CN204536154U - A kind ofly collecting and distributingly to penetrate, the micro-stream in one becomes original position Online Transaction Processing - Google Patents

Abstract

One is collecting and distributing penetrates, the micro-stream in one becomes original position Online Transaction Processing, exist can not original position observe online for normal capillary pipe flow graph, micro-rheometer test system and light scattering rheometer test system can not observe the problem of sample microscopic appearance intuitively, the utility model devises one can carry out laser light scattering and fractographic integrated flat capillary rheology original position Online Transaction Processing simultaneously when rheology testing, stable shear flow field and the rheological parameters relevant to material macro property can either be provided by theological damage, detection and the observation of polymeric material being carried out to original position internal microstructure can be realized again by optical technology, achieve micro imaging system, the combination of laser light scattering system and capillary rheology system, the relation of being more convenient between research material micromechanism and macro property.The laboratory being suitable for high molecular polymer processed and applied uses.

Description

A kind ofly collecting and distributingly to penetrate, the micro-stream in one becomes original position Online Transaction Processing

Technical field

The present invention relates to rheological properties of polymer materials field tests, be specifically related to a kind of rheological property original position Online Transaction Processing, be related specifically to a kind ofly collecting and distributingly to penetrate, the micro-stream in one becomes original position Online Transaction Processing.

Background technology

Rheological is the behavior of elasticity, plasticity and the viscous deformation that macromolecular material produces under effect of stress, the rheological data of macromolecular material is technological parameter the most basic in its processing and forming, has important effect to the design of the determination of the choice and operation of raw material, shaping Optimal technique process, former and mould and the quality that improves goods.Current macromolecular material positive function and customizations future development, and so that method and minimum sample solve the key that processability issues is new material exploitation efficiently.

Flow graph is adopted material to be carried out to the mensuration of rheological characteristics, it is a kind of method of testing of being undertaken testing by simulation actual production technique, have fast, efficiently, advantage accurately and reliably, in research and development and quality control, rheometer test has become indispensable Method means.By flow graph can: Study Polymer Melts Blending Processes, understand in depth in polymer blending process microscopic pattern development; The change of research processing conditions and the relation between material flowability matter and Mechanical Properties of Products; Relation between research material flowing property and molecular structure and component structure; The flow phenomenon of research exception is as extrusion swelling phenomenon, the rule of melt fracture phenomena generation, reason and conquering method etc.But, the comprehensive embodiment of the macro property of goods micmstructure of polymer often, the research of single macroscopic appearance in depth can not disclose the micromechanism of polymeric inner, remains in certain deficiency for the relation explained better between polymeric material macro property and micromechanism.In order to better understand the relation between material microstructure and macro property, the emphasis of researchist starts shift from macroscopic view to micromechanism direction and go deep into.Polymer samples after current rheometer test system all can only obtain " freezing " while obtaining rheological property result, and then characterize accordingly, cannot characterize the Structure and morphology of the polymkeric substance freezed in front or freezing process.By theological damage and other backup system such as optical technology are combined, from both macro and micro two aspect, polymkeric substance is studied, original position on-line tracing is carried out to the rheology testing process of polymkeric substance, significant for the relation disclosed between polymeric material micromechanism and macro property.

Optical technology is the effective means of research material microstructure, if optical detective technology and theological damage can be organically combined, realize the original position on-line checkingi research of material, will contribute to the understanding to micmstructure of polymer and macro property.Light scattering technique is a kind of method of good Non-Destructive Testing material internal unevenness, is combined by theological damage manufactured rheo-optics test macro with light scattering technique.Rheo-optics test macro makes component distortion or deflection in sample to due to flowing, determines the anisotropy of the structure of matter, and then can obtain its microscopic characteristics by measurement light and influencing each other of stream material.Rheo-optics test macro can detect to be sheared or stretches on the impact of sample micromechanism and the microstructure change of flow media; The structure change of shear-induced or the crystallization process of blend polymer can be observed, detect while realizing structural parameters and rheological parameter.

Except light scattering technique, micro-imaging technique is that current minority can, intuitively to the method that material is observed and measured simultaneously, utilize micro-imaging technique except matter dimensions, can also observe the shape of material, structure and surface topography and detect.Microscope combines with theological damage and constitutes another kind of optical flow and become test macro, the direct observation of material internal structure can be carried out while carrying out flow measurement, Study Polymer Melts micromechanism change in a shear condition better, in conjunction with microscope and rheological method, can study shearing and the impact of deformation on sample structure.

