CN112067557A - Oil-gas detection device of oil-immersed equipment - Google Patents

Abstract

The application discloses oil-immersed equipment oil gas detection device includes: the measuring unit is used for respectively measuring the first photoacoustic signal intensity of the characteristic gas in the gas sample to be measured and the second photoacoustic signal intensity of the characteristic gas in the standard gas sample by using narrow-bandwidth laser; the control unit is used for obtaining the actual concentration of the characteristic gas in the gas sample to be detected according to the second photoacoustic signal intensity, the standard photoacoustic signal intensity and the first photoacoustic signal intensity, and determining the operation fault type of the oil-immersed equipment according to the actual concentration; this application can be when detecting second photoacoustic signal intensity and standard photoacoustic signal intensity inequality, revises through the predetermined power to narrow bandwidth laser, can obtain the actual concentration of characteristic gas in the gaseous sample that awaits measuring, can judge out the fault type of oil-immersed equipment according to characteristics such as the component type of characteristic gas in the gaseous sample that awaits measuring and actual concentration, and detection efficiency and degree of accuracy are high.

Description

Oil-gas detection device of oil-immersed equipment

Technical Field

The application relates to an oil-immersed equipment detects the field, especially relates to an oil-immersed equipment oil gas detection device.

Background

With the rapid development of national economy, the demand of various industries on electric power is continuously rising, and nowadays, electric power systems are also developing towards ultrahigh voltage, large capacity and automation, so that a large number of large-scale oil-immersed devices (such as transformers) are adopted in the electric power systems, and in order to guarantee the safe operation of the electric power systems, the operation states of the large-scale oil-immersed devices such as the transformers and the like must be preventively checked and monitored.

Because oil-immersed equipment all chooses compound insulation structure such as cooling oil, oiled paper or oiled paper board for use, when the equipment is inside to take place thermal failure, discharge nature trouble or insulating oil, oiled paper when ageing, can produce multiple gas, these gas can be dissolved in the cooling oil, and the gas of the different grade type of dissolving in the cooling oil can reflect the electrical fault of oil-immersed equipment different grade type.

At present, in a traditional monitoring scheme for the running state of the oil-immersed equipment, after an oil sample in the oil-immersed equipment needs to be manually extracted and concentrated in a laboratory, a gas chromatograph is used for analyzing the oil sample, the running state of the oil-immersed equipment is determined according to an analysis result, and the efficiency is low.

Disclosure of Invention

The embodiment of the application provides an oil-immersed device oil gas detection device to in solving current traditional oil-immersed device running state monitoring scheme, need the oil appearance among the artifical extraction oil-immersed device and concentrate on the laboratory after, use gas chromatograph to carry out the analysis to the oil appearance, confirm the running state of oil-immersed device through the analysis result, the lower technical problem of efficiency.

In order to solve the above problems, the technical scheme provided by the invention is as follows:

the utility model provides an oil-immersed equipment oil gas detection device, includes the control unit, oil circuit unit, degasification unit, gas circuit unit and measuring element, wherein:

the control unit is used for sending a sampling enabling signal, a degassing enabling signal and a measurement enabling signal;

the oil circuit unit is used for receiving the sampling enabling signal and the degassing enabling signal, and is also used for acquiring a cooling oil sample from the oil-immersed equipment according to the sampling enabling signal and controlling the cooling oil sample to flow into the degassing unit according to the degassing enabling signal;

the degassing unit is used for receiving the degassing enabling signal and the measurement enabling signal, degassing the cooling oil sample according to the degassing enabling signal to obtain a gas sample to be measured, and controlling the gas sample to be measured to flow into the gas circuit unit according to the measurement enabling signal;

the gas circuit unit is used for receiving the measurement enabling signal and controlling the gas sample to be measured to flow into the measuring unit from the gas circuit unit according to the measurement enabling signal;

the measurement unit is used for receiving the measurement enabling signal, and controlling a photoacoustic spectroscopy device in the measurement unit according to the measurement enabling signal to respectively measure a first photoacoustic signal of a characteristic gas in the gas sample to be measured and a second photoacoustic signal of the characteristic gas in a standard gas sample by using narrow-bandwidth laser with preset power and preset wavelength, and feeding the first photoacoustic signal and the second photoacoustic signal back to the control unit;

the control unit is further used for determining a first photoacoustic signal intensity of the characteristic gas in the gas sample to be measured and a second photoacoustic signal intensity of the characteristic gas in the standard gas sample according to the first photoacoustic signal and the second photoacoustic signal, and obtaining the actual concentration of the characteristic gas in the gas sample to be measured according to the second photoacoustic signal intensity, the standard photoacoustic signal intensity of the characteristic gas in the standard gas sample and the first photoacoustic signal intensity;

the control unit is further used for determining the operation fault type of the oil-immersed device according to the actual concentration.

