter 19 filtering clutter after mirror 18 convergence, the optical signal of filtering clutter is radiated on measurement photodetector 20 and is converted to survey
The amount signal of telecommunication, measures the signal of telecommunication by measuring signal output interface 22 and enters external signal conditioning device, wherein, repeatedly obtain simultaneously
Take and described reference light paths detector is measured in reference signal output interface 21 and described optical path detector signal output connect
The data of mouth 22 output, can get rid of light source and change the impact brought, according to measuring signal output in described optical path detector
The different pieces of information of interface 22 output calculates oil concentration change, non-contacting realizes the measurement of oil concentration in water, pollution-free, low merit
Consumption, can work continuously, have higher stability and sensitivity.
The above, be only presently preferred embodiments of the present invention, not impose any restrictions the present invention, every according to the present invention
Any simple modification, change and the equivalent structure change that above example is made by technical spirit, all still falls within skill of the present invention
In the protection domain of art scheme.
Claims (9)
1. oil sensor in a contactless water, it is characterised in that: include shell body (1) and inner surface is smooth and outside extending into
Housing (1) is internal for guiding the conduit of water quality to be measured, and is arranged on the sensing testing device in shell body (1), described biography
Sensing electricity testing device includes double light path signal sensor and the base (2) matched with described double light path signal sensor, described double
Connecting on optical path signal detector and have the light trapping (15) connected with described double light path signal sensor, described double light path signal is visited
Survey device and include the light splitting that inner housing (3) and the light source generator being arranged in inner housing (3) are connected with described light source generator
Device (4), it is arranged on described beam splitter (4) side and the reference light paths detector perpendicular with described light source generator and is arranged on
The optical path detector of described beam splitter (4) opposite side, described optical path detector include optical path incidence channel and
The optical path passage perpendicular with described optical path incidence channel, described optical path incidence channel and described optical path
The passage position that crosses is provided with the measurement cavity (14) of hollow structure, and described conduit connects with the top measuring cavity (14),
Light trapping (15) connects with the position that crosses of described optical path incidence channel and described optical path passage, described measurement light
It is provided with the first optical window (13), in described optical path passage near the position measuring cavity (14) in the incidence channel of road
The position measuring cavity (14) is provided with the second optical window (16).
2. according to oil sensor in the contactless water described in claim 1, it is characterised in that: described light source generator includes light
Source incidence channel and the light source (6) being arranged in described light source incidence channel and be arranged on the first convex lens of light source (6) rear side
Mirror (5), light source (6) is LED light source, and described LED light source is connected to power interface (7), and one end of power interface (7) extend into institute
Stating interior the fixing with described light source incidence channel of light source incidence channel to be connected, the other end of power interface (7) is exposed at shell body (1)
Outer surface on.
3. according to oil sensor in the contactless water described in claim 2, it is characterised in that: described reference light paths detector bag
Include reference reflection channel and the second convex lens (9) being successively set in described reference reflection channel, the 3rd convex lens (10)
With reference photodetector (11), the second convex lens (9) is installed near beam splitter (4) side, on reference photodetector (11)
Be connected to reference signal output interface (21), one end of reference signal output interface (21) extend in described reference reflection channel with
Described reference reflection channel is fixing to be connected, and the other end of reference signal output interface (21) is exposed at the outer surface of shell body (1)
On.
4. according to oil sensor in the contactless water described in claim 3, it is characterised in that: described optical path incidence channel
The front end of interior first optical window (13) is provided with the 4th convex lens (12), the primary optical axis of the 4th convex lens (12) and the first convex lens
The primary optical axis of mirror (5) overlaps.
5. according to oil sensor in the contactless water described in claim 4, it is characterised in that: in described optical path passage
Two optical windows (16) rear side is disposed with the 5th convex lens (17), the 6th convex lens (18), optical filter (19) and measures light
Electric explorer (20), measures and is connected on photodetector (20) measure signal output interface (22), measure signal output interface
(22) one end is fixing with described optical path passage in extending into described optical path passage to be connected, and measures signal output interface
(22) the other end is exposed on the outer surface of shell body (1).
6. according to oil sensor in the contactless water described in claim 5, it is characterised in that: described power interface (7), reference
Signal output interface (21) and measurement signal output interface (22) are sub-miniature A connector;Described light source incidence channel, described reference are anti-
Penetrate passage, described optical path incidence channel, described optical path passage and described inner housing (3) processing and fabricating to be integrated.
7. according to oil sensor in the contactless water described in claim 1, it is characterised in that: described base (2) fixedly mounts
On shell body (1) medial surface, base (2) is provided with the through hole of the bottom connection measuring cavity (14), shell body (1) and interior
Housing (3) is black shading housing.
8. according to oil sensor in the contactless water described in claim 1, it is characterised in that: described light trapping (15) is black
Cornu Bovis seu Bubali formula light trapping.
9. according to oil sensor in the contactless water described in claim 1, it is characterised in that: described beam splitter (4) is thin film
Beam splitter.
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Cited By (2)
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CN107144527A (en) * | 2017-06-12 | 2017-09-08 | 智慧盈通(北京)工业技术有限公司 | Detection device and the light source light splitting body and photometric detection module for it |
CN107589074A (en) * | 2017-10-30 | 2018-01-16 | 陕西正大环保科技有限公司 | A kind of anti-pollution structure and method of contactless water quality sensor |
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