CN209398417U - A kind of drilling hyperspectral measurement device in situ - Google Patents
A kind of drilling hyperspectral measurement device in situ Download PDFInfo
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- CN209398417U CN209398417U CN201822223424.0U CN201822223424U CN209398417U CN 209398417 U CN209398417 U CN 209398417U CN 201822223424 U CN201822223424 U CN 201822223424U CN 209398417 U CN209398417 U CN 209398417U
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Abstract
The utility model belongs to high spectrum resolution remote sensing technique field, more particularly to a kind of drilling hyperspectral measurement device in situ, it include: probe, wirerope and cable, the probe further include: container chamber, rotator, light source, reflective mirror, lens, spectrometer, posture logger and several transparent glass;Wirerope and cable are connected separately at the top of the probe;Spectrometer, lens, rotator and posture logger are from top to bottom successively fixed with inside the container chamber;Light source and reflective mirror are additionally provided on the rotator;The probe lower end outer wall is provided with several transparent glass.The utility model realizes the in situ measurement of drilling by the hyperspectral measurement device in situ that drills, rather than coring scans, thus loss of learning caused by avoiding coring imperfect;The hyperspectral measurement in situ that drilling can be achieved ensure that the integrality and accuracy for obtaining subsurface geology information.
Description
Technical field
The utility model belongs to high spectrum resolution remote sensing technique field, and in particular to a kind of drilling hyperspectral measurement device in situ.
Background technique
Rock core is the important carrier for obtaining subsurface geology information, and EO-1 hyperion rock core scanning technique can be identified deep by rock core
The rock and mineral type in portion.But some stratum are more fragile or there is the area of corrosion on stratum, it is difficult to obtain complete rock
The heart, so as to cause the missing of subsurface information.Therefore continue to design a kind of drilling hyperspectral measurement device in situ, realize the original of drilling
Position measurement, rather than coring scans, thus loss of learning caused by avoiding coring imperfect.
Utility model content
The utility model provides a kind of drilling hyperspectral measurement device in situ for prior art deficiency, existing for solving
It is scanned in technology using coring, leads to the technical issues of obtaining imperfect subsurface geology, loss of learning.
Realize the technical solution of the utility model aim:
A kind of drilling hyperspectral measurement device in situ, comprising: probe, wirerope and cable, the probe further include: container
Chamber, rotator, light source, reflective mirror, lens, spectrometer, posture logger and several transparent glass;Connect respectively at the top of the probe
It is connected to wirerope and cable;Spectrometer, lens, rotator and posture record are from top to bottom successively fixed with inside the container chamber
Device;Light source and reflective mirror are additionally provided on the rotator;The probe lower end outer wall is provided with several transparent glass.
The light source provides spectrum segment light source by power supply mode;The light source further include: several independent sub-light sources, light source
Wavelength band is provided in the light of 200nm-3000nm.
The cable further include: the electric wire powered respectively to light source, spectrometer, rotator and posture logger;Control light
The control line and data line of spectrometer, rotator and posture logger.
The wavelength band of the spectrometer is: 200nm-3000nm.
Several transparent glass sizes are greater than reflector size, and transparent glass the fixed position of probe lower end outer wall with
Reflective mirror setting is contour in rotator upper surface location.
The advantageous effects of the utility model are:
The utility model realizes the in situ measurement of drilling by the hyperspectral measurement device in situ that drills, rather than coring scans,
Thus loss of learning caused by avoiding coring imperfect;The hyperspectral measurement in situ that drilling can be achieved ensure that and obtain underground
The integrality and accuracy of geological information.
Detailed description of the invention
A kind of structural schematic diagram for drilling original position hyperspectral measurement device that Fig. 1 designs for the utility model
Wherein: 1- probe, 2- wirerope, 3- cable, 4- container chamber, 5- rotator, 6- light source, 7- reflective mirror, 8- lens, 9-
Spectrometer, 10- posture logger, 11- transparent glass.
Specific embodiment
The utility model is described in further detail below with reference to embodiment.
As indicated with 1, a kind of drilling hyperspectral measurement device in situ, comprising: probe 1, wirerope 2 and cable 3, the probe 1
Further include: container chamber 4, rotator 5, light source 6, reflective mirror 7, lens 8, spectrometer 9, posture logger 10 and several transparent glass
11;1 top of probe is connected separately with wirerope 2 and cable 3;Spectrum is from top to bottom successively fixed with inside the container chamber 4
Instrument 9, lens 8, rotator 5 and posture logger 10;Light source 6 and reflective mirror 7 are additionally provided on the rotator 5;The probe 1
Lower end outer wall is provided with several transparent glass 11.
