CN105158789B - A kind of spatial discrimination radiant flux detecting devices - Google Patents

Abstract

The invention provides a kind of spatial discrimination radiant flux detecting devices, described detecting devices includes apeture lens component, camera, limit borescopic imaging plate, limit orifice plate and flat response X-ray detector F XRD；Black chamber inlet sends visible ray, lens are imaged onto to it on limit borescopic imaging plate, after the position relationship of visible ray picture for determining the limit hole and inlet, the X-ray that black chamber inlet is sent passes through pin hole, only partial x-ray is by limit borescopic imaging plate and the limit hole for limiting orifice plate, the sensitive face for reaching flat response X-ray detector F XRD causes response, this partial x-ray can flow the radiant flux corresponding to inlet internal zone dividing domain, with time limit borescopic imaging plate record inlet by pin hole institute into actinogram and limit hole between position relationship, realize spatial discrimination radiant flux detection.The present invention can realize that Stimulated Light does not play the extra X-ray influence produced at black chamber inlet edge, with broad prospect of application while having the time and space to differentiate ground X-ray radiation stream quantitative detection.

Description

A kind of spatial discrimination radiant flux detecting devices

Technical field

The invention belongs to X-ray detection field, and in particular to a kind of spatial discrimination radiant flux detecting devices.

Background technology

Laser energy can be converted into nearly Planck grenz ray by the black chamber of Laser Driven, and in driving inertial confinement indirectly It is commonly used in fusion ICF.This X-ray energy measured is enough to derive radiation temperature, radiation temperature be Hohlraum radiation source most One of important parameter, is also to explore laser and the basis of black chamber interaction physics process.But black intracavitary portion specific region （Non- hot spot, hot spot or pellet）The spatial-resolved detection of X-ray radiation stream is not yet to solve in indirect driving ICF experiments and very Important the problem of.

And existing diagnostic device has following deficiency：1st, because general black chamber inlet internal diameter is small, about, existing diagnosis is set The effect a diameter of millimeter magnitude of test surface is had, the X-ray that facular area, non-spot area and pellet region are sent is all while quilt These diagnostic tools are detected.Another aspect laser beat inlet edge produce X-ray be still largely mingled in it is above-mentioned In the field of view of receiver of detector.The 2nd, although X-ray framing camera, streak camera can be to X-rays, empty evolution diagnose, But they are all difficult to quantitatively measure X-ray radiation stream.And soft X-ray multi-channel energy spectrometer（Dante）, cvd diamond detector Although can measure the absolute magnitude of radiant flux with flat response X-ray detector F-XRD, these diagnostic tools are again without sky Between differentiate.

The content of the invention

In order to overcome the shortcomings of that diagnostic device can not be while carry out time-space resolution radiant flux quantitative detection, originally in the prior art Invention provides a kind of spatial discrimination radiant flux detecting devices.

The spatial discrimination radiant flux detecting devices of the present invention, is characterized in, described equipment includes camera and in light path On the apeture lens component, limit borescopic imaging plate, limit orifice plate, the flat response X-ray detector F-XRD that are arranged in order.Described pin hole Lens subassembly includes pinhole plate and lens ring, and described pinhole plate is nested in the middle part of lens ring.Described limit borescopic imaging plate It is pasted onto on limit orifice plate.Pin hole center on the pinhole plate, limit borescopic imaging Ban Xiankong centers, the Xian Kong centers for limiting orifice plate with Flat response X-ray detector F-XRD sensitive face center is on same light path straight line.Black chamber is placed in before apeture lens component Side.An angle is provided between camera sight and light path straight line, camera is used to monitor in real time on limit borescopic imaging plate by annular Lens are to position relationship between visible ray picture formed by black chamber inlet and limit hole.

Black chamber inlet sends visible ray, through on annular lens imaging in apeture lens component to limit borescopic imaging plate, it is determined that Limit borescopic imaging plate limit hole and the position relationship of the visible ray picture of black chamber.The X-ray that black chamber inlet is sent passes through apeture lens group In part after pin hole, X-ray reaches flat response X-ray detector F-XRD by the limit hole of limit borescopic imaging plate and the limit hole of limit orifice plate Sensitive face, cause flat response X-ray detector F-XRD respond, X-ray energy stream by limit hole correspond to black chamber inlet in part The radiant flux in region, records black chamber inlet by the way that pin hole institute is into actinogram in apeture lens component, so with time limit borescopic imaging plate Realize the radiation flow measurement of spatial discrimination.

