CN206114539U - Experiment observation system based on bionical compound eye - Google Patents

Abstract

The utility model relates to an experiment observation system based on bionical compound eye, it includes: the microfluidic experimental device is connected with the upper computer; wherein the microfluidic experimental device comprises: the device comprises a processor module, a compound eye image acquisition device connected with the processor module, and a chip position for placing a rock slice test model; the compound eye image acquisition device is suitable for shooting image data of distribution and flow conditions of multiphase fluid in the rock slice test model; the utility model discloses a compound eye image acquisition device can be when light intensity weakens, and the distribution and the flow situation of heterogeneous fluid in the clear rock fragment test model of shooting obtain high-definition image data to in illumination intensity reinforcing, two image acquisition modules can also separately respectively independently gather image data.

Description

Experimental observation system based on bionic compound eye

Technical field

This utility model is related to a kind of experimental observation system based on bionic compound eye.

Background technology

In biology, insecticide has compound eye structural, by imitating Biological Principles, the compound eye structural of insecticide is applied to into sight Survey field, the observation of distribution and flow condition to the heterogeneous fluid in micro-fluidic field can play good observation effect.

Utility model content

The purpose of this utility model is to provide a kind of experimental observation system based on bionic compound eye, with by sliver The shooting pose adjustment of test model, the distribution and the not good technology of flow condition observation effect for overcoming conventional multiphase fluid is asked Topic.

In order to solve above-mentioned technical problem, this utility model provides a kind of experimental observation system based on bionic compound eye System, including：Micro-fluid experiment device, the host computer being connected with the micro-fluid experiment device；Wherein described micro-fluid experiment device Including：Processor module, the compound eye image harvester being connected with the processor module, the core for placing sliver test model Piece position, and the bottom of the chip position be additionally provided with by processor module control electric rotating machine；The processor module is suitable to The shooting attitude of sliver test model on chip position is adjusted by electric rotating machine；And the compound eye image harvester is suitable to clap Take the photograph the view data of the distribution of heterogeneous fluid and flow condition in sliver test model, and by the processor module by the figure As data is activation is to host computer.

Further, the periphery of the chip position is provided with half circular track, and the two ends of the half circular track are provided with rotating shaft, with suitable 180 degree is rotated in the top around sliver test model；The compound eye image harvester includes two image capture modules, and half The center of circular guideway is provided with light sensor；The processor module is suitable to measure sliver test mould according to light sensor The intensity of illumination of type, two image capture modules of control draw close in opposite directions along half circular track or independence and freedom is moved；Wherein work as illumination During strength reduction, processor module controls two image capture modules and draws close along half circular track move toward one another, to shrink ken model Enclose；When intensity of illumination strengthens, processor module controls two image capture modules and moves along half circular track independence and freedom, with only It is vertical to shoot.

Further, the sliver test model includes：Transparent chips, the transparent chips are provided with several and are arranged in order Be suitable to the recess of embedded corresponding imitative core wafer sample, and be sequentially connected by corresponding runner between each recess, wherein The inlet of the first recess is connected with into liquid pool, and the liquid outlet of last recess is connected with clean-up pit；Positioned at the upper end of transparent chips Face seal has transparent upper cover, and the lower surface of transparent chips is provided with diaphragm type light source oled layer.

Further, it is described enter liquid pool by be additionally provided with air inlet, and enter liquid pool and air inlet and the first recess inlet it Between be sequentially etched microbubble generation module, microbubble division module.

Further, the upper surface of the transparent upper cover is provided with heat power supply device, the lower surface of the diaphragm type light source oled layer It is provided with cold source device；And the inlet of each recess is higher than the liquid outlet of the recess.

Further, the heat power supply device and cold source device include some upper and lower symmetrically arranged semiconductor refrigeration sheets；It is described The hot junction of the semiconductor refrigeration sheet in heat power supply device is affixed on the upper end surface of the transparent upper cover directly over recess, the low-temperature receiver The cold end of the semiconductor refrigeration sheet of device is affixed at the lower surface of the diaphragm type light source oled layer immediately below recess；And institute The area coverage for stating semiconductor refrigeration sheet is less than recess area.

