CN204740203U - Embedded micro - high spectrum camera system of light microscopic continues - Google Patents

Abstract

The utility model provides an embedded micro - high spectrum camera system of light microscopic continues, includes a box, then a light microscopic module and a high spectrum camera module. This box have one go into light mouthful intercommunication box inside, and have a first fitting portion in the box. Then light microscopic module setting is in this box for supply an image light beam to pass through, and its optical axis is to going into the light mouth. This high spectrum camera pair of module then the light microscopic module the optical axis and set up in this box, a spectral data and an image data are obtained according to the image light beam of receiving to high spectrum camera module, just high spectrum camera module has a second fitting portion and a joint portion. This high this second fitting portion of spectrum camera module accessible and this first fitting portion gomphosis to be applied to microcosmic detecting system, or combine on a support through this joint portion, in order to be applied to huge sight detecting system.

Description

The micro-EO-1 hyperion camera chain of the embedded light microscopic that continues

Technical field

The utility model system is relevant with spectral photography system; Refer to the micro-EO-1 hyperion camera chain of a kind of embedded light microscopic that continues especially.

Background technology

EO-1 hyperion camera chain incorporates two kinds of systems such as spectral analysis and image analysing computer, and the mode that can can't harm obtains spectroscopic data and the image data of object to be measured, then performs qualitative and quantitative analysis by above-mentioned data.

Wherein, the detection technique of EO-1 hyperion camera chain has been widely used among the fields such as Food Science, medical science and biology, such as: agricultural product can be helped to carry out checking on of quality and classification; Whether the outward appearance detecting agricultural product is damaged; Detect agricultural product and whether have residues of pesticides; Detect sugariness of agricultural product etc.Or, the micro organism quantity on meat surface can be detected, to analyze the aerobic plate count of meat.

In macroscopic detection system, be located on an adjustment support by an EO-1 hyperion camera frame, an object disposing platform of arranging in pairs or groups, wherein this object disposing platform is placed with a undetected object.When for utilizing EO-1 hyperion camera to absorb the spectrum image of this undetected object, by such as driving the mode of this adjustment support or this object disposing platform movement with step motor, realize the relative movement of this adjustment support and this object disposing platform, meaning namely, realize the relative movement between this EO-1 hyperion camera and this undetected object, with banded or wire scans and absorbs spectrum and the image data at each position of this determinand.

In addition, in microcosmic detection system, due to for detect determinand size very small, such as with in microscopic examination eucaryotic cell structure, its size is nearly all below micron order or even nanoscale, no matter be that the mode not moving determinand with mobile EO-1 hyperion camera performs band shape or wire scanning, or perform band shape or wire scanning in the mode not moving EO-1 hyperion camera and mobile determinand, in moving the least limit of its displacement with CD-ROM drive motor control EO-1 hyperion camera or determinand, and cause the relative movements of generation excessive, cause image capture incomplete, the problem of image distortion etc.Specifically, in time using the object lens of oily mirror, determinand immerses in pine and cypress oil, especially cannot with the machine-processed capture of relative movement.

Therefore, in prior art, especially between the image output end of the micro-imaging of EO-1 hyperion camera and determinand, set up a lens fine-tuning, thus, only must by the position of this lens fine-tuning of adjustment, just can realize the relative movement of the micro-imaging of EO-1 hyperion camera and determinand, impel EO-1 hyperion camera to be captured spectrum, the image at each position of determinand a step by a step.

But, between known EO-1 hyperion camera and lens fine-tuning and microscope, normally link together in directly fixing mode, and this little modular construction is quite meticulous, and the relative position of each other close lie in assembling or dismounting time, all need contraposition highly accurately.Therefore, when user uses for the EO-1 hyperion camera in the middle of microcosmic detection system and macroscopic detection system is exchanged or replaced; Or time in microcosmic detection system for replacing different EO-1 hyperion camera (cameras as different size, different frequency range), in the assembling/dismounting of the EO-1 hyperion camera of microcosmic detection system, its handling required by precision high, and have assembling inconvenience problem.

