CN205157429U - Quick detection device of microorganism based on mie scattering - Google Patents
Quick detection device of microorganism based on mie scattering Download PDFInfo
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- CN205157429U CN205157429U CN201520822414.2U CN201520822414U CN205157429U CN 205157429 U CN205157429 U CN 205157429U CN 201520822414 U CN201520822414 U CN 201520822414U CN 205157429 U CN205157429 U CN 205157429U
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Abstract
The utility model discloses a quick detection device of microorganism based on mie scattering, including laser instrument, optics focus system, detector array frame, sample cell and photoelectric detector spare. The laser beam of laser instrument transmission forms the parallel light behind the collimation, then assemble the microorganism sample that shines in the sample cell via the optics focus system on, the microorganism by behind the laser irradiation, go out the scattered light to spatial emission, the photoelectric detector spare that the scattered light was encircleed around the sample cell is received, and is theoretical based on mie scattering, through the computer to the received photosignal, analyze calculation, can arrive the form of current microorganism by real -time detection. The quick real -time detection of microorganism has been realized to this device, adopts the principle of optics scattering, improved measuring speed and precision, has realized that the signal of gathering the in -process is gathered in real time, processing and assay, has wide application prospect.
Description
Technical field
The utility model relates to technical field of biological, and particularly a kind of Mie scattering utilizing illumination to penetrate particulate detects the pick-up unit of microorganism fast.
Background technology
Microorganism is all tiny organisms that are invisible or that do not see, and individual small, structure is simple, usually with the biology that optical microscope and electron microscope just can be seen clearly, is referred to as microorganism.Microorganism comprises bacterium, virus, mould, saccharomycete etc.The detection of microorganism has great significance in food security, medical diagnosis on disease and control, bio-science research etc.The quick testing requirement of microorganism detects objective microbe within the time short as far as possible, simultaneously sensitivity and specificity high, operate simple as far as possible.
Traditional microorganism detection method mainly contains cultivates embrane method, spiral planar counting method, filter membrane method and emerging ATP bioluminescence method, electrical impedance method, color change, Flow Cytometry and laser scanner technique.The usual cost compare of these methods is high, needs carry out the cultivation of some to microorganism in advance and add in incubation and specifically cultivate reagent, and incubation needs to expend the more time simultaneously, and testing result occurs that false-positive possibility is higher.Therefore, need that one does not need additionally to introduce chemical reagent, versatility is good and detect microbial detection device fast.
Summary of the invention
The purpose of this utility model is to overcome above-mentioned the deficiencies in the prior art, a kind of microbial rapid detection device based on Mie scattering is provided, use this device greatly can improve speed and the precision of detection compared to traditional microorganism detection method, and simple to operate, highly versatile.
The technical solution of the utility model is:
A kind of microbial rapid detection device based on Mie scattering, comprise laser instrument, optical focusing system, sample cell, detector array framework and multiple photodetector, described optical focusing system is between described laser instrument and described sample cell, and the laser beam that laser instrument sends focuses in sample cell through optical focusing system; The spherical basket structure that described detector array framework is made up of the semicircular frame arm that many root radiuses are equal, described frame arm is cage bar, and sample cell is positioned at detector array frame center; Every bar frame arm is provided with some exploration holes, the described photodetector that a detection direction is inside is installed in each exploration hole.
Preferably, described frame arm is angularly uniformly distributed at interval at its place sphere, and described exploration hole is equidistantly uniformly distributed in every bar frame arm.
Preferred further, described frame arm totally 4, forms 2 orthogonal annulus of place plane, and wherein each annulus is made up of relative 2 frame arm.
Further preferred, every bar frame arm is distributed with 7 exploration holes, 4 frame arm add up to 28 exploration holes, can install 28 photodetectors.
Preferably, described laser instrument is the single wavelength laser of power adjustable.
Preferably, described sample cell is the hollow ball of a transparent material, and the sample cell centre of sphere overlaps with the centre of sphere of detector array framework.
Preferred further, described laser emitting light is the collimated laser beam of collimation, and the focus of described optical focusing system overlaps with the centre of sphere of sample cell, focuses on the center of solution to be measured in sample cell during laser beam parallel input light focusing system.