Drawings

The technical solution and other advantages of the present application will become apparent from the detailed description of the embodiments of the present application with reference to the accompanying drawings.

Fig. 1 is a scene schematic diagram of an oil-immersed device monitoring system provided in an embodiment of the present application;

fig. 2 is a first structural schematic diagram of an oil-gas detection device of an oil-immersed device provided in the embodiment of the present application;

fig. 3 is a schematic structural diagram of a second oil-gas detection device of an oil-immersed device according to an embodiment of the present application;

fig. 4 is a schematic view of a first structure of a measurement unit according to an embodiment of the present disclosure;

FIG. 5 is a schematic structural diagram of a temperature control unit provided in an embodiment of the present application;

FIG. 6 is a schematic diagram of a temperature control circuit in a temperature control unit provided in an embodiment of the present application;

fig. 7 is a schematic view of a second structure of a measurement unit according to an embodiment of the present disclosure;

fig. 8 is a schematic structural diagram of a third measurement unit provided in the embodiment of the present application;

FIG. 9 is a schematic circuit diagram of a photoelectric conversion circuit of the oil-gas detection device of the oil-immersed device according to the embodiment of the present application;

fig. 10 is a schematic circuit diagram of a first signal amplification circuit of an oil-gas detection device of an oil-immersed device according to an embodiment of the present application;

FIG. 11 is a schematic circuit diagram of a band-pass filter circuit of the oil-gas detection device of the oil-immersed equipment according to the embodiment of the present application;

fig. 12 is a schematic circuit diagram of a second signal amplification circuit of the oil-gas detection device of the oil-immersed device according to the embodiment of the present application;

FIG. 13 is a schematic circuit diagram of an A/D conversion circuit of the oil-gas detection device of the oil-immersed device according to the embodiment of the present application;

fig. 14 is a third structural schematic diagram of an oil-gas detection device of an oil-filled device provided in an embodiment of the present application.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application. It is to be understood that the embodiments described are only a few embodiments of the present application and not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

This application is to in current traditional oily formula equipment running state monitoring scheme, need artifical oil sample that draws in oily formula equipment and concentrate on the laboratory after, uses gas chromatograph to carry out the analysis to oil sample, confirms the running state of oily formula equipment, the lower technical problem of efficiency through the analysis result.

Referring to fig. 1, fig. 1 is a scene schematic diagram of an operation state monitoring system of an oil-immersed device according to an embodiment of the present disclosure, where the system may include an oil-immersed device 10 and an oil-gas detection device 20 of the oil-immersed device, and the oil-gas detection device 20 of the oil-immersed device may be connected to the oil-immersed device 10 through a pipeline.

The oil-filled device 10 may be an oil-filled transformer, the internal insulation structure of the oil-filled transformer is a composite insulation structure mainly including cooling oil and an insulation material, and the insulation material may be one or more of insulation paper and an insulation board.

Wherein, the cooling oil is generally a mixture composed of a plurality of hydrocarbon molecules, and the cooling oil can be composed of most of burned warp and a small part of ring burned warp and unsaturated aromatic warp; the insulating paper or the insulating board may be a fibrous product, and the main component of the insulating paper or the insulating board is cellulose. When a fault such as discharge or overheating occurs inside the oil-filled transformer, high-carbon organic molecules in the insulating material are cracked to generate characteristic gases such as methane, ethane, ethylene, acetylene, carbon monoxide, carbon dioxide and hydrogen, and the generated characteristic gases are continuously accumulated in the cooling oil of the oil-filled device 10.

Specifically, as shown in fig. 1 and fig. 2, fig. 2 is a first structural schematic diagram of an oil-filled device oil-gas detection device 20 provided in an embodiment of the present application, where the oil-filled device oil-gas detection device 20 includes an oil path unit 201, a degassing unit 202, an air path unit 203, a measurement unit 204, and a control unit 205.