The beneficial effects of the utility model are that this utility model adjusts sliver test model on chip position by electric rotating machine Shooting attitude, make compound eye image harvester be obtained in that a more proper image, and the compound eye image for adopting Harvester can be when light intensity weakens, and two image capture modules are drawn close along half circular track move toward one another, is regarded with shrinking Domain scope, clearly to shoot the distribution of heterogeneous fluid and flow condition in sliver test model, obtains the view data of high-resolution, And when intensity of illumination strengthens, two image capture modules separately can also independently gather view data；And will clap The distribution of heterogeneous fluid and the view data of flow condition are uploaded to host computer in the sliver test model taken the photograph, and are easy to experimenter By host computer observed image data, and by host computer preservation, backup image data；The micro-fluid experiment device is easy to Distribution and flow condition to the heterogeneous fluids of many imitative core wafer samples, carries out omnibearing observation, and also can by according to The embedded accordingly imitative core wafer sample that is suitable to of secondary arrangement constitutes corresponding TCH test channel, and imitating core wafer sample can be according to imitative rock The density degree in microcosmic duct is accordingly sorted in heart thin slice sample, to constitute different test modes, and then meets various Type core wafer is tested, and clearly shoots corresponding microcosmic in imitative core wafer sample by omnibearing image collecting device The distribution of heterogeneous fluid and flow condition in duct, to carry out data analysiss to many imitative core wafer samples.

Description of the drawings

This utility model is further illustrated with reference to the accompanying drawings and examples.

Fig. 1 is the theory diagram of experimental observation system of the present utility model；

Fig. 2 is the structural representation of experimental observation system of the present utility model；

Fig. 3 is the side structure diagram of sliver test model of the present utility model；

Fig. 4 is the plan structure diagram of sliver test model of the present utility model；

Fig. 5 is the structural representation of guide rail travel mechanism of the present utility model.

In figure：

Sliver test model 1, transparent chips 100, imitative core wafer sample 101, runner 102, enter liquid pool 103, clean-up pit 104th, air inlet 105, microbubble generation module 106, microbubble division module 107；

Transparent upper cover 2；

Diaphragm type light source oled layer 3, single OLED light source 301；

Heat power supply device 41, cold source device 42, semiconductor refrigeration sheet 400；

Image capture module 5a, 5b, half circular track 51, rotating shaft 52, light sensor 53；

Chip position 6；

Slide block 7, roller 71, micro-driving motor 72.

Specific embodiment

This utility model is described in further detail presently in connection with accompanying drawing.These accompanying drawings are simplified schematic diagram, Basic structure of the present utility model is only illustrated in a schematic way, therefore it only shows the composition relevant with this utility model.

As shown in Figures 1 to 4, this utility model provides a kind of experimental observation system based on bionic compound eye, bag Include：Micro-fluid experiment device, the host computer being connected with the micro-fluid experiment device；Wherein described micro-fluid experiment device includes： Processor module, the compound eye image harvester being connected with the processor module, the chip position for placing sliver test model, And the bottom of the chip position is additionally provided with the electric rotating machine controlled by processor module；The processor module is suitable to by rotation The shooting attitude of sliver test model on rotating motor adjustment chip position, to reach more proper image, is easy to follow-up multiple Eye image collecting device preferably gathers respective image data；And the compound eye image harvester is suitable to shoot sliver test The view data of the distribution of heterogeneous fluid and flow condition in model, and sent the view data by the processor module To host computer.

Specifically, send with regard to view data to the mode of host computer and such as but not limited to pass through processor module with serial ports Mode send data to host computer, experimenter can check view data by host computer, and described image data also may be used To be preserved by host computer, be achieved, in order to analysis of experimental data.