Another is preferred further, and the material of described sample cell is glass.
Preferably, the optical axis extended line being arranged on all photodetectors in exploration hole converges at the centre of sphere of detector array framework.
Preferably, described photodetector is photodiode.
Technical solutions of the utility model carry out microorganism detection based on Mie theory.Mie theory is that in research transparent medium, when monochromatic optical wave is irradiated on the spheric grain of arbitrary diameter and composition, the characteristic of light wave generation scattering and the theory of solution, be widely applied in fields such as environmental protection, the energy, astronomy, meteorology, medical science.Microorganism in transparency liquid, after the irradiation of laser, scattered light can be sent in space towards periphery, and there is correlativity in the scattered light intensity in different angles space and particle diameter, difform particle is distributed with different rules at the scattered light intensity in space, by collecting the scattered light of surrounding space, the shape-structure parameter of microorganism can be solved based on Mie theory.For realizing the rapid microbial detection based on Mie scattering, need by the monochromatic light exposure of certain energy on microorganism, the utility model have employed laser instrument as radiation source, and laser has the advantages that monochromaticity is good, concentration of energy, beam quality are high; Photodiode has fast response time, feature that noise is low, is the conventional device in photoelectric detection system.Simultaneously in order to collection space scattered light, need to lay photodetector around microorganism, the utility model have employed photodiode, has fast response time, feature that noise is low.
Technical solutions of the utility model have the following advantages:
1. photodetector is distributed on the framework of spherical caged, and microorganism to be detected is positioned at frame center, makes photodetector can collection space scattered light adequately and uniformly, ensure that accuracy of detection; According to different detection targets and requirement, frame arm can also expand to different structure, meets the structural requirement of different detection;
2., without the need to introducing extra detection reagent when the utility model pick-up unit detects different microorganisms, set of device can detect plurality of target microorganism, pick-up unit highly versatile;
3. photoelectric detector can realize photoelectric signal transformation fast, and signal input computing machine high speed processing, can obtain real-time testing result, realize detecting real-time.
Accompanying drawing explanation
Fig. 1 is the microbial rapid detection apparatus structure stereographic map of the utility model based on Mie scattering.
Wherein:
1: laser instrument; 2: optical focusing system; 3: detector array framework; 31: frame arm; 32: exploration hole; 4: sample cell; 5: photodetector.
Embodiment
The utility model is described further by embodiment below in conjunction with accompanying drawing, to understand the utility model better.
Composition graphs 1, the microbial rapid detection device based on Mie scattering is made up of laser instrument 1, optical focusing system 2, detector array framework 3, sample cell 4 and photodetector 5.The spherical basket structure that detector array framework 3 is made up of four identical semicircle arcuation frame arm 31, bulb diameter is 203mm, the thickness of single frame arm 31 is 26mm, every root frame arm 31 is equidistantly evenly distributed with the exploration hole 32 that 7 are used for installing detector; The optical maser wavelength of laser instrument 1 is 632nm, and power is that 0mW to 100mW is adjustable, built-in collimation filter unit, and the laser of transmitting is collimation directional light; The focus of optical focusing system 2 overlaps with the centre of sphere of detector array framework 3, and the back focal length of optical focusing system 2 is 260mm, and the laser that laser instrument 1 is launched converges at focus place through optical focusing system 2; Sample cell 4 is generally transparent material and makes, in order to hold solution to be measured, analyze for ease of detecting, adopt the structure of space symmetr as far as possible, the hollow ball-shape container that in the present embodiment, sample cell 4 is made for glass, be placed in detector array framework 3, the centre of sphere of sample cell 4 overlaps with the centre of sphere of detector array framework 3, and the bulb diameter of sample cell 4 is 79mm; Installed in the exploration hole 32 of frame arm 31 and amounted to 28 photodetectors 5, the optical axis extended line of photodetector 5 all converges at the centre of sphere of detector array framework 3.
