CN201607410U - Nanometer sensor for simultaneously detecting light signal and electric signal - Google Patents
Nanometer sensor for simultaneously detecting light signal and electric signal Download PDFInfo
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- CN201607410U CN201607410U CN2010201338489U CN201020133848U CN201607410U CN 201607410 U CN201607410 U CN 201607410U CN 2010201338489 U CN2010201338489 U CN 2010201338489U CN 201020133848 U CN201020133848 U CN 201020133848U CN 201607410 U CN201607410 U CN 201607410U
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Abstract
The utility model discloses a nanometer sensor for simultaneously detecting a light signal and an electric signal. Compared with the prior art, the utility model is characterized in that two ends of a nanometer semiconducting metal oxide (6) are respectively provided with a positive electrode (9) and a negative electrode (10), and current output between the positive electrode (9) and the negative electrode (10) and a light and electric signal switching device (8) are connected with an electric signal detection circuit (11). An injection port (2) and a vent nozzle (3) are positioned at the side surface of a quartz tube (1), and the included angle of the centerline of the injection port (2) and the vent nozzle (3) in the circumferential direction is 0 to 15 degrees. The nanometer sensor overcomes the defects of complex operating, long analysis time and poor accuracy of the existing sensor due to objective component catalytic light-emitting signal approaching and has the advantages of good stability and repeatability, realization of multi-objective component detecting, short detecting time, high detecting efficiency and precision, and the like.
Description
Technical field:
The utility model relates to a kind of nano-sensor (nano-material surface-catalyzed luminescent sensor), especially a kind ofly shorten detection time, reduce and detect cost, have the nano-sensor that good stable and reappearance, detection efficiency and precision detect photosignal high the time.
Background technology:
The nano-material surface-catalyzed luminescent sensor applications is extensive, as can be used for quantitative evaluation nano material catalytic activity; The detection by quantitative that is used for ethanol, methyl alcohol and petroleum chemicals etc.; Be used for food hormone medicine residue detection; Be used for the selection type detecting device of capillary gas chromatograph etc.The structure of existing nano-material surface-catalyzed luminescent sensor is that the diameter that will scribble nano material is that to place diameter be that 12~20mm, length are in the quartz ampoule of 100~150mm to 4~7mm electric ceramic rod, diagonally opposing corner is provided with injection port, drain on quartz ampoule, corresponding optical filter or grating, the photosignal conversion equipment (Weak-luminescence measuring instrument, photomultiplier etc.) of being provided with nano material outside quartz ampoule.During measurement, resistance wire in the electric ceramic rod heats nano material, sampling systems such as pneumatic pump enter quartz ampoule with carrier gas from injection port with sample, the nano-material surface of flowing through is discharged from drain, the nano-material surface-catalyzed light that sends becomes the electric signal that is suitable for data processing units such as microcomputer through the photosignal conversion equipment again behind optical filter or grating removal parasitic light.But because the catalytic luminescence signal of target analytes is near (as ethanol and methyl alcohol, alcohols and ethers etc.), make the catalytic luminescence signal on the nano catalytic material surface of flowing through be difficult to differentiate, sometimes need to rely on the change analysis condition to distinguish signal, directly influence the accuracy of quantitative test and made complex operation, increased the time of analyzing and testing.In addition, because existing detecting device is that diagonally opposing corner is provided with injection port, drain on quartz ampoule, flow through time on nano catalytic material surface of sample and carrier gas is long and dead volume is big, easily cause problems such as emission response time length, luminous signal curve broadening, thereby make the stability and the poor reproducibility of luminous signal, measuring accuracy is lower, has directly influenced the accuracy of quantitative test.
Summary of the invention:
The utility model is in order to solve the above-mentioned shortcoming of existing in prior technology, provides a kind of and shortens detection time, reduced and detect cost, has the nano-sensor that good stable and reappearance, detection efficiency and precision detect photosignal high the time.。
Technical solution of the present utility model is: a kind of nano-sensor that detects photosignal simultaneously, quartz ampoule is arranged, injection port and drain are arranged on the quartz ampoule, quartz ampoule is built-in with the ceramic heat rod, be built-in with heating element at the ceramic heat rod, outside the ceramic heat rod, scribble nano semi-conductor metal oxide, corresponding optical filter or grating and the photosignal conversion equipment of being provided with nano semi-conductor metal oxide, two ends at described nano semi-conductor metal oxide are respectively equipped with positive electrode, negative electrode, positive electrode, electric current output between the negative electrode and photosignal conversion equipment and electrical signal detection circuit join; Described injection port and drain are positioned at the side of quartz ampoule, and the center line of injection port and drain angle in a circumferential direction is 0~15 degree.
One end of described ceramic heat rod is fixed on the end face of quartz ampoule.