Theological damage and optical technology combine and can study the relation between the macro property of polymkeric substance and micromechanism, but current instrument all exists some deficiency.Microscope combines with theological damage, although the observation of material internal structure can be carried out while carrying out flow measurement, thus determine its structural property, but itself also has certain limitation: Anton Paar company is on the basis of MCR flow graph, microscope is installed on flow graph, achieve the observation to sample microscopic appearance in shear flow process and detection, but to be fractographicly limited in scope, the structure display for polymkeric substance smaller szie is not obvious, light scattering technique is combined with theological damage, there is some defect equally: Yoshiaki etc. have manufactured instrument (the Yoshiaki TAKAHASHI that has small-angle neutron scattering technology and flow measurement concurrently, Masahiro NODA, Masanori NARUSE, Toshiji KANAYA, Hiroshi WATANBE, Tadashi KATO, Masayuki IMAI, Yushu MATSUSHITA.Apparatus for small-angle neutron scattering and rheological measurements under sheared conditions.NIHON REOROJI GAKKAISHI, 2000, 28:187-191), this device is except carrying out the research of steady shear speed aspect, for the creep of most of complex fluid, stress relaxation phenomenon can both obtain good research effect, but sample microscopic appearance can not be observed intuitively, that detected is limited in scope.Chemistry Suo Hanzhichao seminar of the Chinese Academy of Sciences invents and has manufactured a vertebral plate shear rheology device (Charles C.Han, Yonghua Yao, Ruoyu Zhang, Erik K.Hobbie.Effect of shear flow on multi-component polymer mixtures.Polymer, 2006,3:3271-3286; ZL200510123609.9,2010.12.29, combining laser light scattering under shearing field and microscopical in-situ observation system), micro-image under shearing condition and light scattering information can be obtained by arranging corresponding light hole and small angle scattering device and micro imaging system at the lower planes of vertebral plate cutting system simultaneously; But micromechanism information and rheological behaviour do not combine by this device, its vertebral plate cutting system only has 10 to the range of shear rate that sample is sheared ^-2~ 2 × 10 ³s ^-1, small angle scattering device (can receive the scattered light of-35 ° ~ 35 °) cannot receive the scattered light information of large scattering angle (>=35 °), and for high speed shear state, and the structural information of smaller szie can not effectively obtain.

The kapillary that existing capillary rheometer uses is steel circular cylindrical, in order to passing through of light when ensureing that scattering measuring system and micro imaging system and capillary rheometer are used in conjunction, kapillary need use the material that can make light therethrough, as quartz glass etc. (201310176593.2, CN103245651A, 2013.08.14, a kind of detection method being applicable to the eccentric focus type laser-Induced Fluorescence Detection device that capillary column detects); But when exciting light incides on cylindrical transparent kapillary, due to the lens effect that cylindrical capillary tube exists, dioptrics distortion is produced to light beam, changes light path, can not get micro-image accurately; Material directly cannot carry out macro-mechanical property test (such as stretch and tear) after cylindrical capillary tube die extrusion, thus cannot realize the association from microcosmic to macro property data.

Summary of the invention

Relation comprehensively in depth between Study Polymer Melts micromechanism and macro property, need be applied to stream simultaneously and become in detection system by micro-imaging technique, laser light scattering techniques.Exist can not original position observe online for current capillary rheometer, it is not obvious that micro-rheometer test system observes display for small size polymer architecture, and light scattering rheometer test system can not observe the problem of sample microscopic appearance intuitively, the utility model devises one can carry out laser light scattering and fractographic integrated kapillary original position Online Transaction Processing simultaneously when rheology testing, structure change under stream variable field is associated with the rheological property of macroscopic view, for researching and developing the product of functionalization and customizations further, carry out development that macromolecular material newly fills a prescription and determine optimized processing technology, easy measure is provided.

The utility model solves the technical scheme that its technical matters adopts:

One is collecting and distributing penetrates, the micro-stream in one becomes original position Online Transaction Processing and comprises four basic modules: capillary rheometer (1), LASER Light Source (3), laser light scattering system (5) and micro imaging system (6), all be installed on optical table (2), laser light scattering system (5) and microscopy imaging system (6) share the flat hole kapillary (10) in capillary rheometer (1), light-scattering system (5) and microscopy imaging system (6) are installed on a high-precision optical systematic evaluation guide rail (4) on optical table (2), these two systems can move on high-precision optical systematic evaluation guide rail (4), realize the quick switching of laser light scattering light path and microscopes optical path.