The light source 6 provides spectrum segment light source by power supply mode;The light source 6 further include: several independent sub-light sources, light
Source 6 provides wavelength band in the light of 200nm-3000nm.
The cable 3 further include: the electric wire powered respectively to light source 6, spectrometer 9, rotator 5 and posture logger 10;
Control the control line and data line of spectrometer 9, rotator 5 and posture logger 10.
The wavelength band of the spectrometer 9 is: 200nm-3000nm.
11 size of several transparent glass is greater than 7 size of reflective mirror, and transparent glass 11 is fixed in 1 lower end outer wall of popping one's head in
Position is arranged contour in 5 upper surface location of rotator with reflective mirror 7.
A kind of measurement method of the hyperspectral measurement device in situ as described above that drills, includes the following steps:
Step 1 determines the drilling fluid types to be measured for drilling and using;
Step 2 is that transparent drilling fluid directly executes step 3 to unused drilling fluid or drilling fluid, is otherwise first bored
Well liquid cleaning, then carry out step 3;
Probe 1 is connect by step 3 with wirerope 2 and cable 3;
Step 4 draws probe 1 using wirerope 2 and enters drilling, controls probe 1 by the well length that enters of control wirerope 2
Enter well depth, light source 6 and rotator 5 are powered and controlled using cable 3, and spectrometer 9 and posture logger 10 are obtained
Data are transmitted back to ground.
Step 5, constantly change wirerope 2 enters well length, until entire drilling is all measured and finishes.
It includes: rotator rotation angle, probe rotation angle and the positive north that posture logger 10 as described above, which records content,
To angle, pop one's head in inclined direction and inclination angle.
The utility model is explained in detail above in conjunction with embodiment, but the utility model is not limited to above-mentioned implementation
Example, within the knowledge of a person skilled in the art, can also be in the premise for not departing from the utility model aims
It is lower that various changes can be made.The content being not described in detail in the utility model can use the prior art.
Claims (5)
1. a kind of drilling hyperspectral measurement device in situ characterized by comprising probe (1), wirerope (2) and cable (3), institute
State probe (1) further include: container chamber (4), rotator (5), light source (6), reflective mirror (7), lens (8), spectrometer (9), posture
Logger (10) and several transparent glass (11);Wirerope (2) and cable (3) are connected separately at the top of the probe (1);The appearance
Spectrometer (9), lens (8), rotator (5) and posture logger (10) are from top to bottom successively fixed with inside device chamber (4);It is described
Light source (6) and reflective mirror (7) are additionally provided on rotator (5);Described probe (1) lower end outer wall is provided with several transparent glass
(11)。
2. a kind of drilling hyperspectral measurement device in situ as described in claim 1, it is characterised in that: the light source (6) passes through
Power supply mode provides spectrum segment light source;The light source (6) further include: several independent sub-light sources, light source (6) provide wavelength band and exist
The light of 200nm-3000nm.
3. a kind of drilling hyperspectral measurement device in situ as described in claim 1, it is characterised in that: the cable (3) is also wrapped
It includes: the electric wire powered respectively to light source (6), spectrometer (9), rotator (5) and posture logger (10);Control spectrometer (9),
The control line and data line of rotator (5) and posture logger (10).
4. a kind of drilling hyperspectral measurement device in situ as described in claim 1, it is characterised in that: the spectrometer (9)
Wavelength band be: 200nm-3000nm.
5. a kind of drilling hyperspectral measurement device in situ as described in claim 1, it is characterised in that: several transparent glass
(11) size is greater than reflective mirror (7) size, and transparent glass (11) is in the fixed position of probe (1) lower end outer wall and reflective mirror (7)
It is arranged contour in rotator (5) upper surface location.
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CN201822223424.0U CN209398417U (en) | 2018-12-27 | 2018-12-27 | A kind of drilling hyperspectral measurement device in situ |
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CN201822223424.0U CN209398417U (en) | 2018-12-27 | 2018-12-27 | A kind of drilling hyperspectral measurement device in situ |
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Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN109681197A (en) * | 2018-12-27 | 2019-04-26 | 核工业北京地质研究院 | A kind of drilling hyperspectral measurement device in situ and its measurement method |
CN111879247A (en) * | 2020-08-03 | 2020-11-03 | 海伯森技术(深圳)有限公司 | Device for measuring specification of shaft hole |
-
2018
- 2018-12-27 CN CN201822223424.0U patent/CN209398417U/en active Active
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN109681197A (en) * | 2018-12-27 | 2019-04-26 | 核工业北京地质研究院 | A kind of drilling hyperspectral measurement device in situ and its measurement method |
CN111879247A (en) * | 2020-08-03 | 2020-11-03 | 海伯森技术(深圳)有限公司 | Device for measuring specification of shaft hole |
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