Described lens ring primary optical axis is perpendicular to described pinhole plate.

Angular range between described camera sight and light path straight line is 20 ° ~ 40 °.

Pin hole center on described pinhole plate and lens ring primary optical axis distance are hundred micron dimensions and its following.

The pinhole diameter of described pinhole plate is less than or equal to hundred micron dimensions.

Described pinhole plate is tantalum piece of the thickness between 20um ~ 100um.

Object distance, the image distance of described lens ring imaging are identical with object distance, the image distance difference of pinhole plate pin-hole imaging.

The limit hole of described limit borescopic imaging plate is identical with the limit hole size of described limit orifice plate.

The limit hole of described limit borescopic imaging plate is more than the device space through theoretical calculation with the limit bore dia of limit orifice plate and differentiated The product of rate and the pin-hole imaging multiplication factor of apeture lens component, and less than the black chamber inlet size and apeture lens group The product of the pin-hole imaging multiplication factor of part, while less than flat response X-ray detector F-XRD sensitive face size.

Described limit orifice plate thickness is the tantalum piece of 20um ~ 100um magnitudes.

Described flat response X-ray detector F-XRD uses the time of being based on, by absolute calibration, in photon energy range 0.1 ~ 4KeV flat response X-ray detectors.

Described black chamber is the conventional black chamber in driving inertial confinement fusion indirectly.

Described ring-lens material uses K9 glass.

Present invention has the advantages that：

1. the present invention can be realized differentiates ground X-ray radiation stream quantitative detection with the time and space.

2. the spatial discrimination of the present invention reaches 100um magnitudes and its following.

3. Stimulated Light does not play the extra X-ray produced at inlet edge influence for detection of the present invention on X-ray, with wide Wealthy application prospect.

Brief description of the drawings

Fig. 1 is spatial discrimination radiant flux detecting devices light channel structure schematic diagram of the invention；

Fig. 2 is the apeture lens modular construction schematic diagram in the spatial discrimination radiant flux detecting devices of the present invention；

The visible images that camera is gathered during Fig. 3 aims at for the spatial discrimination radiant flux detecting devices of the present invention；

Fig. 4 limits the X of borescopic imaging plate record for the spatial discrimination radiant flux detecting devices of the present invention during Targeting Light image；

In figure, the camera 5. of 1. 3 apeture lens component of black 2. adjustable diaphragm of chamber 4. limit borescopic imaging plate 6. limits orifice plate 7. the pinhole plate of 10. lens ring of flat response X-ray detector F-XRD 8. oscillograph, 9. computers 11..

Embodiment

The present invention is described in detail with specific embodiment below in conjunction with the accompanying drawings.

Embodiment 1

Fig. 1 is the spatial discrimination radiant flux detecting devices light channel structure schematic diagram of the present invention, and Fig. 2 is space point of the invention Distinguish the apeture lens modular construction schematic diagram in radiant flux detecting devices, in Fig. 1, Fig. 2, spatial discrimination radiant flux of the invention Detecting devices, including camera 4, the apeture lens component 3 being arranged in order in light path, limit borescopic imaging plate 5, limit orifice plate 6, flat sound Answer X-ray detector F-XRD 7.Described apeture lens component 3 includes pinhole plate 11 and lens ring 10, described pinhole plate 11 are nested in the middle part of lens ring 10.Described limit borescopic imaging plate 5 is pasted onto on limit orifice plate 6.Pin hole on the pinhole plate 11 Center, the Xian Kong centers of limit borescopic imaging plate 5, the Xian Kong centers for limiting orifice plate 6 and flat response X-ray detector F-XRD 7 it is sensitive Face center is on same light path straight line.Black chamber 1 is placed in the front of apeture lens component 3.The sight of camera 4 and light path straight line it Between have an angle, camera 4 is used to monitor in real time on limit borescopic imaging plate 5 from lens ring to formed by the black inlet of chamber 1 Position relationship between light image and limit hole.