The utility model is simultaneously as detection signal with the catalytic luminescence signal of nano-material surface and electrochemical signals, has good two dimensional character signal, resolution and detection sensitivity all improve greatly, fast quantification when can realize the multiple goal component has further reduced the detection cost, has improved detection efficiency; Overcome existing sensor because of target components catalytic luminescence signal near the complex operation that exists, analysis time is long and the shortcoming of poor accuracy, have lack good stable and reappearance, the detection that can realize the multiple goal component, detection time, detection efficiency and precision advantages of higher.
Description of drawings:
Fig. 1 is the structural representation of the utility model embodiment 1.
Embodiment:
Below in conjunction with description of drawings embodiment of the present utility model.
As shown in Figure 1: quartz ampoule 1 is arranged, quartz ampoule 1 is provided with injection port 2 and drain 3, quartz ampoule 1 is built-in with ceramic heat rod 4, at ceramic heat rod 4 internal fixation heating element 5 is arranged, outside ceramic heat rod 4, scribble nano semi-conductor metal oxide 6, with nano semi-conductor metal oxide 6 corresponding optical filter or grating 7 and the photosignal conversion equipments 8 of being provided with, be respectively equipped with positive electrode 9 at the two ends of described nano semi-conductor metal oxide 6, negative electrode 10, can be at positive electrode 9, reometer (electrical signal detection circuit 11) joins between the negative electrode 10, also electric current can be drawn, current output terminal and mould/number conversion circuit 12 joins, and described photosignal conversion equipment 8 and mould/number conversion circuit 12 joins with microprocessor (electrical signal detection circuit 11) simultaneously.For fear of the big problem of dead volume that causes because of injection port 2 and drain 3 diagonal angle settings, described injection port 2 and drain 3 are positioned at the side of quartz ampoule 1, and the center line angle in a circumferential direction of injection port 2 and drain 3 is 0~15 degree.For the end with described ceramic heat rod 4 easy for installation is fixed on the end face of quartz ampoule 1.
According to the method for prior art heating element 5 and power supply are joined during detection, simultaneously positive and negative electrode 9,10 and power supply are joined, the nano material of the electric current that makes intensity 1~15mA during by zero load.Sample atomized according to art methods and be carrier gas with the air, enter from injection port 2, flow out from drain 3, the sample nano semi-conductor metal oxide 6 of promptly flowing through produces the light signal and the electric signal that become correlativity with concentration.By light signal and electric signal are handled and detected, can measure the content of target component.
Claims (2)
1. nano-sensor that detects photosignal simultaneously, quartz ampoule (1) is arranged, injection port (2) and drain (3) are arranged on the quartz ampoule (1), quartz ampoule (1) is built-in with ceramic heat rod (4), be built-in with heating element (5) at ceramic heat rod (4), outside ceramic heat rod (4), scribble nano semi-conductor metal oxide (6), corresponding optical filter or grating (7) and the photosignal conversion equipment (8) of being provided with nano semi-conductor metal oxide (6), it is characterized in that: be respectively equipped with positive electrode (9) at the two ends of described nano semi-conductor metal oxide (6), negative electrode (10), positive electrode (9), electric current output and photosignal conversion equipment (8) between the negative electrode (10) join with electrical signal detection circuit (11); Described injection port (2) and drain (3) are positioned at the side of quartz ampoule (1), and the center line angle in a circumferential direction of injection port (2) and drain (3) is 0~15 degree.
2. the nano-sensor that detects photosignal simultaneously according to claim 1 is characterized in that: an end of described ceramic heat rod (4) is fixed on the end face of quartz ampoule (1).
Priority Applications (1)
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CN2010201338489U CN201607410U (en) | 2010-03-18 | 2010-03-18 | Nanometer sensor for simultaneously detecting light signal and electric signal |
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CN2010201338489U CN201607410U (en) | 2010-03-18 | 2010-03-18 | Nanometer sensor for simultaneously detecting light signal and electric signal |
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CN2010201338489U Expired - Fee Related CN201607410U (en) | 2010-03-18 | 2010-03-18 | Nanometer sensor for simultaneously detecting light signal and electric signal |
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Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
WO2019207291A1 (en) * | 2018-04-24 | 2019-10-31 | University Of The West Of England | Sensors for determining volatile compounds based on electrical conductivity and cataluminescence measurements of metal oxide films |
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2010
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Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
WO2019207291A1 (en) * | 2018-04-24 | 2019-10-31 | University Of The West Of England | Sensors for determining volatile compounds based on electrical conductivity and cataluminescence measurements of metal oxide films |
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C14 | Grant of patent or utility model | ||
GR01 | Patent grant | ||
C17 | Cessation of patent right | ||
CF01 | Termination of patent right due to non-payment of annual fee |
Granted publication date: 20101013 Termination date: 20130318 |