Described capillary rheometer (1) is made up of controller (12), plunger (7), electric heating cover (8), barrel (9) and flat hole kapillary (10); Plunger (7) is connected with controller (12) by data line, and controller (12) is connected with computing machine by data line; The top of barrel (9) interior material is plunger (7), and the surrounding outer layer of barrel (9) is constant temperature electric heating cover (8), inside has heating wire, can realize the thermostatic control from room temperature to 300 DEG C; The wall of barrel (9) has a temperature probe (11), temperature probe (11) is connected with external opertaing device by data line with heating wire, can the actual temperature of polymer melt in experiments of measuring process; The below of barrel (9) is flat hole kapillary (10), the side of flat hole kapillary (10) outer electric heating cover (8) has the circular light hole (13) that a diameter is 2mm, the same position of relative opposite side, has the conical light hole (14) that a cone angle is 70 °.

Flat hole kapillary (10) in described capillary rheometer (1) adopts transparent quartz glass material to make, capillary bore mouth structure is flat hole (43), the position that light path is passed through when flat hole kapillary (10) detects is made as bilateral channel-shaped light path plane (42), and the entrance of flat hole kapillary (10) upper end material is pyramidal structure (41).

Described micro imaging system (6) is made up of LASER Light Source (3), condenser (16), long reach object lens (17), photographed images acquisition system (18) and external computer monitor (19), the front installation condenser (16) of circular light hole (13) of the upper diameter 2mm of capillary rheometer (1) electric heating cover (8), in the front of condenser (16), LASER Light Source (3) is installed, long reach object lens (17) are arranged on the dead ahead of the upper conical light hole (14) of electric heating cover (8), in the side of long reach object lens (17), photographed images acquisition system (18) is installed again, photographed images acquisition system (18) is connected with external computer monitor (19), LASER Light Source (3) during use, condenser (16), circular light hole (13), conical light hole (14), long reach object lens (17) and photographed images acquisition system (18) are in the same center line.

Described laser light scattering system (5) comprises LASER Light Source (3), horizontal laser light colimated light system, big angle detection system (31), little angle signal detection system (32) and rotatable adjutage (33); Wherein: horizontal laser light colimated light system comprises aperture (21), optical filtering (22), polarizer (23) and condenser (16); Big angle signal detection system (31) comprises camera lens a (25), camera lens b (26) and big angle signal detector (27), camera lens a (25) is made up of one group of identical wide-aperture concave lens and convex lens with camera lens b (26), two back-to-back installations of camera lens; Camera lens a (25) can receive the scattered light in 0 ~ 60 ° of angular range, after forming directional light, is focused on the inductor of big angle signal detector (27) by camera lens b (26); Little angle signal detection system (32) comprises analyzer (28), screen (29) and little angle signal detecting device (30); Horizontal laser light colimated light system is installed on the side of the circular light hole (13) of the upper diameter 2mm of capillary rheometer (1) electric heating cover (8), is followed successively by aperture (21), optical filtering (22), polarizer (23) and condenser (16) from LASER Light Source (3) to circular light hole (13); Big angle signal detection system (31) and little angle signal detection system (32) are installed in the side of the conical light hole (14) on electric heating cover (8); Little angle signal detection system (32) is installed in laser incident direction, and when horizontal laser light colimated light system, circular light hole (13), conical light hole (14) and little angle signal detection system (32) use, place point-blank; Big angle signal detector (27) is one with the CCD detecting device of mechanical shutter; Big angle signal detection system (31) is installed on a rotatable adjutage (33), and rotatable adjutage (33) and laser incident direction angle are θ, and during operation, θ can adjust; Little angle detection system is formed primarily of analyzer (28), screen (29) and little angle signal detecting device (30).

Described LASER Light Source (3) both can produce laser also can produce micro-imaging light source.

The beneficial effects of the utility model are: laser light scattering techniques, micro-imaging technique and theological damage are organically combined, stable shear flow field and the rheological parameters relevant to material macro property can either be provided by theological damage, detection and the observation of polymeric material being carried out to original position internal microstructure can be realized again by optical technology, relation between research material micromechanism and macro property is further investigation polymer product performance supplying method and means.

