CN204514477U - The thermal coupling structure of super long alignment detector and single-point low-temperature receiver - Google Patents
The thermal coupling structure of super long alignment detector and single-point low-temperature receiver Download PDFInfo
- Publication number
- CN204514477U CN204514477U CN201520186779.0U CN201520186779U CN204514477U CN 204514477 U CN204514477 U CN 204514477U CN 201520186779 U CN201520186779 U CN 201520186779U CN 204514477 U CN204514477 U CN 204514477U
- Authority
- CN
- China
- Prior art keywords
- low temperature
- low
- temperature
- super long
- long alignment
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Expired - Fee Related
Links
Landscapes
- Photometry And Measurement Of Optical Pulse Characteristics (AREA)
Abstract
This patent discloses the high-temperature homogeneity coupled structure of a kind of super long alignment detector and single-point low-temperature receiver, it is primarily of super long alignment infrared eye, heat insulating mattress, the low temperature thermosphere of assisting three layers of overlaying structure of fixing base, hollow cone support column, " tree-shaped " low temperature flexibility cold chain, " dentation " occlusion structure and single-point low-temperature receiver composition." tree-shaped " low temperature flexibility cold chain and three stackedly adds the equalizing temperature method that Structures at Low Temperature thermosphere combines and evenly guides on super long alignment infrared eye by cold for single-point former cold, obtain high temperature homogeneity, eliminate simultaneously low-temperature receiver be connected with super long alignment infrared eye after three-dimensional shrinkage in temperature-fall period; This patent adopts bridge-type mechanical support structure to have good environmental suitability; This patent structure is simple, easy to operate, maintainability and interchangeability good, be equally applicable to the thermal coupling occasion of other super large cold platform and single-point low-temperature receiver.
Description
Technical field
This patent relates to super long alignment infrared eye encapsulation technology, the thermal coupling structure of a kind of super long alignment detector of concrete finger and single-point low-temperature receiver, it is applicable to the Dewar encapsulation of super long alignment infrared focus plane detector chip, is equally applicable to the thermal coupling occasion of other super large cold platform and single-point low-temperature receiver.
Background technology
High spatial resolution infrared remote sensing instrument is the core component of infrared YX, search, tracker.The method improving spatial resolution generally has two kinds, and one is the photoelectric properties improving infrared eye, improves detection sensitivity, to obtain more information; Two is increase infrared-sensitive unit quantity, and namely at the remote sensing instrument of phase co-altitude, identical swath, responsive unit is more, and its spatial discrimination is higher.Thus super long alignment (>=6000 yuan) infrared focus plane assembly technology of preparing is at space flight, aviation infrared regime important in inhibiting.Along with wavelength is to long wave expansion and the raising of detection sensitivity, super long alignment infrared focus plane detector could must work under profound hypothermia.Due to mechanical refrigeration there is compact conformation, the advantage such as volume is little, lightweight, refrigerating capacity is large, cooling time is short, cryogenic temperature controlled range is large, such detector mostly adopts mechanical refrigeration mode in the application of space at present.Mostly adopt Dewar to encapsulate when so also making it apply and form super long alignment infrared focus plane Dewar component.
Traditional small-scale infrared detector dewar assembly, due to alignment or planar array detector scale smaller, the stem stem of separated type Dewar or the interior pipe of integrated form Dewar are the mechanical support of detector and the low temperature platform carrier of detector.Because detector is only a module and small-sized, the temperature homogeneity of detector is easy to control at ± 0.5K.Low temperature platform and supporting construction are generally cantilever design, cold platform small-sized, and the stress produced due to difference between cold platform and detector expansion coefficient is also less to the performance impact of detector.The such as package assembly of Chinese patent 200810334312 large area array infrared detector on cold platform and assemble method thereof, its low-temperature receiver is the cold head of separated type Dewar.Embodiment is encapsulation 320 × 240 battle arrays, and detector full-size is about 9.6mm × 7.2mm.Its detector is glued on jewel substrate.Jewel substrate is glued on stem stem cold head, and the temperature homogeneity of detector is easy to control at ± 0.5K.The wire structures and attaching method thereof of Chinese patent CN2008100334308 long line series infrared detector dewar assembly in addition, the wire structures of its multiple submodule outer leads of mainly setting forth and merge outbound course.It is not set forth the temperature homogeneity between 2000 yuan of each submodules of detector, and its single-point low-temperature receiver is similarly the support of detector.The length of cold platform is about about 61mm.Along with the development of super long alignment (>=6000 yuan) infrared focus plane assembly, the size of detector reaches >=180mm after, cannot using single-point low-temperature receiver simply as mechanical support, the affect problem of temperature homogeneity on detector performance of the upper each submodule of cold platform (>=180mm) just seems more outstanding, must explore a kind of new method and solve this problem.