Utility model content

The purpose of this utility model is to provide a kind of embedded light microscopic that continues micro-EO-1 hyperion camera chain, when its EO-1 hyperion camera is replaced and is used between macroscopic detection system and microcosmic detection system, and simple and convenient assembly.

For achieving the above object, the micro-EO-1 hyperion camera chain of the embedded light microscopic that continues that the utility model provides, be selectively be arranged in a casing or be arranged on a support, this support moves relative to a determinand; Wherein, this casing has one first fitting portion; The micro-EO-1 hyperion camera chain of this embedded light microscopic that continues comprises: one continues light microscopic module and an EO-1 hyperion camera model.This light microscopic module that continues is passed through with for an image strip; This EO-1 hyperion camera model is located at this and is continued on the optical axis of light microscopic module, in order to receive this image strip by this light microscopic module that continues, and obtaining a spectroscopic data and an image data according to the image strip received, this EO-1 hyperion camera model has one second fitting portion and a joint portion; Wherein, this EO-1 hyperion camera model is chimeric with the first fitting portion of this casing and be positioned at this casing in detachable mode by this second fitting portion, or is connected with this support by the mode that this joint portion is detachable.

Wherein, this EO-1 hyperion camera model also includes a location-plate and an EO-1 hyperion camera; This location-plate has this second fitting portion and this joint portion; This EO-1 hyperion camera is connected with this location-plate, and this EO-1 hyperion camera receives this image strip, and this image strip is converted to this spectroscopic data and this image data.

The micro-EO-1 hyperion camera chain of the embedded light microscopic that continues that the utility model provides, also includes a casing, and to continue light microscopic module and an EO-1 hyperion camera model.This casing comprises side plate, and this side plate has a light inlet and is communicated with this box house, and has one first fitting portion in this casing; This continues light microscopic module installation in this casing, and this light microscopic module that continues is passed through for an image strip, and this continues, the optical axis of light microscopic module is to should light inlet; This EO-1 hyperion camera model is arranged in this casing to the optical axis of the light microscopic module that should continue, and this EO-1 hyperion camera model obtains a spectroscopic data and an image data according to the image strip received, and this EO-1 hyperion camera model has one second fitting portion; Wherein, this EO-1 hyperion camera model is connected with this first fitting portion in detachable mode by this second fitting portion.

Wherein, this EO-1 hyperion camera model includes a joint portion; This EO-1 hyperion camera model is connected with this first fitting portion by this second fitting portion or is connected with a support in detachable mode by this joint portion, and wherein this support is for driving this EO-1 hyperion camera model to move relative to a determinand.

Wherein, this EO-1 hyperion camera model also includes a location-plate and an EO-1 hyperion camera; This location-plate has this second fitting portion and this joint portion; This EO-1 hyperion camera is connected with this location-plate, and this EO-1 hyperion camera receives this image strip, and this image strip is converted to this spectroscopic data and this image data.

Wherein, this casing also includes a upper cover, and this upper cover has a block; When entire of this upper cover, this block is butted on this EO-1 hyperion camera model.

Wherein, this casing includes two projections and forms this first fitting portion; This EO-1 hyperion camera model includes two grooves and forms this second fitting portion; The quantity of the block of this upper cover is two; When entire of this upper cover, this two block is butted on this EO-1 hyperion camera model, and this two block and this two groove in the same plane.

Wherein, this casing also includes a base and an adjustment plate, and this base is connected with this side plate and this upper cover; This adjustment plate is arranged in a movable manner on this base, and this adjustment plate has this first fitting portion.

Effect of the present utility model is, EO-1 hyperion camera model can be arranged at according to user demand in casing or on support, and is applicable in microcosmic detection system or macroscopic detection system, and has simple and convenient assembly and pinpoint double effects.

Accompanying drawing explanation

Fig. 1 is the stereographic map of the micro-EO-1 hyperion camera chain of the embedded light microscopic that continues of the utility model one preferred embodiment.