The black inlet of chamber 1 sends visible ray, through annular lens imaging is to limiting on borescopic imaging plate 5 in apeture lens component 3, really Fixed limit borescopic imaging plate 5 limits hole and the position relationship of the visible ray picture of black chamber 1.The X-ray that the black inlet of chamber 1 is sent is saturating through pin hole In mirror assembly 3 after pin hole, X-ray reaches flat response X-ray detection by the limit hole of limit borescopic imaging plate 5 and the limit hole of limit orifice plate 6 Device F-XRD 7 sensitive face, causes flat response X-ray detector F-XRD to respond, and X-ray energy stream corresponds to the black note of chamber 1 by limiting hole The subregional radiant flux of inlet internal, records the black inlet of chamber 1 with time limit borescopic imaging plate 5 and passes through pin hole in apeture lens component 3 Institute is achieved in that the radiation flow measurement of spatial discrimination into actinogram.

Described lens ring primary optical axis is perpendicular to described pinhole plate 11.

Angle between the described sight of camera 4 and light path straight line is 20 °.

Pin hole center on described pinhole plate 11 and the primary optical axis distance of lens ring 10 are in hundred micron dimensions and its following.

The pinhole diameter of described pinhole plate 11 is 100um.

Described pinhole plate 11 is the tantalum piece that thickness is 100um.

Object distance, the image distance of the described imaging of lens ring 10 are identical with object distance, the image distance difference of the pin-hole imaging of pinhole plate 11.

The limit hole of described limit borescopic imaging plate 5 is identical with the limit hole size of described limit orifice plate 6.

The limit hole of described limit borescopic imaging plate 5 is 2mm with the limit bore dia for limiting orifice plate 6.

Described limit orifice plate 6 is the tantalum piece that thickness is 100um.

Described flat response X-ray detector F-XRD 7 is using the time of being based on, by absolute calibration, in photon energy model Enclose 0.1 ~ 4KeV flat response X-ray detectors.

Described black chamber 1 is the conventional black chamber in driving inertial confinement fusion indirectly.

Described ring-lens material uses K9 glass.

During the spatial discrimination radiant flux detecting devices work of the present invention, flat response X-ray detector F-XRD 7 and oscillograph 8 connections, oscillograph 8 is connected with computer 9.

Adjustable diaphragm 2 in the present invention, the pin hole center of apeture lens component 3, the Xian Kong centers of limit borescopic imaging plate 5 limit hole The Xian Kong centers of plate 6 and flat response X-ray detector F-XRD 7 sensitive face center are point-blank.Apeture lens component 3 In pinhole diameter be 100um.For carrying out X-ray imaging to the black inlet of chamber 1, this actinogram is by being that 2mm limits hole with diameter D Limit orifice plate 6 carry and the condition of the black inlet picture of chamber 1 of two-dimensional observation be provided.Limit orifice plate 6 also serves as imaging surface, is one piece Tantalum piece thick 100um.Also have diameter 2mm sizes limit hole limit borescopic imaging plate 5 be close to limit orifice plate 6 on, it be able to record that by The actinogram and this actinogram of the inlet of black chamber 1 that pin hole is formed and the position relationship in limit hole.Flat response X-ray detector F-XRD 7 is one and is based on the time, by absolute calibration, in photon energy range 0.1 ~ 4KeV flat response X-ray detectors, it Behind limit orifice plate 6.Therefore, the X-ray that only the black inlet of chamber 1 of specific part sprays passes through pin hole, limit borescopic imaging plate 5 and limit Orifice plate 6, is collided with the sensitive faces of flat response X-ray detector F-XRD 7.With 7 pairs of collisions of flat response X-ray detector F-XRD Response, the voltage signal recorded by oscillograph 8 is output in computer 9.These X-ray parts being detected only with black chamber The X-ray that specific diameter d is sent by 0.2mm regions in 1 is corresponding.So spatial discrimination radiant flux detecting devices is aimed at Region set in advance in one black chamber 1, spatial discrimination radiant flux detection can just be realized.