Specifically, the control unit 205 is configured to send a sampling enable signal to the oil path unit 201, a degassing enable signal to the oil path unit 201 and the degassing unit 202, and a measurement enable signal to the degassing unit 202, the gas path unit 203, and the measurement unit 204, so as to control operations of the oil path unit 201, the degassing unit 202, the gas path unit 203, and the measurement unit 204.

Specifically, the oil circuit unit 201 is configured to receive the sampling enable signal and the degassing enable signal, and the oil circuit unit 201 is further configured to obtain a cooling oil sample from the oil-filled device 10 according to the sampling enable signal, and control the cooling oil sample to flow into the degassing unit 202 according to the degassing enable signal.

In an embodiment, when the oil path unit 201 obtains the cooling oil sample from the oil-filled device 10, a valve and an oil pump may be disposed between the oil-filled device 10 and the oil path unit 201, when the control unit 205 sends the sampling enable signal to the oil path unit 201, the valve between the oil path unit 201 and the oil-filled device 10 is opened, the oil pump extracts the cooling oil sample from the oil-filled device 10 into the oil path unit 201, and the volume of the cooling oil sample is set according to a requirement.

In an embodiment, after the oil path unit 201 obtains the cooling oil sample, the cooling oil sample may be pretreated in the oil path unit 201, for example, if impurities such as organic particles or water exist in the cooling oil sample, the impurities such as organic particles or water in the cooling oil sample are removed in the pretreatment process, so that the pretreated cooling oil sample is relatively pure.

Specifically, the degassing unit 202 is configured to receive the degassing enable signal and the measurement enable signal, and the degassing unit 202 is further configured to degas the cooling oil sample according to the degassing enable signal to obtain a gas sample to be measured, and control the gas sample to be measured to flow into the gas circuit unit 203 according to the measurement enable signal.

The oil line unit 201 and the degassing unit 202 can be communicated through an oil pipe, and a valve is arranged on the oil pipe to control the connection and disconnection between the oil line unit 201 and the degassing unit 202.

In one embodiment, when the degassing unit 202 is used to degas the cooling oil sample, the cooling oil sample may be degassed by headspace degassing or by degassing the cooling oil sample by a degassing membrane tube.

Wherein, the mode of headspace degasification is that the cooling oil sample gets into the oil tank, with the gas outgoing of oil tank top, avoids original gas in the oil tank to produce the influence to the gas sample that awaits measuring for form the negative pressure in the oil tank, then adopt to the oil tank bottom heating, carry out the mode of stirring to the cooling oil sample simultaneously, make the gas sample that awaits measuring in the cooling oil separate out.

The mode of adopting degasification membrane tube degasification means taking out the gas in the degasification membrane tube earlier, avoids original gas in the degasification membrane tube to produce the influence to the gas sample that awaits measuring in the cooling oil sample, and makes and form the negative pressure in the degasification membrane tube, then makes the cooling oil sample enter into the degasification membrane tube, is equipped with polytetrafluoroethylene nanometer separation membrane in the degasification membrane tube, adopts the gas sample that awaits measuring in the polytetrafluoroethylene nanometer separation membrane separation cooling oil sample.

Specifically, the gas circuit unit 203 is configured to receive the measurement enable signal, and the gas circuit unit 203 is further configured to control the gas sample to be measured to flow from the gas circuit unit 203 to the measurement unit 204 according to the measurement enable signal.

In an embodiment, the gas path unit 203 may include a pipeline and a filtering and drying component, and the degassing unit 202 and the measuring unit 204 may communicate through the pipeline in the gas path unit 203; when the gas sample to be detected enters the gas circuit unit 203 from the degassing unit 202, the gas sample to be detected may have impurity gases such as water vapor, and the gas sample to be detected may be pretreated by the filtering and drying component in the gas circuit unit 203 to remove the impurity gases in the gas sample to be detected.

Specifically, the measurement unit 204 is configured to receive the measurement enable signal, and the measurement unit 204 is further configured to control the photoacoustic spectroscopy device in the measurement unit 204 according to the measurement enable signal to measure a first photoacoustic signal of the characteristic gas in the gas sample to be measured and a second photoacoustic signal of the characteristic gas in the standard gas sample using a narrow bandwidth laser with a preset power and a preset wavelength, respectively, and feed back the first photoacoustic signal and the second photoacoustic signal to the control unit 205.