Fig. 2 is the partial exploded view of Fig. 1.

Fig. 3 is partial sectional view, and display is when entire of upper cover, and projection embeds in groove, and block is pressed against on location-plate.

Fig. 4 is the schematic diagram that the micro-EO-1 hyperion camera chain of the embedded light microscopic that continues of the utility model is applied to microcosmic detection system.

Fig. 5 is the schematic diagram that the utility model EO-1 hyperion camera model is applied to macroscopic detection system.

Symbol description in accompanying drawing

The micro-EO-1 hyperion camera chain of the 100 embedded light microscopic that continues, 10 casings, 11 bases, 11a screw, 12 side plates, 12a light inlet, 14 upper covers, 14a block, 16 dividing plates, 16a printing opacity mouth, 18 adjustment plates, 18a projection, 18b elongated slot, 20 continue light microscopic module, 22 CD-ROM drive motor, 24 continue light microscopic, 30 EO-1 hyperion camera models, 32 location-plates, 32a groove, 32b screw, 34 EO-1 hyperion cameras, 34a slit, 200 optical microscopes, 300 lens mounts, 400 supports, 500 monitor stations, 600 determinands.

Embodiment

For can the utility model be illustrated more clearly in, lifts preferred embodiment and coordinate accompanying drawing to be described in detail as follows.

Referring to shown in Fig. 1 to Fig. 2, is the micro-EO-1 hyperion camera chain 100 of the embedded light microscopic that continues of the utility model one preferred embodiment, includes a casing 10, and to continue light microscopic module 20 and an EO-1 hyperion camera model 30.

This casing 10 includes a base 11, two-phase symmetrically arranged side plate 12, upper cover 14, dividing plate 16 and an adjustment plate 18.This two side plate is connected to the both sides of this base 11, and wherein this side plate 12 has a light inlet 12a to be communicated with this casing 10 inner.This upper cover 14 is articulated in this base one ora terminalis, and has two block 14a inside this upper cover 14.This dividing plate 16 to be arranged on this base and between this two side plate 12, and its to have a printing opacity mouth 16a relative with this light inlet 12a.This adjustment plate 18 has two projection 18a, and this two projection 18a forms one first fitting portion, and this adjustment plate 18 is corresponding screw 11a locked on this base 11 after being each passed through its three elongated slot 18b with three screw (not shown).This light microscopic module 20 that continues is arranged on this base 11, and this dividing plate 16 and there is this light inlet 12a side plate 12 between.This light microscopic module 20 that continues includes a CD-ROM drive motor 22 and and to continue light microscopic 24.This CD-ROM drive motor 22 is connected with this light microscopic 24 that continues, in order to drive this light microscopic 24 that continues in radial or axial movement.This light microscopic 24 that continues passes through for an image strip, and its optical axis is to should light inlet 12a.

This EO-1 hyperion camera model 30 includes location-plate 32 and an EO-1 hyperion camera 34.This location-plate 32 has two groove 32a and a joint portion.In the present embodiment, this two groove 32a forms one second fitting portion; This joint portion is that a plurality of screw 32b being formed at this location-plate 32 end face, those screws 32b are used for locking for the clasp such as screw or bolt.This EO-1 hyperion camera 34 is installed on this location-plate 32, and this EO-1 hyperion camera 34 has a slit 34a, in order to receive outside image strip.