Whole test macro adopts Modular Structure Design, for convenience detach and installation, makes detection more fast with flexible, can be used alone a certain item detection means, also can alternate combinations use.

The main body of device is through transformation capillary rheometer, its capillary bore is flat structure, solve on the one hand light source through after the problem of optical distortion, flat extruded material can be directly used in the test of pulling strengrth etc. on the other hand, be conducive to the realization of optical system observing and extrusion process that is virtually reality like reality, realize while carrying out rheology testing, in-situ study is carried out to the shape characteristic of kapillary inner sample and micromechanism, relation between further research material micromechanism and macro property, realize from microcosmic to the association of macro property data.

Capillary rheology system, light scattering technique and micro-imaging technique organically combine by native system, achieve the detection to material in situ and observation, impart the research range that normal capillary pipe flow graph is larger, research contents is more extensive: research micron, submicron particle stably dispersing sex chromosome mosaicism in the polymer; The form reunion behavior of nano particle in shearing field in simulating cutting process; The orientation of Study Polymer Melts molecule under shear stress, crystallisation problems; Consistency problem between research compound substance; In research extrusion, particularly in high speed extrusion process, melt rotates, distortion, the phenomenon such as to break.Achieving under same experiment condition by switching micro imaging system and light-scattering system, obtaining spatial shape and the structure of sample in-situ, carry out the contrast verification of dynamic shearing sample macroscopic view and microscopic property after the match.The combination of micro imaging system, laser light scattering system and capillary rheology system, for the relation of more deep Study Polymer Melts material microstructure and macro property, the progress promoting the research and development of high performance material and material science is significant.

Below in conjunction with accompanying drawing, the utility model is further illustrated.

Accompanying drawing explanation

Fig. 1 is that the utility model a kind ofly collecting and distributingly to be penetrated, the micro-stream in one becomes original position Online Transaction Processing general structure schematic diagram.

Fig. 2 is the structural representation of capillary rheometer in Fig. 1 (1).

Fig. 3 is the light channel structure schematic diagram of micro imaging system in Fig. 1 (6).

Fig. 4 is the light channel structure schematic diagram of laser light scattering system (5) in Fig. 1.

Fig. 5 is the front view of flat hole kapillary (10) in Fig. 2.

Fig. 6 is the left view of flat hole kapillary (10) in Fig. 2.

Fig. 7 is the vertical view of flat hole kapillary (10) in Fig. 2.

Fig. 8 be in Fig. 1 laser light scattering system (5) and capillary rheometer (1) in conjunction with schematic diagram.

Fig. 9 be micro imaging system in Fig. 1 (6) with capillary rheometer (1) in conjunction with schematic diagram.

In figure:

1. capillary rheometer, 2. optical table, 3. laser instrument, 4. high-precision optical systematic evaluation guide rail, 5. laser light scattering system, 6. micro imaging system, 7. plunger, 8. electric heating cover, 9. barrel, 10. flat hole kapillary, 11. temperature probes, 12. controllers, 13. circular light holes, 14. conical light holes, 16. condensers, 17. long reach object lens, 18. photographed images acquisition systems, 19. monitors, 21. apertures, 22. light filters, 23. polarizers, 25. camera lens a, 26. camera lens b, 27. big angle signal detectors, 28. analyzers, 29. screens, 30. little angle signal detecting devices, 31. big angle signal detection systems, 32. little angle signal detection systems, 33. rotatable adjutages, 35.Y to, 36.Z to, 41. pyramidal structures, 42. light path planes, 43. flat hole, θ. the angle of big angle signal detection system and incident light.

Embodiment

With reference to accompanying drawing 1, the utility model one is collecting and distributing penetrates, the micro-stream in one becomes original position Online Transaction Processing and comprises capillary rheometer (1), LASER Light Source (3), laser light scattering system (5) and micro imaging system (6), all be installed on optical table (2), light-scattering system (5) and microscopy imaging system (6) share the flat hole kapillary (10) in capillary rheometer (1), light-scattering system (5) and microscopy imaging system (6) are installed on a high-precision optical systematic evaluation guide rail (4) on optical table (2), by computer software, the quick switching realizing laser light scattering light path and microscopes optical path is moved on high-precision optical systematic evaluation guide rail (4) to these two systems.