Summary of the invention
The object of this patent is to provide the high-temperature homogeneity coupled structure of a kind of super long alignment detector and single-point low-temperature receiver, solves the high-temperature homogeneity of oversize and the problem of mechanical support in the Dewar encapsulation of spliced super long alignment infrared detector chip.
As shown in Figure 1, it comprises super long alignment infrared eye 1, heat insulating mattress 2, auxiliary fixing base 3, hollow cone support column 4, tree-shaped low temperature flexibility cold chain 5, low temperature thermosphere 6 and single-point low-temperature receiver 7 for a kind of super long alignment detector of this patent and the thermal coupling structure of single-point low-temperature receiver.
Long line series infrared detector 1 is spliced on splicing substrate 102 by multiple chip submodule 101, splicing substrate 102 is made up of the kovar of low bulk or invar, each chip submodule 101 is glued on the boss 103 of splicing substrate 102 relevant position, evenly have through hole 104 in splicing substrate 102 surrounding, have the screw 105 of some at splicing substrate 102 middle section.
Heat insulating mattress 2 selects TC4 or zirconia material, and it is a cylindrical sheet, the thick 0.1-0.2mm of Thickness Ratio low temperature thermosphere 6 thickness.
Auxiliary fixing base 3 as shown in Figure 2, for rectangle platy structure, select thermal conductivity low and the little TC4 material of proportion, zone line has the reserved screw 301 of rectangular distribution, have rectangular opening 302 structure and heat insulation mounting structure 304 in the reserved screw 301 of rectangular distribution, there is support mounting hole 303 at two ends.Centre position rectangular opening 302 size 1-2mm less of low temperature thermosphere 6 length and width size.Rectangular opening 302 is outer is heat insulation mounting structure 304, and the fixed frame size 0.2mm-0.4mm less of low temperature thermosphere 6 length and width size of heat insulation mounting structure 304, the width of fixed frame selects 1mm-1.5mm, and clearance groove width is 0.5mm-1.5mm.The width of dowel structure is 1-2mm.
Hollow cone support column 4 selects TC4 material, and shape is hollow cone, and cone wall thickness is 0.2-0.4mm, and cone comparatively small end has installation screw 401 structure.
" tree-shaped " structure that " tree-shaped " low temperature flexibility cold chain 5 exports for single-point input multiple spot, it selects oxygen-free copper or pure aluminum material, and each branch road is hollow multi-disc " S type " cold chain 501 structure, and every sheet thickness is 0.15-0.25mm, and between two panels, gap is 0.3-0.5mm." tree-shaped " low temperature flexibility cold chain 5 one end is low-temperature receiver installation end 502, and one end is the fixed block 503 distributed at regular intervals having multiple branch road in addition, and each fixed block 503 has fixed block hole 504." tree-shaped " low temperature flexibility cold chain 5 has destressing ditch 505 structure in the middle of Width, and destressing ditch 505 runs through " S type " cold chain 501 and fixed block 503.
Low temperature thermosphere 6 short transverse is three layers of overlaying structure, middle layer select the argent of high heat conductance or metallic copper or sapphire layer and, the indium metal that upper strata and lower floor select 0.1-0.3mm thickness quality softer, the size of upper strata in Length x Width direction is the same with the middle layer size of low temperature thermosphere 6, and the size of lower floor in Length x Width direction is the same with each fixed block 503 size of " tree-shaped " soft type cold chain 5.Low temperature thermosphere 6 three is stacked adds structural thickness 0.1-0.2mm thicker in the thickness of heat insulating mattress 2.As shown in Figure 4, length direction adopts multi-disc arrangement " dentation occlusion " structure of " Z " font in the middle of the "L" shaped of two ends.On low temperature thermosphere 6, relevant position is provided with mounting hole 601.