Apeture lens component 3 is the core component of spatial discrimination radiant flux detecting devices, diameter=100um pin holes be On 100um thickness tantalum pieces pinhole plate 11, as shown in Fig. 2 the pinhole plate is nested in the middle part of lens ring.What lens ring 10 was imaged puts Big multiple and object distance are identical with the difference of pin-hole imaging.This just make lens ring 10 to the black inlet of chamber 1 institute into visible ray picture with Pin hole is to the black inlet of chamber 1 institute into actinogram, and position is identical with size.Therefore, the black inlet of chamber 1 is illuminated when with visible ray, profit With the position relationship of camera 4 in real time between monitoring limit hole and the imaging of lens ring 10, lens ring 10 can just realize reality When auxiliary aim at.An adjustable diaphragm 2 is provided with before apeture lens component 3, for protecting lens, prevents X-ray from passing through Lens cause signal to disturb.As a result, as having been carried out 10 times of amplifications, the pin hole determined by pinhole diameter and multiplication factor into The spatial resolution of picture is computed being 0.11mm.Therefore utilization space resolving radiation stream detecting devices goes detection to come from 0.2mm diameters The feasibility of the X-ray radiation stream in region is also proved.

It is assumed thatIt is the X of specific 0.2mm diameter regions in black chamber that spatial discrimination radiant flux detecting devices is detected Ray radiant flux.Through the pin hole of pinhole plate 11, the X-ray energy detected by equipment is met: ,It is the solid angle of the pin hole of pinhole plate 11,It is the pinhole diameter of pinhole plate 11,It is the pin of black chamber and pinhole plate 11 The distance between hole, takes 205mm here.It is assumed that the voltage signal recorded by oscillograph 8 is, Wo Menyou, it is signal attenuation multiple,It is flat response X-ray detector F-XRD 7 average response coefficient, It is the resistance of oscillograph 8.Therefore, according to the principle and voltage signal values of spatial discrimination radiant flux detecting devices, so that it may To obtain radiant flux.

The visible images that camera is gathered during Fig. 3 aims at for the spatial discrimination radiant flux detecting devices of the present invention, Fig. 4 limits the x-ray image of borescopic imaging plate record for the spatial discrimination radiant flux detecting devices of the present invention during Targeting.Figure Small black circle in 3 in big black circle is that the speck in aiming area under visible light, Fig. 4 is laser hits point in black chamber inlet Facular area, black circle is the aiming under X-ray and search coverage.The present invention is achieved in God Light III prototype laser devices successfully should With in the present embodiment, the black chamber of selection is diameter 1.2mm, long 2.4mm, inlet 0.85mm golden chamber.The frequency multiplication of eight beam 3, 800J/1.5ns laser, injects black chamber with 45 ° from black chamber inlet two ends respectively.First, black chamber inlet is illuminated by visible light, Aimed at by the auxiliary space resolving radiation stream detecting devices of lens ring 10, aim at result, as shown in Figure 3.Then carry out Laser target shooting, oscillograph 8 recorded effective voltage signal, and combine above theory deduction by computer 9, and processing is taken aim at The radiant flux exact value in quasi- region.Actual detection region of the equipment in black chamber has also been recorded with time limit borescopic imaging plate 5, has such as been schemed Shown in 4.

Embodiment 2

The present embodiment is identical with the structure of embodiment 1, except that the described sight of camera 4 and light path straight line it Between angle be 40 °, the pinhole diameter of described pinhole plate is 80um, and described pinhole plate is the tantalum piece that thickness is 20um, institute The limit hole of the limit borescopic imaging plate 5 stated and the limit bore dia of limit orifice plate 6 are 3mm, described limit orifice plate 6 be thickness be 20um tantalum Piece.

One of ordinary skill in the art will be appreciated that embodiment described here is to aid in reader and understands this hair Bright principle, it should be understood that protection scope of the present invention is not limited to such especially statement and embodiment.This area Those of ordinary skill can make according to these technical inspirations disclosed by the invention various does not depart from the other each of essence of the invention Plant specific deformation and combine, these deformations and combination are still within the scope of the present invention.