With reference to accompanying drawing 2, capillary rheometer (1) is made up of controller (12), plunger (7), electric heating cover (8), barrel (9) and flat hole kapillary (10); Plunger (7) is connected with controller (12) by data line, and controller (12) is connected with computing machine by data line; The top of barrel (9) interior material is plunger (7), and the surrounding outer layer of barrel (9) is constant temperature electric heating cover (8), inside has heating wire, can realize from room temperature to 300 DEG C of precision ± 0.01 DEG C thermostatic controls; The wall of barrel (9) has a temperature probe (11), temperature probe (11) is connected with external opertaing device by data line with heating wire, can the actual temperature of polymer melt in experiments of measuring process; The below of barrel (9) is flat hole kapillary (10), the side of flat hole kapillary (10) outer electric heating cover (8) has the circular light hole (13) that a diameter is 2mm, the same position of relative opposite side, have the conical light hole (14) that a cone angle is 70 °, to ensure that the scattered light within the scope of 2-70 ° can by optical scattering systems axiol-ogy.

With reference to accompanying drawing 2, accompanying drawing 3 and accompanying drawing 9, micro imaging system (6) is formed primarily of LASER Light Source (3), condenser (16), long reach object lens (17), photographed images acquisition system (18) and external computer monitor (19), the condenser (16) of phase difference ring is comprised in the front installation one of circular light hole (13) of the upper diameter 2mm of capillary rheometer (1) electric heating cover (8), in the front of condenser (16), LASER Light Source (3) is installed, long reach object lens (17) are arranged on the dead ahead of the upper conical light hole (14) of electric heating cover (8), in the side of long reach object lens (17), photographed images acquisition system (18) is installed again, photographed images acquisition system (18) is connected with external computer monitor (19), LASER Light Source (3) during use, condenser (16), circular light hole (13), conical light hole (14), long reach object lens (17) and photographed images acquisition system (18) are in the same center line.

With reference to accompanying drawing 3, the course of work of micro imaging system (6) is: be condensed on the circular light hole (13) of the upper diameter 2mm of electric heating cover (8) by LASER Light Source (3) by the condenser (16) of operating distance 60mm, be driven on the inner sample of flat hole kapillary (10), the bright ring that the front difference ring of condenser (16) is formed coincides with the Crape ring differed in object lens, and the light projecting flat hole kapillary (10) is caught on camera image capturing system device (18) reception through the object lens (17) of 20mm operating distance; Micro imaging system (6) can move to (36) are upper to (35) and z at y, for focusing on and select suitable viewing area, possess reflected light light field, the optical observation function reflected light differential interference function of difference and computing machine Synchronous function simultaneously.The camera view of photographed images acquisition system (18) CCD camera lens is 0.22 × 0.165mm;

With reference to accompanying drawing 2, accompanying drawing 4 and accompanying drawing 8, laser light scattering system (5) mainly comprises LASER Light Source (3), horizontal laser light colimated light system, big angle detection system (31), little angle signal detection system (32) and rotatable adjutage (33); Wherein: horizontal laser light colimated light system comprises aperture (21), optical filtering (22), polarizer (23) and condenser (16); Big angle signal detection system (31) comprises camera lens a (25), camera lens b (26) and big angle signal detector (27), wherein camera lens a (25) is made up of one group of identical wide-aperture concave lens and convex lens with camera lens b (26), two back-to-back installations of camera lens, both can collect the optical signalling of extensive angle, the image of acquisition is also undistorted; Camera lens a (25) can receive the scattered light in 0 ~ 60 ° of angular range, after forming directional light, is focused on the inductor of big angle signal detector (27) by camera lens b (26); Little angle signal detection system (32) comprises analyzer (28), screen (29) and little angle signal detecting device (30).Horizontal laser light colimated light system is installed on the side of the circular light hole (13) of the upper diameter 2mm of capillary rheometer (1) electric heating cover (8), is followed successively by aperture (21), optical filtering (22), polarizer (23) and condenser (16) from LASER Light Source (3) to circular light hole (13).Big angle signal detection system (31) and little angle signal detection system (32) are installed in the side of the conical light hole (14) on electric heating cover (8).Little angle signal detection system (32) is installed in laser incident direction, and when the little angle signal detection system (32) of horizontal laser light colimated light system, circular light hole (13), conical light hole (14) uses, place point-blank; Big angle signal detector (27) is one with the CCD detecting device of mechanical shutter; Big angle signal detection system (31) is installed on a rotatable adjutage (33), and rotatable adjutage (33) and laser incident direction angle are θ, and during operation, θ can adjust; Little angle detection system is formed primarily of analyzer (28), screen (29) and little angle signal detecting device (30), and screen is 11mm to the distance of sample, and little angle signal detecting device is a high-speed camera.