The thermal coupling structure of super long alignment detector 1 and single-point low-temperature receiver 7 as shown in Figure 1, the heat insulation mounting structure 304 of auxiliary fixing base 3 is low temperature thermosphere 6.On auxiliary fixing base 3, the surrounding of low temperature thermosphere 6 is placed with the heat insulating mattress 2 of rectangular distribution.Low temperature thermosphere 6 and heat insulating mattress 2 are super long alignment detector 1, and on super long alignment detector 1, the unthreaded hole 104 of rectangular distribution aligns with the reserved screw 301 of the rectangular distribution on the pad circular hole 201 of each heat insulating mattress 2 and auxiliary fixing base 3 and installs.Be " tree-shaped " low temperature flexibility cold chain 5 below low temperature thermosphere 6, each fixed block 503 of " tree-shaped " low temperature flexibility cold chain 5 is fixed with low temperature thermosphere 6 through each rectangular opening 302 of auxiliary fixing base 3.In support mounting hole 303 position of auxiliary fixing base 3 both sides, circular cone support column 4 is installed.Fix with single-point low-temperature receiver 7 below the low-temperature receiver installation end 502 of " tree-shaped " low temperature flexibility cold chain 5.
The performing step of this patent is as follows:
(1) be inverted by super long alignment infrared eye 1, low temperature thermosphere 6 is fixed on the reserved installation screw 105 of the splicing substrate 102 of super long alignment infrared eye 1 by the screw reserving installation hole 601 run through on low temperature thermosphere 6 of 18 stainless steels;
(2) submodule 101 of super long alignment infrared eye 1 is upwards placed.The screw of TC4 material runs through the through hole 104 and heat insulating mattress 2 that super long alignment infrared eye 1 surrounding homogeneity opens, and is fixed on by super long alignment infrared eye 1 on the reserved screw 301 of auxiliary fixing base 3.Realize fixing the circumference of low temperature thermosphere 6 by the heat insulation mounting structure 304 of auxiliary fixing base 3 simultaneously.Heat insulation mounting structure 304 can increase the heat transfer resistance between low temperature thermosphere 6 and auxiliary fixing base 3, reduces conductive heat leakage, then carries out polishing and gold-plated process to auxiliary fixing base 3 surface and leak heat to reduce its radiation;
(3) the auxiliary fixing base 3 with super long alignment infrared eye 1 is inverted, the screw of 18 stainless steels step 1 installed is pulled down successively, six cold quantity transmissions fixed block 503 along separate routes of " tree-shaped " low temperature flexibility cold chain 5 is allowed to run through rectangular opening 302 on auxiliary fixing base 3, the fixed block hole 504 of six fixed blocks 503 of " tree-shaped " low temperature flexibility cold chain 5 is realized again with stainless steel screw, mounting hole 601 on low temperature thermosphere 6 is connected with the screw 105 on the splicing substrate 2 having super long alignment infrared eye 1, such realization " tree-shaped " low temperature flexibility cold chain 5 is coupled with the Low Temperature Thermal of super long alignment infrared eye 1,
(4) use Titanium Alloy Screw to run through the preformed hole 301 at auxiliary fixing base 3 two ends, the installation realizing the reserved screw 401 of auxiliary fixing base 3 two ends and hollow cone support column 4 is fixed;
(5) hollow cone support column 4 is fixed by mounting platform belonging to stainless steel screw and single-point low-temperature receiver 7, realize the bridge-type mechanical support of super long alignment infrared eye 1 like this, finally by stainless steel screw, the low-temperature receiver installation end 502 of " tree-shaped " low temperature flexibility cold chain 5 and single-point low-temperature receiver 7 are installed fixing.
The thermal design principle of this patent structure is as follows:
(1) this patent is each chip submodule 101 be transferred to by the cold uniform high-efficiency of single-point low-temperature receiver 7 on super long alignment infrared eye 1, requires that coupling post-mounting structure ensures that in the temperature variation interval of 65K-350K each chip submodule 101 performance on super long alignment infrared eye 1 is normal simultaneously.
(2) in the super long alignment detector 1 thermal coupling structure with single-point low-temperature receiver 7, auxiliary fixing base 3 forms bridge-type mechanics mounting structure with the hollow cone support column 4 of both sides.In order to the cold reducing single-point low-temperature receiver 7 dissipates, auxiliary fixing base 3 and the hollow cone support column 4 of both sides all adopt the titanium alloy material of low heat conductivity, hollow cone support column 4 adopts hollow and thin-walled conical structure to reduce bridge-type mechanics mounting structure thermal conductivity further simultaneously, makes bridge-type mechanics mounting structure have good heat-blocking action.Polishing can be carried out and gold-plated process leaks heat to reduce radiation to the hollow cone support column 4 of auxiliary fixing base 3 and both sides.