Claims (10)

1. a kind of spatial discrimination radiant flux detecting devices, it is characterised in that described equipment includes camera（4）With in light path The apeture lens component being arranged in order（3）, limit borescopic imaging plate（5）, limit orifice plate（6）, flat response X-ray detector F-XRD（7）； Described apeture lens component（3）Including pinhole plate（11）And lens ring（10）, described pinhole plate（11）It is nested in annular Lens（10）Middle part；Described limit borescopic imaging plate（5）It is pasted onto limit orifice plate（6）On；The pinhole plate（11）On pin hole in The heart, limit borescopic imaging plate（5）Xian Kong centers, limit orifice plate（6）Xian Kong centers and flat response X-ray detector F-XRD（7）Spirit Min Mian centers are on same light path straight line；Black chamber（1）It is placed in apeture lens component（3）Front；Camera（4）Sight and light An angle, camera are provided between the straight line of road（4）For monitoring limit borescopic imaging plate in real time（5）On by lens ring（10）To black Chamber（1）Position relationship between visible ray picture formed by inlet and limit hole；

Black chamber（1）Inlet sends visible ray, through apeture lens component（3）Middle annular lens imaging to limit borescopic imaging plate（5）On, It is determined that limit borescopic imaging plate（5）Limit hole and black chamber（1）Visible ray picture position relationship；Black chamber（1）The X-ray that inlet is sent is worn Needle passing hole lens subassembly（3）After middle pin hole, X-ray is by limit borescopic imaging plate（5）Limit hole and limit orifice plate（6）Limit hole, reach Flat response X-ray detector F-XRD（7）Sensitive face, cause flat response X-ray detector F-XRD（7）Response, X-ray energy stream Correspond to black chamber by limiting hole（1）The radiant flux in inlet internal zone dividing domain, with time limit borescopic imaging plate（5）Record black chamber（1）Injection Mouth passes through apeture lens component（3）Middle pin hole institute is into actinogram.

2. spatial discrimination radiant flux detecting devices according to claim 1, it is characterised in that described lens ring（10） Primary optical axis is perpendicular to described pinhole plate（11）.

3. spatial discrimination radiant flux detecting devices according to claim 1, it is characterised in that described camera（4）Depending on Angular range between line and light path straight line is 20 ° ~ 40 °.

4. spatial discrimination radiant flux detecting devices according to claim 1, it is characterised in that described pinhole plate（11）On Pin hole center and lens ring（10）Primary optical axis distance is hundred micron dimensions and its following.

5. spatial discrimination radiant flux detecting devices according to claim 1, it is characterised in that described pinhole plate（11）'s Pinhole diameter is less than or equal to hundred micron dimensions.

6. spatial discrimination radiant flux detecting devices according to claim 1, it is characterised in that described pinhole plate（11）For Tantalum piece of the thickness between 20um ~ 100um；Described limit orifice plate（6）For the tantalum piece that thickness is 20um ~ 100um magnitudes.

7. spatial discrimination radiant flux detecting devices according to claim 1, it is characterised in that described lens ring（10） Object distance, image distance and the pinhole plate of imaging（11）Object distance, the image distance difference of pin-hole imaging are identical.

8. spatial discrimination radiant flux detecting devices according to claim 1, it is characterised in that described limit borescopic imaging plate （5）Limit hole and described limit orifice plate（6）Limit hole size it is identical.

9. spatial discrimination radiant flux detecting devices according to claim 1, it is characterised in that described limit borescopic imaging plate （5）Limit hole with limit orifice plate（6）Limit bore dia be more than device space resolution ratio through theoretical calculation and apeture lens component（3） Pin-hole imaging multiplication factor product, and less than the black chamber（1）Inlet size and apeture lens component（1）Pin hole into As the product of multiplication factor, while less than flat response X-ray detector F-XRD（7）Sensitive face size.

10. spatial discrimination radiant flux detecting devices according to claim 1, it is characterised in that described flat response X-ray Detector F-XRD（7）Using based on the time, by absolute calibration, in photon energy range 0.1 ~ 4KeV flat response X-ray detections Device.