With reference to accompanying drawing 4 and accompanying drawing 8, the course of work of light-scattering system (5) is: 20 milliwatt wavelength are that the laser that penetrates of the LASER Light Source (3) of 633nm controls the size of hot spot through aperture (21), then light microscopic (22) after filtration, condenser (16), be driven on the sample of kapillary inside by the circular light hole (13) of the upper diameter 2mm of electric heating cover (8), the light scattering receiving system (5) be installed on high-precision optical systematic evaluation guide rail (4) by the conical light hole (14) on electric heating cover (8) through the scattered light sent after flat hole kapillary (10) and sample is received, the scattered light being 2 ° ~ 25 ° by conical light hole (14) range of scatter angles passes through to select the analyzer (28) added to be irradiated on screen (29), then, captured by the high-speed camera as little angle signal detecting device (30), polymer crystallization H is carried out _v, V _vthe detection of image, when not using analyzer (28), the scattered light of 20 ° ~ 70 ° of range of scatter angles, can carry out the research of the very high phase-splitting of intensity, adjusting rotatable adjutage (33) makes θ be 45 °, the scattered light being then 15 ° ~ 70 ° by the range of scatter angles of conical light hole (14) is first collected by the wide-aperture camera lens a (25) near kapillary, focused on big angle signal detector (27) by another identical high-aperture lenses b (26) after forming directional light, the great dynamic range high sensitivity two-dimensional array CCD controlled by controllable continuous mechanical shutter gathers, and mechanical shutter and CCD are controlled by the computing machine be connected with controller.

With reference to accompanying drawing 1, micro imaging system (6) and laser light scattering system (5) are arranged on one by computer-controlled high-precision optical systematic evaluation guide rail (4), can need to automatically switch between the two systems according to test.

With reference to accompanying drawing 5, accompanying drawing 6 and accompanying drawing 7, be passing through of light in guarantee light-scattering system and micro imaging system, flat hole kapillary (10) adopts transparent quartz glass material to make, to reduce the loss of light as far as possible; Simultaneously for avoiding traditional circular hole kapillary diverse location on the impact of light, capillary bore mouth structure is flat hole (43), and the position that light path is passed through when flat hole kapillary (10) detects is bilateral channel-shaped light path plane (42); The entrance of flat hole kapillary (10) upper end material is pyramidal structure (41), and the material being beneficial to melting enters kapillary smoothly.

Operation steps of the present utility model is as follows:

Before testing, check that whether the barrel (9) of capillary rheometer (1) is clean, whether flat hole kapillary (10) all the other various pieces that are whether intact, instrument stand intact, whether circuit is connected.Test temperature is set by temperature controller, flow graph barrel (9) is heated, after the temperature arrival design temperature of device display to be controlled, sample is added in barrel (9), by controller (12) the setting shearing condition of plunger (7), when the temperature stabilization of temperature controller is after design temperature, the plunger (7) on barrel (9) top is extruded material with certain speed or with the speed of certain rule change under the drive of CD-ROM drive motor from capillary die.In the process extruded, measure the pressure of flat hole kapillary (10) mouth mould porch, again in conjunction with known speed parameter, mouth mould and barrel parameter and rheological model etc., thus calculate the parameters such as the shear viscosity of melt under different shear rate.When detection system is operated under laser light scattering pattern, by computing machine control high-precision optical systematic evaluation guide rail (4), light scattering receiving system (5) is moved to the front of capillary rheometer (1), the exposure of setting mechanical shutter and two-dimensional array CCD, time delay, range of scatter angles is that the scattering laser of 0 ~ 20 ° is received by CCD, and the scattering laser that range of scatter angles is 20 ~ 70 ° is gathered by little angle signal detecting device (30).When being operated under micro-imaging pattern, by high-precision optical systematic evaluation guide rail (4), micro imaging system (6) is moved to the front of capillary rheometer (1), light field and polarization light source or flash light source illuminate in flat hole kapillary (10) sample be under design temperature, are then caught on camera image capturing system through long reach object lens (17) and receive.The rheological property data that the microscope gathered and light scattering result are used for recording with flow graph are further analyzed and matching.