(3) heat transfer structure be made up of the splicing substrate 102 of " tree-shaped " low temperature flexibility cold chain 5, low temperature thermosphere 6 and super long alignment infrared eye 1, makes single-point low-temperature receiver 7 cold uniform high-efficiency be transferred to each chip submodule 101 on super long alignment infrared eye 1.For make distance low-temperature receiver installation end 502 different distance each fixed block 503 between homogeneous temperature, need according to cold quantity transmission requirement at each branch road of " tree-shaped " low temperature flexibility cold chain 5, design different " S type " cold chain 501 structures and sheet number makes each fixed block 503 equalizing temperature.Under " S type " cold chain 501 structure and destressing ditch 505 structure act on simultaneously, " tree-shaped " low temperature flexibility cold chain 5 can be made to possess certain flexibility, and the three-dimensional shrinkage that this flexibility can be used to produce in refrigeration cool-down process after elimination single-point low-temperature receiver 7 splices substrate 102 thermal coupling with super long alignment infrared eye 1 is on the impact of each chip submodule 101 on super long alignment infrared eye 1.Polishing and gold-plated process can be carried out to " tree-shaped " low temperature flexibility cold chain 5 and leak heat to reduce radiation.
(4) super long alignment detector 1 is with the thermal coupling structure of single-point low-temperature receiver 7, and low temperature thermosphere 6 is thermal barrier that the second homogenisation of each branch's fixed block 503 temperature of " tree-shaped " low temperature flexibility cold chain 5 and super long alignment infrared eye 1 splice substrate 102 and each fixed block 503 installation position of " tree-shaped " low temperature flexibility cold chain 5 and non-mounting position equalizing temperature.Good temperature homogeneity is obtained for making super long alignment infrared eye 1, by " L word " type and " Z-shaped " type splicing construction, every block low temperature thermosphere 6 all obtains the cold from two " tree-shaped " low temperature flexibility cold chain 5 fixed block 504 transmission, thus overcome the thermograde between " tree-shaped " low temperature flexibility cold chain 5 fixed block 504 by low temperature thermosphere 6, realize temperature second homogenisation.Each chip submodule 101 on super long alignment infrared eye 1 is finally made to obtain good temperature homogeneity.
More than complete the super long alignment detector of this patent and the high-temperature homogeneity thermal coupling structure of single-point low-temperature receiver; This patent has the following advantages and is:
1) structure is simple, easy to operate, maintainability and interchangeability good;
2) single-point low-temperature receiver is evenly guided on super large cold platform by the scheme combined by " tree-shaped " low temperature flexibility cold chain and low temperature thermosphere.Obtain ± temperature homogeneity that 0.5K is high, by intermediate ends multi-disc " S " the type structure of " tree-shaped " low temperature flexibility cold chain provide certain flexibility eliminate low-temperature receiver be connected with super long alignment infrared eye after three-dimensional shrinkage in temperature-fall period;
3) have 2 destressing ditches in the middle of the Width at " tree-shaped " low temperature flexibility cold chain to eliminate " tree-shaped " low temperature flexibility cold chains and to install the chip submodule 101 of super long alignment infrared eye 1 at Width mount stress at Width, reduce mounting structure to the impact of detector performance;
4) the two substrates spiro connection structure of auxiliary fixing base and super long alignment infrared eye splicing substrate is adopted, guarantee that super long alignment infrared eye only bears one dimension constraint at low temperatures, avoid the extra-stress of bridge-type supporting construction at mechanics and temperature-fall period, avoid encapsulating structure on the impact of detector performance;
5) adopt bridge-type mechanical support structure, detector assembly has good mechanical environment adaptability;
Accompanying drawing explanation
The thermal coupling structure of Fig. 1 super long alignment detector and single-point low-temperature receiver and implementation method schematic diagram;
In figure: 1-super long alignment detector;
101-chip submodule;
102-splicing substrate;
103-boss;
104-unthreaded hole;
105-screw;
2-heat insulating mattress;
201-pad circular hole;
3-auxiliary fixing base;
301-reserved screw;
302-rectangular opening;
303-support mounting hole;
304-heat insulation mounting structure;
4-hollow cone support column;
401-installation screw;
5-" tree-shaped " low temperature flexibility cold chains;
501-" S type " cold chains;
502-low-temperature receiver installation end;
503-fixed block;
504-fixed block hole;
505-destressing groove;
6-low temperature thermosphere;
601-mounting hole;
7-single-point low-temperature receiver;
Fig. 2 is auxiliary fixing base 3 local structural graph.