Further, the periphery of the chip position 6 is provided with half circular track 51, and the two ends of the half circular track 51 are provided with rotating shaft 52, it is suitable for rotating 180 degree (as shown in the F1 of direction, from a side shifting of sliver test model around the top of sliver test model To opposite side)；The compound eye image harvester includes two image capture modules, and the center of half circular track is provided with light Dependent sensor；The processor module is suitable to measure the intensity of illumination of sliver test model according to light sensor, controls two figures As acquisition module is drawn close in opposite directions or independence and freedom is moved along half circular track；Wherein when intensity of illumination weakens, two images are controlled Acquisition module is drawn close along half circular track move toward one another, to shrink FOV (Field of View), improves image-capturing resolution；When intensity of illumination strengthens When, two image capture modules of control are moved along half circular track independence and freedom, with independent shooting.

Therefore, when light intensity weakens, being drawn close along half circular track move toward one another by two image capture modules can It is clear to shoot the distribution of heterogeneous fluid and flow condition in sliver test model, the view data of high-resolution is obtained, and in light When according to intensity enhancing, two image capture modules separately can also independently gather view data, not affect definition Meanwhile, expand the ken, can simultaneously shoot distribution and the flow condition of the heterogeneous fluid of two imitative core wafer samples.With regard to two figures As in the moving direction as Fig. 1 of acquisition module shown in direction F2 and F3.

Described image acquisition module drives its opposite or free movement by a guide rail travel mechanism.

The guide rail travel mechanism by processor module control, to adjust the direction of motion.

Specifically, the guide rail travel mechanism can be realized by prior art.

Fig. 5 shows a kind of optional embodiment of guide rail travel mechanism, and the guide rail travel mechanism includes：With semicircle The slide block 7 that guide rail coordinates, the upper surface still image acquisition module of the slide block 7, and be provided with inside slide block 7 and half circular track The roller 71 for rolling, and the roller 71 is coordinated to be rotated by micro-driving motor control, and micro-driving motor is fixed and slide block 7 Inwall, and the micro-driving motor by processor module by motor drive module control, also, half circular track outside Face is the flank of tooth, and the roller is to be suitable to the gear with the flank engagement.

Described image acquisition module such as but not limited to adopts ccd image sensor；The processor module is for example but not It is limited to using S3C2440A processors.

Specifically, the sliver test model includes：Transparent chips 100, the transparent chips 100 be provided with several according to The recess for being suitable to embedded corresponding imitative core wafer sample 101 of secondary arrangement, and between each recess by corresponding runner 102 successively It is connected, wherein the inlet in the first recess is connected with into liquid pool 103, the liquid outlet of last recess is connected with clean-up pit 104；Position Transparent upper cover 2 is sealed with the upper surface of transparent chips 100, and the lower surface of transparent chips 100 is provided with diaphragm type light source Oled layer 3, the diaphragm type light source oled layer 3 has some single OLED light sources 301 in array distribution.

In test, first each imitative core wafer sample is respectively put in respective recess, can be according to imitative core wafer sample The density degree in microcosmic duct is ranked up in this, test solution can from positioned at the imitative core wafer sample of the first recess according to The secondary imitative core wafer sample for flowing through remaining each recess；Meanwhile, diaphragm type light source oled layer is lighted, can be under appropriate brightness Observation the test solution distribution of heterogeneous fluid and flow condition in corresponding microcosmic duct in each imitative core wafer sample, also can be Foam flooding experiment is carried out in the case of the microcosmic duct saturation crude oil of imitative rock core structure.

Preferably, a length of 5 millimeters of the runner 102, width is 1 millimeter, and depth is 10 microns.

Further, it is described enter liquid pool 103 by be additionally provided with air inlet 105, and enter liquid pool 103 and air inlet 105 is recessed with first Microbubble generation module 106, microbubble division module 107 has been sequentially etched between the inlet in portion.

Specifically, from gas is injected from air inlet, while by certain density surfactant solution (test solution) From the imitative core wafer sample of the first inlet injection, gas-liquid two-phase is sent out in microbubble generation module and microbubble division module Raw cutting division produces microcosmic foam, is then injected in the microcosmic duct in imitative core wafer sample.

Optionally, it is described enter liquid pool 103, clean-up pit 104, air inlet 105 etch in transparent upper cover 2.

Optionally, the transparent chips adopt glass medium material, transparent upper cover to adopt quartz glass thin slice.