Specifically, the control unit 205 is further configured to determine a first photoacoustic signal intensity of the characteristic gas in the gas sample to be measured and a second photoacoustic signal intensity of the characteristic gas in the standard gas sample according to the first photoacoustic signal and the second photoacoustic signal.

The narrow-bandwidth laser is laser subjected to periodic intensity modulation or periodic frequency modulation, the narrow-bandwidth laser has a preset wavelength corresponding to the characteristic gas, and the narrow-bandwidth laser is monochromatic light; the characteristic gas can be any one of methane, ethane, ethylene, acetylene, carbon monoxide, carbon dioxide and hydrogen, and when the gas sample to be measured is measured, the concentration of all kinds of characteristic gases in the gas sample to be measured needs to be measured; the standard gas sample comprises methane, ethane, ethylene, acetylene, carbon monoxide, carbon dioxide, hydrogen and other gases, and the standard concentration of the characteristic gas in the standard gas sample is a known concentration.

The photoacoustic spectroscopy is a spectroscopy for detecting the concentration of an absorbent by using the photoacoustic effect, and is based on the principle of the photoacoustic effect, that is, the principle that a substance generates an acoustic signal when irradiated with periodic intensity-modulated light or periodic frequency-modulated light. The specific principle of the photoacoustic effect is as follows: the characteristic gas molecules in the gas sample to be detected are excited to a high-energy state after absorbing the narrow-bandwidth laser with the corresponding wavelength, the characteristic gas molecules return to a low-energy state through spontaneous radiation transition and non-radiation transition, the energy released by the characteristic gas molecules is converted into translational kinetic energy and rotational kinetic energy of the gas sample to be detected in the process that the characteristic gas molecules return to the low-energy state through the non-radiation transition, the temperature of the gas sample to be detected is increased, the gas pressure of the gas sample to be detected is increased under the condition that the gas volume of the gas sample to be detected is certain, if the narrow-bandwidth laser is subjected to light intensity modulation or frequency modulation, the temperature of the gas sample to be detected can show periodic change which is the same as modulation frequency, the pressure of the gas sample to be detected is further subjected to periodic change, and when the modulation frequency is within an audio frequency range, an acoustic signal, i.e. a photo acoustic signal, is generated.

It can be understood that each gas molecule in the characteristic gases of methane, ethane, ethylene, acetylene, carbon monoxide, carbon dioxide, hydrogen, etc. has its own absorption band and absorption peak, and there is a certain difference between the absorption peaks of different gases.

Therefore, when the oil-gas detection device 20 of the oil-immersed device is used for detecting gas dissolved in cooling oil of the oil-immersed device 10, the wavelength of the narrow-bandwidth laser can be adjusted, so that the narrow-bandwidth laser is only absorbed by corresponding characteristic gas in a gas sample to be detected, and the independent detection of the characteristic gas such as methane, ethane, ethylene, acetylene, carbon monoxide, carbon dioxide and hydrogen in the gas sample to be detected is realized, and thus the component type of the characteristic gas in the gas sample to be detected can be detected.

Under the condition that the power and the wavelength of the narrow-bandwidth laser are not changed, the strength of the photoacoustic signal generated by the characteristic gas is in a direct proportional relation with the concentration of the characteristic gas, so that the concentration of the characteristic gas in the gas sample to be detected can be detected, the fault property and the fault type of the oil-immersed equipment 10 can be judged according to the characteristics such as the component type, the concentration and the like of the characteristic gas in the gas sample to be detected, the real-time monitoring on the oil-immersed equipment 10 such as an oil-filled transformer can be realized, the detection efficiency is high, and the internal fault of the oil-filled equipment 10 such as the oil-filled transformer can be found in. During an epidemic situation, the oil-gas detection device 20 of the oil-immersed device can be used for real-time and effective monitoring on the oil-immersed device 10, a worker does not need to periodically extract an oil sample in the oil-immersed device 10 and analyze the oil sample in a laboratory by using a gas chromatograph, and the labor intensity and the work risk of the worker are reduced; meanwhile, when the oil-immersed device 10 has a fault, the oil-gas detection device 20 of the oil-immersed device can detect the fault type of the oil-immersed device 10 in time and send an alarm to a worker, so that the worker can process the oil-immersed device 10 according to the fault type.

As shown in table 1 below, table 1 shows the types of characteristic gases corresponding to the respective failure types.