Fig. 3 is " tree-shaped " low temperature flexibility cold chain structural drawing.
Fig. 4 is the structural drawing of low temperature thermosphere 6.
Embodiment
Be described in further detail in the embodiment of embodiment to this patent below in conjunction with accompanying drawing:
The present embodiment is the high-temperature homogeneity coupling process of super long alignment 8000 yuan of detectors and single-point low-temperature receiver, and as shown in Figure 1, its main implementation method is as follows:
1) the super long alignment infrared eye 1 of 16 512 element chip submodules 101 also level of being inverted there is is to be placed on tooling platform splicing on splicing substrate 102 boss 103, chip submodule 101 is faced down, splicing substrate 102 material therefor is that Lo-Ex can cut down, and physical dimension is 280 × 26 × 8mm.Note each chip submodule 101 safety during installation, avoid touching.Argent is selected in low temperature thermosphere 6 middle layer, silver strip sizes of substrate is 100 × 70 × 0.8mm, first silver strip substrate is carried out to the high-temperature annealing process of 800 DEG C, silver strip substrate is made to obtain softer ground, 2 "L" shaped as shown in Figure 4 and 3 " Z " font silver strips are processed again by laser cutting parameter, and the silver strip after cutting is polished and cleaned, obtain the middle layer silver strip prepared.The upper and lower two-layer metal indium sheet of low temperature thermosphere 6 three layers of overlaying structure is formed by cut, indium sheet sizes of substrate 120 × 90 × 0.1mm, upper strata indium sheet is the same with the middle silver layer size of low temperature thermosphere in the size of long Width, and lower floor is the same with six fixed blocks 503 of " tree-shaped " soft type cold chain 5 in the size of long Width.According to structure shown in Fig. 4, upper and lower 2 layers of indium sheet are clipped middle layer silver strip and be combined into low temperature thermosphere 6, and be placed on splicing substrate 102, use tweezers to adjust mounting hole 601 on each low temperature thermosphere 6 to aim at each screw 105 on splicing substrate 102, using the stainless steel screw of M2 × 5mm to be pre-fixed by each low temperature thermosphere 6 splices on substrate 102 at super long alignment infrared eye 1, when pre-fixing, screw does not tighten, and avoids extruding stressed to low temperature thermosphere 6.
2) auxiliary fixing base 3 is lain in a horizontal plane on operator's console, assisting base plate 3 uses titanium alloy TC 4 material, be of a size of 360 × 65 × 10mm, six rectangular openings 302 and the heat insulation mounting structure 304 of auxiliary fixing base 3 is processed as shown in Figure 2 by wire cutting technology, fixed frame width and gap width are 1mm, fixed frame housing size 0.3mm less of low temperature thermosphere 6 length and width size, fixed frame dowel width 1mm.Totally 20 TC4 heat insulating mattress 2 be evenly placed on each preformed hole 301 of auxiliary fixing base 3 rectangular distribution, heat insulating mattress 2 is of a size of φ 3.5 × 0.9mm, and pad circular hole 201 is φ 2.2mm.Tweezers are used to be aimed at each preformed hole 301 by each heat insulating mattress 2 Upper gasket circular hole 201.The super long alignment infrared eye 1 being preinstalled with low temperature thermosphere 6 is placed on the heat insulating mattress 2 on auxiliary fixing base 3, make each unthreaded hole 104 on super long alignment infrared eye 1 aim at the heat insulating mattress 2 Upper gasket circular hole 201 of adjusted position during placement, use the Titanium Alloy Screw of M2 × 10mm to run through unthreaded hole 104 and pad circular hole 201 on splicing substrate 102 and fix with reserved screw 301 on auxiliary fixing base 3.Time fixing, use torque screwdrivers that 3 Newton force are set and evenly tighten 20 M2 × 10mm Titanium Alloy Screws, the splicing substrate 102 of super long alignment infrared eye 1, heat insulating mattress 2 and auxiliary fixing base 3 are closely fixed, and low temperature thermosphere 6 is fixed by heat insulation mounting structure 304 pressing on the splicing substrate 102 of super long alignment infrared eye 1 and auxiliary fixing base 3 in each M2 × 10mm Titanium Alloy Screw fixation procedure.Low temperature thermosphere 6 thickness be made up of 2 0.1mm indium sheet and 1 0.8mm silver strip is 1mm, and heat insulating mattress thickness is 0.9mm, is installed the decrement that can produce 0.1mm to low temperature thermosphere 6 thickness direction by extruding.