This EO-1 hyperion camera model 30 is arranged in this casing 10 corresponding to the optical axis of this light microscopic module 20 that continues and the optical axis of this light inlet 12a.In the locator meams of this EO-1 hyperion camera model 30 of rear explanation, please coordinate shown in Fig. 3, when the location of EO-1 hyperion camera model 30, respectively in alignment with after respectively this projection 18a of this adjustment plate 18 by this two groove 32a of this EO-1 hyperion camera model 30, EO-1 hyperion camera model 30 is put down gently in this casing 10, this two projection 18a is chimeric this two groove 32a respectively, can complete EO-1 hyperion camera model 30 in the location of horizontal direction.And when this upper cover 14 entire, two block 14a of upper cover 14 will be pressed against the side of this location-plate 32, and this two blocks 14a and this two groove 32a is in the same plane, to complete this EO-1 hyperion camera model 30 in the location of vertical direction.And after EO-1 hyperion camera model 30 completes location in casing 10, the slit 34a system of EO-1 hyperion camera 34 is right against this printing opacity mouth 16a.Thus, by above-mentioned easy mode, EO-1 hyperion camera model 30 can be reached and the effect of the accurate contraposition of the light microscopic 24 that continues.

Please coordinate shown in Fig. 4, when this is embedded continue the micro-EO-1 hyperion camera chain 100 of light microscopic to be applied to microcosmic detection system and need be connected with optical microscope 200 time, the micro-EO-1 hyperion camera chain 100 of this embedded light microscopic that continues is connected with this optical microscope 200 by a lens mounts 300 with its light inlet 12a.And from the image strip that this optical microscope 200 produces, will sequentially by this lens mounts 300, this light inlet 12a, this is after light microscopic 24 and this printing opacity mouth 16a, slit 34a via this EO-1 hyperion camera model 30 received, and by this EO-1 hyperion camera 34, this image strip is converted to spectroscopic data and image data.

Because EO-1 hyperion camera model 30 of the present utility model is arranged in casing 10 in Embedded mode, therefore, when EO-1 hyperion camera model 30 uses for being converted to macroscopic detection system, only the upper cover 14 of casing 10 need be opened, after this EO-1 hyperion camera model 30 is directly taken out, can substitute and use to macroscopic detection system.Please refer to shown in Fig. 5, EO-1 hyperion camera model 30 is connected on the support 400 of macroscopic detection system in detachable mode by its joint portion.Such as: to pass from support 400 rear with securing member (not shown) and lock in this screw 32b, so that EO-1 hyperion camera model 30 is fixed on support 400.Wherein, this support can drive this EO-1 hyperion camera model 30 relative to the determinand 600 be placed on monitor station 500 carries out the movement of vertical direction or horizontal direction, to obtain spectrum and the image data of this determinand 600.

By above-mentioned design, the EO-1 hyperion camera model 30 of the micro-EO-1 hyperion camera chain 100 of the embedded light microscopic that continues of the present utility model can according to user demand, selectively be arranged in this casing 10, with continue light microscopic module 20 with the use of and the detection system of microcosmic can be applicable to; Or be arranged on support 400, and the detection system of macroscopic can be applicable to.Particularly, in the detection system of microcosmic, the demand precision in its assembling is low, handling means are simple, and has the double effects of simple and convenient assembly and precision positioning concurrently.

In addition, when using the demand of multiple different frequency range EO-1 hyperion camera if necessary, also only can use a casing 10, the EO-1 hyperion camera of arranging in pairs or groups different respectively uses, and has a tractor serves several purposes, cost-effective effect.

In addition, if during the projection distance of the slit 34a that need adjust EO-1 hyperion camera model 30 with the light microscopic 24 that continues, due to this adjustment plate 18 be each passed through its three elongated slot 18b by three screw (not shown) after the corresponding screw 11a locked on this base 11, and those elongated slots 18b is the design adopting long strip type, therefore still possess a little can before and after adjustment nargin exist, in other words, this adjustment plate 18 adopts moveable mode to be arranged on base 11, therefore, during for adjustment projection distance, the screw of fixed adjustment plate 18 is only needed to unclamp, after adjustment before and after the direction of elongated slot 18b, the front and back focusing stroke of part can be used to drive its projection distance.

The foregoing is only the better possible embodiments of the utility model, wherein, in the groove of location-plate and the projection of adjustment plate, also can be replaced into the technological means that other combine with embedded mode equably.In addition, this EO-1 hyperion camera model 30, in response to different user demand, in the detection system of macroscopic, also can be installed on the support as equipment such as aircraft, mechanical arm, camera bellows, and not be limited with above-described embodiment.Such as the equivalence that application the utility model instructions and claim are done changes, and ought to be included in the scope of the claims of the present utility model.