The principle of device is as follows: the collimated laser beam after the collimation emitted by laser instrument 1 is after optical focusing system 2 is assembled, focus on the focus place of optical focusing system 2, because the focus of optical focusing system 2 overlaps with the centre of sphere of detector array framework 3 and sample cell 4, laser beam focuses on the centre of sphere place of sample cell 4 after optical focusing system 2 is assembled, microbiological specimens in sample cell 4 is owing to being subject to the irradiation of laser, spatial emission can go out scattered light towards periphery, scattered light is received respectively by the photodetector 5 in each orientation, light intensity is converted to electric signal, Signal transmissions is to computing machine, later stage to the Photoelectric Signal Processing analysis obtained, obtains the form species category information of the microorganism to be checked in sample cell 4 by computing machine.
Should understand; above-described embodiment is only for illustrating technical conceive of the present utility model and feature; its object is to understand content of the present utility model for those skilled in the art and implement according to this, not embodiment is exhaustive, can not limit protection domain of the present utility model with this.Allly modify according to technical scheme of the present utility model or equivalent to replace, and not departing from aim and the scope of technical solutions of the utility model, it all should be encompassed in the middle of right of the present utility model.
Claims (10)
1. the microbial rapid detection device based on Mie scattering, comprise laser instrument (1), optical focusing system (2) and sample cell (4), described optical focusing system (2) is positioned between described laser instrument (1) and described sample cell (4), the laser beam that laser instrument (1) sends focuses in sample cell (4) through optical focusing system (2), it is characterized in that:
Also comprise detector array framework (3) and multiple and photodetector (5), the spherical basket structure that described detector array framework (3) is made up of the semicircular frame arm (31) that many root radiuses are equal, described frame arm (31) is cage bar, and sample cell (4) is positioned at detector array framework (3) center; Every bar frame arm (31) is provided with some exploration holes (32), the described photodetector (5) that a detection direction is inside is installed in each exploration hole (32).
2. the microbial rapid detection device based on Mie scattering according to claim 1, it is characterized in that: described frame arm (31) is angularly uniformly distributed at interval at its place sphere, described exploration hole (32) is equidistantly uniformly distributed on every bar frame arm (31).
3. the microbial rapid detection device based on Mie scattering according to claim 2, it is characterized in that: described frame arm (31) totally 4, form 2 orthogonal annulus of place plane, wherein each annulus is made up of relative 2 frame arm (31).
4. the microbial rapid detection device based on Mie scattering according to claim 3, is characterized in that: every bar frame arm (31) is distributed with 7 exploration holes (32).
5. the microbial rapid detection device based on Mie scattering according to claim 1, is characterized in that: the single wavelength laser that described laser instrument (1) is power adjustable.
6. the microbial rapid detection device based on Mie scattering according to claim 1, it is characterized in that: described sample cell (4) is the hollow ball of a transparent material, and sample cell (4) centre of sphere overlaps with the centre of sphere of detector array framework (3).
7. the microbial rapid detection device based on Mie scattering according to claim 6, it is characterized in that: described laser instrument (1) emergent light is the collimated laser beam of collimation, and the focus of described optical focusing system (2) overlaps with the centre of sphere of sample cell (4).
8. the microbial rapid detection device based on Mie scattering according to claim 6, is characterized in that: the material of described sample cell (4) is glass.
9. the microbial rapid detection device based on Mie scattering according to claim 1, is characterized in that: the optical axis extended line being arranged on all photodetectors (5) in exploration hole (32) converges at the centre of sphere of detector array framework (3).
10. the microbial rapid detection device based on Mie scattering according to claim 1, is characterized in that: described photodetector (5) is photodiode.
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Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN105136745A (en) * | 2015-10-21 | 2015-12-09 | 南京先进激光技术研究院 | Rapid microorganism detecting device based on mie scattering |
CN106596498A (en) * | 2017-01-19 | 2017-04-26 | 大连理工大学 | Device for quickly detecting air microorganisms |
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Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN105136745A (en) * | 2015-10-21 | 2015-12-09 | 南京先进激光技术研究院 | Rapid microorganism detecting device based on mie scattering |
CN106596498A (en) * | 2017-01-19 | 2017-04-26 | 大连理工大学 | Device for quickly detecting air microorganisms |
CN106596498B (en) * | 2017-01-19 | 2018-09-04 | 大连理工大学 | A kind of air microbe device for fast detecting |
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