3) also level of being inverted by the auxiliary fixing base 3 being fixed with super long alignment infrared eye 1 is placed on tooling platform, chip submodule 101 is faced down, notes chip submodule 101 safety during operation, avoid touching.18 screws super long alignment infrared eye 1 being pre-installed low temperature thermosphere 6 are all removed.Six fixed blocks 503 of " tree-shaped " low temperature flexibility cold chain 5 being run through six rectangular openings 302 on auxiliary fixing base 3 is placed in the indium sheet of low temperature thermosphere 6, " tree-shaped " low temperature flexibility cold chain 5 selects oxygenless copper material, it is symmetrical structure in this patent, six fixed block 503 spacings are 45mm, and low-temperature receiver installation end and fixed block 503 are apart from being 89mm." tree-shaped " low temperature flexibility cold chain 5, by wire cutting technology, is processed into multi-disc " S type " structure 501 having six cold quantity transmission branch roads as shown in Figure 3.Each branch road comprises multi-disc " S type " cold chain 501 structure of hollow, and every sheet thickness is 0.25mm, is spaced apart 0.3mm." tree-shaped " low temperature cold chain 5 by wire cutting technology, has the destressing ditch 505 that two 0.3mm are wide in the middle of Width, and destressing ditch 505 only runs through six branch road fixed blocks 503 and " S type " cold chain 501.Each fixed block hole 504 on each fixed block 503 is made to aim at mounting hole 601 on low temperature thermosphere 6 during installation, M2 × 6mm stainless steel screw is used will " tree-shaped " low temperature flexibility cold chain 5 to fasten each branch road fixed block 503 and low temperature thermosphere 6 and splicing on substrate 102, tighten in process, use torque screwdrivers that 3 Newton force are set and carry out tightening action, guarantee that each fixed block 503 evenly tightens.
4) two hollow cone support columns 4 are separately fixed at auxiliary fixing base 3 two ends, hollow cone support column 4 uses titanium alloy TC 4 material, wall thickness 0.25mm, is highly 65mm.M3 × 6mm Titanium Alloy Screw is used by auxiliary fixing base 3 supporting on mounting hole 303 and hollow cone support column 4, installation screw 401 to fasten.Auxiliary fixing base 3 with " tree-shaped " low temperature flexibility cold chain 5 and super long alignment infrared eye 1 is fixed on the loading end belonging to single-point low-temperature receiver 7 by hollow cone support column 4, realizes the bridge-type mechanical support of super long alignment infrared eye 1.Finally the low-temperature receiver installation end 502 of tree-shaped low temperature flexibility cold chain 5 is coupled fixing with single-point low-temperature receiver 7.
Below the high-temperature homogeneity coupling process of super long alignment detector and single-point low-temperature receiver is just completed.
Claims (4)
1. the thermal coupling structure of super long alignment detector and single-point low-temperature receiver, it comprises super long alignment infrared eye (1), heat insulating mattress (2), auxiliary fixing base (3), hollow cone support column (4), tree-shaped low temperature flexibility cold chain (5), low temperature thermosphere (6) and single-point low-temperature receiver (7); It is characterized in that:
Described super long alignment detector and the thermal coupling structure of single-point low-temperature receiver are: the heat insulation mounting structure (304) of auxiliary fixing base (3) is upper is low temperature thermosphere (6), on auxiliary fixing base (3), there is heat insulating mattress (2) in the surrounding of low temperature thermosphere (6); Low temperature thermosphere (6) and heat insulating mattress (2) are above super long alignment detector (1); Low temperature thermosphere (6) below is " tree-shaped " low temperature flexibility cold chain (5), and each fixed block (503) of " tree-shaped " low temperature flexibility cold chain (5) is fixed with low temperature thermosphere (6) through each rectangular opening (302) of auxiliary fixing base (3); In auxiliary fixing base (3) both sides, circular cone support column (4) is installed; " tree-shaped " low temperature flexibility cold chain (5) below is fixed with single-point low-temperature receiver (7).
2. the thermal coupling structure of super long alignment detector according to claim 1 and single-point low-temperature receiver, it is characterized in that: described auxiliary fixing base (3) selects thermal conductivity low and the little TC4 material of proportion, auxiliary fixing base (3) has the heat insulation mounting structure (304) increasing structure thermal resistance, and there is hollow cone support column (4) mounting structure at auxiliary fixing base (3) two ends.