TABLE 1

As can be seen from table 1, when the oil-filled device 10 has different fault types, the types of the characteristic gases measured from the gas sample to be measured are different, for example, when the fault type is that the cooling oil is overheated, the types of the corresponding characteristic gases are hydrogen, ethylene, methane, and ethane; when the fault type is cooling oil and paper overheating, the corresponding characteristic gas types are hydrogen, carbon monoxide, carbon dioxide, ethylene, methane and ethane; when the fault type is partial discharge in cooling oil and paper insulation, the types of corresponding characteristic gases are hydrogen, carbon monoxide, carbon dioxide, acetylene, methane and ethane; when the fault type is spark discharge in the cooling oil, the corresponding characteristic gas is hydrogen and acetylene; when the fault type is arc discharge in cooling oil, the corresponding characteristic gas is hydrogen, acetylene, ethylene, methane and ethane; when the fault type is arc discharge in cooling oil and paper, the corresponding characteristic gas is hydrogen, carbon monoxide, carbon dioxide, acetylene, ethylene, methane and ethane; when the fault type is that paper is wetted or cooling oil has bubbles, the corresponding characteristic gas is hydrogen; in table 1 "-" indicates that the concentration of the characteristic gas in the fault type is 0.

It is understood that the concentration of the characteristic gas in the gas sample to be measured refers to the mass number of the characteristic gas in the standard volume of the gas sample to be measured.

Specifically, the control unit 205 is further configured to obtain an actual concentration of the characteristic gas in the gas sample to be detected according to the second photoacoustic signal intensity, the standard photoacoustic signal intensity of the characteristic gas in the standard gas sample, and the first photoacoustic signal intensity, and determine the operation fault type of the oil-filled device 10 according to the actual concentration.

It should be noted that, under the condition that the wavelength of the narrow-bandwidth laser and the concentration of the characteristic gas are not changed, the strength of the photoacoustic signal generated by the characteristic gas has a linear relationship with the power of the narrow-bandwidth laser, and due to factors such as device aging, the power of the narrow-bandwidth laser used by the photoacoustic spectroscopy device in the measurement unit 204 may be attenuated in the monitoring process, so that the actual power of the narrow-bandwidth laser is different from the preset power, and thus the detected strength of the first photoacoustic signal is smaller than the accurate strength of the first photoacoustic signal, so that the measured concentration of the characteristic gas in the gas sample to be detected, which is determined according to the strength of the first photoacoustic signal, is smaller than the actual concentration, and the fault determination result of the oil-filled device oil gas detection apparatus 20 on the oil-filled device 10.

In the application, by detecting the gas sample to be detected and the standard gas sample simultaneously in the photoacoustic spectroscopy device, because the type and the concentration of the characteristic gas in the standard gas sample are determined, under the condition that the power and the wavelength of the narrow-bandwidth laser used by the photoacoustic spectroscopy device are determined, the standard photoacoustic signal intensity of the characteristic gas in the standard gas sample can be calculated, when a second photoacoustic signal intensity of the characteristic gas in the standard gas sample is detected to be different from the standard photoacoustic signal intensity, namely, the difference between the preset power and the actual power of the narrow-bandwidth laser used by the photoacoustic spectroscopy device can be judged, at the moment, the actual power of the narrow-bandwidth laser is changed by correcting the preset power of the narrow-bandwidth laser, the actual concentration of the characteristic gas in the gas sample to be detected can be obtained, and the detection precision and accuracy of the oil-gas detection device 20 of the oil-immersed equipment are improved.

It should be noted that, when the actual concentration of the characteristic gas in the gas sample to be measured is obtained, it needs to be determined whether the second photoacoustic signal intensity is the same as the standard photoacoustic signal intensity; if the measured concentration is the same as the actual concentration, the control unit 205 may determine the measured concentration of the characteristic gas in the gas sample to be measured corresponding to the first photoacoustic signal intensity according to the correspondence between the gas concentration, the narrow bandwidth laser power and the photoacoustic signal intensity, and obtain the actual concentration, where the measured concentration is the same as the actual concentration.

And when the second photoacoustic signal intensity is judged to be different from the standard photoacoustic signal intensity, the measured concentration of the characteristic gas in the gas sample to be detected corresponding to the first photoacoustic signal intensity is different from the actual concentration, and at this time, the oil-gas detection device 20 of the oil-immersed device has an error in fault detection of the oil-immersed device 10, and the detection result needs to be corrected to obtain the actual concentration of the characteristic gas in the gas sample to be detected.