Claims (8)

1. the micro-EO-1 hyperion camera chain of the embedded light microscopic that continues, be selectively arranged in a casing or be arranged on a support, this support moves relative to a determinand;

It is characterized in that, this casing has one first fitting portion; The micro-EO-1 hyperion camera chain of this embedded light microscopic that continues comprises:

One continues light microscopic module, passes through with for an image strip; And

One EO-1 hyperion camera model, being located at this continues on the optical axis of light microscopic module, in order to receive this image strip by this light microscopic module that continues, and obtain a spectroscopic data and an image data according to the image strip received, this EO-1 hyperion camera model has one second fitting portion and a joint portion;

Wherein, this EO-1 hyperion camera model is chimeric with the first fitting portion of this casing and be positioned at this casing in detachable mode by this second fitting portion, or is connected with this support in detachable mode by this joint portion.

2. the micro-EO-1 hyperion camera chain of the embedded light microscopic that continues according to claim 1, is characterized in that, this EO-1 hyperion camera model includes a location-plate and an EO-1 hyperion camera; This location-plate has this second fitting portion and this joint portion; This EO-1 hyperion camera is connected with this location-plate, and this EO-1 hyperion camera receives this image strip, and this image strip is converted to this spectroscopic data and this image data.

3. the micro-EO-1 hyperion camera chain of the embedded light microscopic that continues, is characterized in that, comprising:

One casing, comprises side plate, and this side plate has a light inlet and is communicated with this box house, and has one first fitting portion in this casing;

One continues light microscopic module, is arranged in this casing, and this light microscopic module that continues is passed through for an image strip, and this continues, the optical axis of light microscopic module is to should light inlet; And

One EO-1 hyperion camera model, is arranged in this casing to the optical axis of the light microscopic module that should continue, and this EO-1 hyperion camera model obtains a spectroscopic data and an image data according to the image strip received, and this EO-1 hyperion camera model has one second fitting portion; Wherein, this EO-1 hyperion camera model system is connected with this first fitting portion in detachable mode by this second fitting portion.

4. the micro-EO-1 hyperion camera chain of the embedded light microscopic that continues according to claim 3, it is characterized in that, this EO-1 hyperion camera model includes a joint portion; This EO-1 hyperion camera model is connected with this first fitting portion by this second fitting portion or is connected with a support in detachable mode by this joint portion, and wherein this support moves relative to a determinand for driving this EO-1 hyperion camera model.

5. the micro-EO-1 hyperion camera chain of the embedded light microscopic that continues according to claim 4, is characterized in that, this EO-1 hyperion camera model includes a location-plate and an EO-1 hyperion camera; This location-plate has this second fitting portion and this joint portion; This EO-1 hyperion camera is connected with this location-plate, and this EO-1 hyperion camera receives this image strip, and this image strip is converted to this spectroscopic data and this image data.

6. the micro-EO-1 hyperion camera chain of the embedded light microscopic that continues according to claim 3, it is characterized in that, this casing includes a upper cover, and this upper cover has a block; When entire of this upper cover, this block is butted on this EO-1 hyperion camera model.

7. the micro-EO-1 hyperion camera chain of the embedded light microscopic that continues according to claim 6, is characterized in that, this casing includes two projections and forms this first fitting portion; This EO-1 hyperion camera model includes two grooves and forms this second fitting portion; The quantity of the block of this upper cover is two; When entire of this upper cover, this two block is butted on this EO-1 hyperion camera model, and this two block and this two groove in the same plane.

8. the micro-EO-1 hyperion camera chain of the embedded light microscopic that continues according to claim 6, is characterized in that, this casing includes a base and an adjustment plate, and this base is connected with this side plate and this upper cover; This adjustment plate is arranged on this base in a movable manner, and this adjustment plate has this first fitting portion.