3. the thermal coupling structure of super long alignment detector according to claim 1 and single-point low-temperature receiver, it is characterized in that: described " tree-shaped " low temperature flexibility cold chain (5) selects oxygen-free copper or pure aluminum material, each branch road is hollow multi-disc " S type " cold chain (501) structure, every sheet thickness is 0.15-0.25mm, between two panels, gap is 0.3-0.5mm, in the middle of the Width of " tree-shaped " low temperature flexibility cold chain (5), have destressing ditch (505) structure.
4. the thermal coupling structure of super long alignment detector according to claim 1 and single-point low-temperature receiver, it is characterized in that: described low temperature thermosphere (6) short transverse is three layers of overlaying structure, argent, metallic copper or sapphire high thermal conductivity material are selected in middle layer, and upper strata and lower floor select the indium metal on softer ground; Low temperature thermosphere (6) adopts multi-disc arrangement " dentation occlusion " structure of " Z " font in the middle of the "L" shaped of two ends.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201520186779.0U CN204514477U (en) | 2015-01-21 | 2015-03-31 | The thermal coupling structure of super long alignment detector and single-point low-temperature receiver |
Applications Claiming Priority (3)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201520041381 | 2015-01-21 | ||
| CN2015200413818 | 2015-01-21 | ||
| CN201520186779.0U CN204514477U (en) | 2015-01-21 | 2015-03-31 | The thermal coupling structure of super long alignment detector and single-point low-temperature receiver |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CN204514477U true CN204514477U (en) | 2015-07-29 |
Family
ID=53588882
Family Applications (2)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CN201510169308.3A Expired - Fee Related CN104748859B (en) | 2015-01-21 | 2015-03-31 | The thermal coupling structure and implementation method of super long alignment detector and single-point low-temperature receiver |
| CN201520186779.0U Expired - Fee Related CN204514477U (en) | 2015-01-21 | 2015-03-31 | The thermal coupling structure of super long alignment detector and single-point low-temperature receiver |
Family Applications Before (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CN201510169308.3A Expired - Fee Related CN104748859B (en) | 2015-01-21 | 2015-03-31 | The thermal coupling structure and implementation method of super long alignment detector and single-point low-temperature receiver |
Country Status (1)
| Country | Link |
|---|---|
| CN (2) | CN104748859B (en) |
Cited By (2)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN104748859A (en) * | 2015-01-21 | 2015-07-01 | 中国科学院上海技术物理研究所 | Thermal coupling structure and realization method for ultra-long line array detector and single-point cold source |
| CN113763844A (en) * | 2021-08-31 | 2021-12-07 | 上海卫星工程研究所 | Red flag mark for Mars detection and mounting method |
Families Citing this family (4)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN109405382B (en) * | 2018-09-29 | 2020-11-10 | 北京空间机电研究所 | Anti-impact vibration-reduction heat dissipation system suitable for satellite-borne gas bearing refrigerator |
| CN109974864A (en) * | 2019-03-11 | 2019-07-05 | 中国科学院上海技术物理研究所 | Three-dimension flexible board structure for the splicing of GaAs base large area array infrared focus plane |
| CN111710749B (en) * | 2020-04-23 | 2022-09-09 | 中国科学院上海技术物理研究所 | Long-line detector splicing structure based on multi-substrate secondary splicing and implementation method |
| CN112414560A (en) * | 2020-10-12 | 2021-02-26 | 中国电子科技集团公司第十一研究所 | Cold head supporting structure |
Family Cites Families (8)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| JPH06235657A (en) * | 1992-12-15 | 1994-08-23 | Nikon Corp | Infrared ray detector |
| JPH06221915A (en) * | 1993-01-21 | 1994-08-12 | Nikon Corp | Infrared detector |
| CN2711723Y (en) * | 2004-06-22 | 2005-07-20 | 中国科学院上海技术物理研究所 | Low temperature composite Dewar |
| CN2718568Y (en) * | 2004-06-22 | 2005-08-17 | 中国科学院上海技术物理研究所 | Dewar with micro-refrigerator |
| CN101226925B (en) * | 2008-02-01 | 2011-02-16 | 中国科学院上海技术物理研究所 | Wiring structure of long line series infrared detector dewar assembly and connecting method thereof |