In an embodiment, the control unit 205 is further configured to determine a photoacoustic signal intensity attenuation value caused by power attenuation of the narrow-bandwidth laser light at the sample standard concentration according to the second photoacoustic signal intensity and the standard photoacoustic signal intensity when it is determined that the second photoacoustic signal intensity is not the same as the standard photoacoustic signal intensity of the characteristic gas in the standard gas sample.

The control unit 205 is further configured to determine the narrow-bandwidth laser power attenuation value according to the correspondence between the gas concentration, the narrow-bandwidth laser power attenuation value, and the photoacoustic signal intensity attenuation value.

The control unit 205 is further configured to send a correction enable signal to the measurement unit 204 according to the narrow bandwidth laser power attenuation value.

The measurement unit 204 is further configured to modify the preset power according to the modification enable signal.

The measuring unit 204 is further configured to control the photoacoustic spectroscopy device to re-measure the characteristic gas in the gas sample to be measured by using the narrow-bandwidth laser with the corrected preset power, so as to obtain the actual photoacoustic signal intensity of the characteristic gas in the gas sample to be measured.

The control unit 205 is further configured to determine the actual concentration corresponding to the actual photoacoustic signal intensity according to a correspondence between a gas concentration, a narrow bandwidth laser power, and a photoacoustic signal intensity.

The sample standard concentration refers to the concentration of the characteristic gas in the standard gas sample, the sample standard concentration is a known concentration, and the sample standard concentration is greater than the minimum concentration that can be measured by the measurement unit 204, and the sample standard concentration may preferably be 25-1000 ppm.

It can be understood that, when the oil-gas detection device 20 of the oil-immersed device works, the control unit 205 selects the preset power according to the requirement on the actual power of the narrow-bandwidth laser, and if the actual power of the narrow-bandwidth laser is required to be a megawatt, the preset power is selected to be a megawatt, at this time, the intensity of the standard photoacoustic signal generated when the characteristic gas with the standard concentration in the standard gas sample absorbs the narrow-bandwidth laser with the preset power should be b millivolts, and b is an electrical signal value corresponding to the size of the sound signal generated when the characteristic gas with the standard concentration in the standard gas sample absorbs the narrow-bandwidth laser with the preset power.

However, when the power of the narrow-bandwidth laser is attenuated, the actual power of the narrow-bandwidth laser is smaller than the preset power, so that the second photoacoustic signal intensity detected at this time is only c mv, and at this time, the photoacoustic signal intensity attenuation value caused by the power attenuation of the narrow-bandwidth laser under the standard concentration can be determined to be b-c mv, the control unit 205 can determine the narrow-bandwidth laser power attenuation value to be d according to the corresponding relationship between the gas concentration, the narrow-bandwidth laser power attenuation value and the photoacoustic signal intensity attenuation value, so as to correct the preset power according to the narrow-bandwidth laser power attenuation value, so that the actual power of the narrow-bandwidth laser is a megawatt, and the actual photoacoustic signal intensity generated after the narrow-bandwidth laser with the characteristic gas absorption power of a megawatt in the gas sample to be detected can be obtained, so as to correct the detection result of the characteristic gas in the gas sample to be detected, the detection precision is improved.

In an embodiment, the control unit 205 is further configured to send an adjustment enable signal to the measurement unit 204 when the second photoacoustic signal strength is determined to be different from the standard photoacoustic signal strength of the characteristic gas in the standard gas sample.

The measurement unit 204 is further configured to dynamically adjust the preset power according to the adjustment enable signal until the second photoacoustic signal strength is the same as the standard photoacoustic signal strength.

The measuring unit 204 is further configured to control the photoacoustic spectroscopy device to re-measure the characteristic gas in the gas sample to be measured by using the narrow-bandwidth laser with the adjusted preset power, so as to obtain the actual photoacoustic signal intensity of the characteristic gas in the gas sample to be measured.

The control unit 205 is further configured to determine the actual concentration corresponding to the actual photoacoustic signal intensity according to a correspondence between a gas concentration, a narrow bandwidth laser power, and a photoacoustic signal intensity.

It should be noted that, dynamically adjusting the preset power refers to adjusting the preset power within a certain numerical range, each preset power obtains a corresponding second photoacoustic signal intensity during the adjustment process, and the adjustment is stopped until the second photoacoustic signal intensity is the same as the standard photoacoustic signal intensity, and at this time, the preset power corresponding to the second photoacoustic signal intensity is the corrected preset power.