The upper surface of the transparent upper cover is provided with heat power supply device, and the lower surface of the diaphragm type light source oled layer is provided with low-temperature receiver Device；And the inlet of each recess is higher than the liquid outlet of the recess.

The heat power supply device and cold source device include some upper and lower symmetrically arranged semiconductor refrigeration sheets；The thermal source dress The hot junction of the semiconductor refrigeration sheet put is affixed on the upper end surface of the transparent upper cover directly over recess, the cold source device The cold end of semiconductor refrigeration sheet is affixed at the lower surface of the diaphragm type light source oled layer immediately below recess；And described partly lead The area coverage of body refrigerating sheet is less than recess area.

The host computer being related in embodiment can adopt PC, or industrial computer, with display module, to show corresponding figure As data.

With it is above-mentioned according to desirable embodiment of the present utility model as enlightenment, by above-mentioned description, related work people Member can carry out various change and modification in the range of without departing from this utility model technological thought completely.This reality The content being not limited to new technical scope in description, it is necessary to its technology is determined according to right Property scope.

Claims (5)

1. a kind of experimental observation system based on bionic compound eye, it is characterised in that include：Micro-fluid experiment device, with this The connected host computer of micro-fluid experiment device；Wherein

The micro-fluid experiment device includes：Processor module, the compound eye image harvester being connected with the processor module, use The electric rotating controlled by processor module is additionally provided with the chip position for placing sliver test model, and the bottom of the chip position Machine；

The processor module is suitable to adjust the shooting attitude of sliver test model on chip position by electric rotating machine；And

The compound eye image harvester is suitable to shoot the distribution of heterogeneous fluid and the image of flow condition in sliver test model Data, and the view data is sent to host computer by the processor module；

The periphery of the chip position is provided with half circular track, and the two ends of the half circular track are provided with rotating shaft, is suitable for being surveyed around sliver The top of die trial type rotates 180 degree；

The compound eye image harvester includes two image capture modules, and the center of half circular track is provided with light sensor Device；

The processor module is suitable to measure the intensity of illumination of sliver test model according to light sensor, controls two image acquisition Module is drawn close in opposite directions along half circular track or independence and freedom is moved；Wherein

When intensity of illumination weakens, the processor module controls two image capture modules and leans on along half circular track move toward one another Hold together, to shrink FOV (Field of View)；

When intensity of illumination strengthens, the processor module controls two image capture modules and transports along half circular track independence and freedom It is dynamic, with independent shooting.

2. experimental observation system according to claim 1, it is characterised in that

The sliver test model includes：Transparent chips, what the transparent chips were provided with that several are arranged in order is suitable to be embedded in The recess of corresponding imitative core wafer sample, and be sequentially connected by corresponding runner between each recess, wherein

It is connected with into liquid pool in the inlet of the first recess, the liquid outlet of last recess is connected with clean-up pit；

Transparent upper cover is sealed with positioned at the upper surface of transparent chips, and the lower surface of transparent chips is provided with diaphragm type light source OLED Layer.

3. experimental observation system according to claim 2, it is characterised in that it is described enter liquid pool by be additionally provided with air inlet, and Microbubble generation module, microbubble division module have been sequentially etched between the inlet for entering liquid pool and air inlet and the first recess.

4. experimental observation system according to claim 3, it is characterised in that the upper surface of the transparent upper cover is provided with thermal source Device, the lower surface of the diaphragm type light source oled layer is provided with cold source device；And

Liquid outlet of the inlet of each recess higher than the recess.

5. experimental observation system according to claim 4, it is characterised in that if the heat power supply device and cold source device include Do upper and lower symmetrically arranged semiconductor refrigeration sheet；

The hot junction of the semiconductor refrigeration sheet in the heat power supply device is affixed on the upper end surface of the transparent upper cover directly over recess, The cold end of the semiconductor refrigeration sheet of the cold source device is affixed on the lower surface of the diaphragm type light source oled layer immediately below recess Place；And

The area coverage of the semiconductor refrigeration sheet is less than recess area.