| CN102820308B (en) * | 2012-08-03 | 2015-03-25 | 中国科学院上海技术物理研究所 | Dual-waveband linear infrared focal plane detector integrated structure |
| CN103344061B (en) * | 2013-06-21 | 2015-03-25 | 中国科学院上海技术物理研究所 | Coupling structure between linear type pulse tube refrigerator and infrared device and manufacturing method for same |
| CN104748859B (en) * | 2015-01-21 | 2017-09-26 | 中国科学院上海技术物理研究所 | The thermal coupling structure and implementation method of super long alignment detector and single-point low-temperature receiver |
-
2015
- 2015-03-31 CN CN201510169308.3A patent/CN104748859B/en not_active Expired - Fee Related
- 2015-03-31 CN CN201520186779.0U patent/CN204514477U/en not_active Expired - Fee Related
Cited By (3)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN104748859A (en) * | 2015-01-21 | 2015-07-01 | 中国科学院上海技术物理研究所 | Thermal coupling structure and realization method for ultra-long line array detector and single-point cold source |
| CN104748859B (en) * | 2015-01-21 | 2017-09-26 | 中国科学院上海技术物理研究所 | The thermal coupling structure and implementation method of super long alignment detector and single-point low-temperature receiver |
| CN113763844A (en) * | 2021-08-31 | 2021-12-07 | 上海卫星工程研究所 | Red flag mark for Mars detection and mounting method |
Also Published As
| Publication number | Publication date |
|---|---|
| CN104748859B (en) | 2017-09-26 |
| CN104748859A (en) | 2015-07-01 |
Similar Documents
| Publication | Publication Date | Title |
|---|---|---|
| CN204514477U (en) | The thermal coupling structure of super long alignment detector and single-point low-temperature receiver | |
| JP5942699B2 (en) | Magnetic resonance signal detection module | |
| CN109974864A (en) | Three-dimension flexible board structure for the splicing of GaAs base large area array infrared focus plane | |
| CN100479150C (en) | Super long alignment infrared focus plane detector | |
| US5590538A (en) | Stacked multistage Joule-Thomson cryostat | |
| KR20110009199A (en) | Cryogenic vacuum break thermal coupler with cross-axial actuation | |
| US5651256A (en) | Superconductive magnet having a thermal shield | |
| JP5942700B2 (en) | Magnetic resonance signal detection probe | |
| CN103500749A (en) | Thermoelectric refrigerating ultra-long linear array InGaAs detector encapsulation structure | |
| CN102820308B (en) | Dual-waveband linear infrared focal plane detector integrated structure | |
| Dicker et al. | MUSTANG2: a large focal plan array for the 100 meter Green Bank Telescope | |
| US6417514B1 (en) | Sensor/support system having a stabilization structure affixed to a side of a platform oppositely disposed from a sensor assembly | |
| CN101292122A (en) | Multi-stage pulse tube cryocooler with acoustic impedance constructed to reduce transient cool down time and thermal loss | |
| CN104538384A (en) | Densely arrayed and spliced dual-band long linear infrared focal plane detector structure | |
| CN2913794Y (en) | Thermally-insulated support means of vacuum interlayer cryogenic fluid delivery conduit without cooling screen | |
| CN112013886A (en) | Infrared detector splicing module and infrared detector integrated assembly | |
| US6044713A (en) | Strain measurement system and method | |
| Poole et al. | Gas-gap heat switches with negative room temperature conductor separation and their application to ultra-low temperature platforms | |
| Hollister et al. | The cryomechanical design of MUSIC: a novel imaging instrument for millimeter-wave astrophysics at the Caltech Submillimeter Observatory | |
| US20110005238A1 (en) | Methods and apparatus for dewar and cold shield assemblies | |
| CN101226925B (en) | Wiring structure of long line series infrared detector dewar assembly and connecting method thereof | |
| CN104596647A (en) | Partial-elasticity cold chain for infrared focal plane dewar | |
| CN203631552U (en) | Thermoelectric refrigeration super long alignment InGaAs detector packaging structure | |
| CN204373784U (en) | For local elasticity's cold chain of infrared focus plane Dewar | |
| Sugimoto et al. | Thermal link for cartridge-type cryostat |
Legal Events
| Date | Code | Title | Description |
|---|---|---|---|
| C14 | Grant of patent or utility model | ||
| GR01 | Patent grant | ||
| CF01 | Termination of patent right due to non-payment of annual fee | ||
| CF01 | Termination of patent right due to non-payment of annual fee |
Granted publication date: 20150729 Termination date: 20180331 |