Claims (1)

1. one kind is collecting and distributingly penetrated, the micro-stream in one becomes original position Online Transaction Processing and comprise four basic modules: capillary rheometer (1), LASER Light Source (3), laser light scattering system (5) and micro imaging system (6), all be installed on optical table (2), it is characterized in that:

Laser light scattering system (5) and microscopy imaging system (6) share the flat hole kapillary (10) in capillary rheometer (1), light-scattering system (5) and microscopy imaging system (6) are installed on a high-precision optical systematic evaluation guide rail (4) on optical table (2), these two systems can move on high-precision optical systematic evaluation guide rail (4), realize the quick switching of laser light scattering light path and microscopes optical path;

Described capillary rheometer (1) is made up of controller (12), plunger (7), electric heating cover (8), barrel (9) and flat hole kapillary (10); Plunger (7) is connected with controller (12) by data line, and controller (12) is connected with computing machine by data line; The top of barrel (9) interior material is plunger (7), and the surrounding outer layer of barrel (9) is constant temperature electric heating cover (8), inside has heating wire, can realize the thermostatic control from room temperature to 300 DEG C; The wall of barrel (9) has a temperature probe (11), temperature probe (11) is connected with external opertaing device by data line with heating wire, can the actual temperature of polymer melt in experiments of measuring process; The below of barrel (9) is flat hole kapillary (10), the side of flat hole kapillary (10) outer electric heating cover (8) has the circular light hole (13) that a diameter is 2mm, the same position of relative opposite side, has the conical light hole (14) that a cone angle is 70 °;

Flat hole kapillary (10) in described capillary rheometer (1) adopts transparent quartz glass material to make, capillary bore mouth structure is flat hole (43), the position that light path is passed through when flat hole kapillary (10) detects is made as bilateral channel-shaped light path plane (42), and the entrance of flat hole kapillary (10) upper end material is pyramidal structure (41);

Described micro imaging system (6) is made up of LASER Light Source (3), condenser (16), long reach object lens (17), photographed images acquisition system (18) and external computer monitor (19), the front installation condenser (16) of circular light hole (13) of the upper diameter 2mm of capillary rheometer (1) electric heating cover (8), in the front of condenser (16), LASER Light Source (3) is installed, long reach object lens (17) are arranged on the dead ahead of the upper conical light hole (14) of electric heating cover (8), in the side of long reach object lens (17), photographed images acquisition system (18) is installed again, photographed images acquisition system (18) is connected with external computer monitor (19), LASER Light Source (3) during use, condenser (16), circular light hole (13), conical light hole (14), long reach object lens (17) and photographed images acquisition system (18) are in the same center line,

Described laser light scattering system (5) comprises LASER Light Source (3), horizontal laser light colimated light system, big angle detection system (31), little angle signal detection system (32) and rotatable adjutage (33); Wherein: horizontal laser light colimated light system comprises aperture (21), optical filtering (22), polarizer (23) and condenser (16); Big angle signal detection system (31) comprises camera lens a (25), camera lens b (26) and big angle signal detector (27), camera lens a (25) is made up of one group of identical wide-aperture concave lens and convex lens with camera lens b (26), two back-to-back installations of camera lens; Camera lens a (25) can receive the scattered light in 0 ~ 60 ° of angular range, after forming directional light, is focused on the inductor of big angle signal detector (27) by camera lens b (26); Little angle signal detection system (32) comprises analyzer (28), screen (29) and little angle signal detecting device (30); Horizontal laser light colimated light system is installed on the side of the circular light hole (13) of the upper diameter 2mm of capillary rheometer (1) electric heating cover (8), is followed successively by aperture (21), optical filtering (22), polarizer (23) and condenser (16) from LASER Light Source (3) to circular light hole (13); Big angle signal detection system (31) and little angle signal detection system (32) are installed in the side of the conical light hole (14) on electric heating cover (8); Little angle signal detection system (32) is installed in laser incident direction, and when horizontal laser light colimated light system, circular light hole (13), conical light hole (14) and little angle signal detection system (32) use, place point-blank; Big angle signal detector (27) is one with the CCD detecting device of mechanical shutter; Big angle signal detection system (31) is installed on a rotatable adjutage (33), and rotatable adjutage (33) and laser incident direction angle are θ, and during operation, θ can adjust; Little angle detection system is formed primarily of analyzer (28), screen (29) and little angle signal detecting device (30);

Described LASER Light Source (3) both can produce laser also can produce micro-imaging light source.