It can be understood that, when the oil-gas detection device 20 of the oil-immersed apparatus works, if the preset power is a megawatt, at this time, when the characteristic gas with the standard concentration in the standard gas sample has the narrow-bandwidth laser with the preset power, the standard photoacoustic signal intensity generated should be b millivolts, but when the power of the narrow-bandwidth laser is attenuated, the actual power of the narrow-bandwidth laser is smaller than the preset power, so that the second photoacoustic signal intensity detected at this time is only c millivolts, at this time, the control unit 205 controls the measurement unit 204 to dynamically adjust the preset power until the second photoacoustic signal intensity generated when the characteristic gas with the standard concentration in the standard gas sample absorbs the narrow-bandwidth laser is b millivolts, and then adjustment and correction of the preset power can be completed, so that the actual photoacoustic signal intensity generated after the characteristic gas in the gas sample to be detected absorbs the narrow-bandwidth laser with the characteristic gas absorption power of a megawatt can be obtained, thereby obtaining the actual concentration of the characteristic gas in the gas sample to be detected.

In an embodiment, the control unit 205 is further configured to determine, according to the correspondence relationship between the gas concentration, the narrow bandwidth laser power and the photoacoustic signal intensity, a sample standard concentration of the characteristic gas in the standard gas sample corresponding to the standard photoacoustic signal intensity, a sample measured concentration of the characteristic gas in the standard gas sample corresponding to the second photoacoustic signal intensity, and a measured concentration of the characteristic gas in the gas sample to be measured corresponding to the first photoacoustic signal intensity.

The control unit 205 is further configured to determine a concentration measurement error according to the sample standard concentration and the sample measurement concentration when it is determined that the second photoacoustic signal intensity is not the same as the standard photoacoustic signal intensity of the characteristic gas in the standard gas sample.

The control unit 205 is further configured to correct the measured concentration according to the concentration measurement error to obtain the actual concentration.

It can be understood that the preset power is a megawatt, the sample standard concentration of the characteristic gas in the standard gas sample is b, when the power of the narrow-bandwidth laser is attenuated, the actual power of the narrow-bandwidth laser is smaller than the preset power, which results in that the intensity of the detected second photoacoustic signal is only c millivolts, and the sample measured concentration of the characteristic gas in the standard gas sample corresponding to the intensity of the second photoacoustic signal can be obtained as d according to the correspondence between the gas concentration, the narrow-bandwidth laser power and the photoacoustic signal intensity, so that a concentration measurement error can be determined as b-d, and at this time, the control unit 205 can correct the measured concentration of the characteristic gas in the gas sample to be measured according to the concentration measurement error to obtain the actual concentration of the characteristic gas in the gas sample to be measured.

In an embodiment, the control unit 205 is further configured to determine the actual power of the narrow-bandwidth laser light corresponding to the second photoacoustic signal intensity according to a correspondence between the gas concentration, the narrow-bandwidth laser light power, and the photoacoustic signal intensity.

The control unit 205 is further configured to determine a power attenuation ratio of the laser power according to the actual power and the preset power when it is determined that the second photoacoustic signal intensity is different from the standard photoacoustic signal intensity of the characteristic gas in the standard gas sample.

The control unit 205 is further configured to send a modification enable signal to the measurement unit 204 according to the power attenuation ratio.

The measurement unit 204 is further configured to modify the preset power according to the modification enable signal.

The measuring unit 204 is further configured to control the photoacoustic spectroscopy device to re-measure the characteristic gas in the gas sample to be measured by using the narrow-bandwidth laser with the corrected preset power, so as to obtain the actual photoacoustic signal intensity of the characteristic gas in the gas sample to be measured.

The control unit 205 is further configured to determine the actual concentration corresponding to the actual photoacoustic signal intensity according to a correspondence between a gas concentration, a narrow bandwidth laser power, and a photoacoustic signal intensity.

It should be noted that, when the oil-gas detection device 20 of the oil-immersed device works, for example, the actual power requirement of the narrow bandwidth laser is 20 mw, the preset power is 20 mw, but the actual power of the narrow-bandwidth laser is only 10 mw, and the ratio of the actual power of the narrow-bandwidth laser to the preset power is 0.5, at this time, the preset power of the narrow-bandwidth laser is corrected, the preset power of the laser with high and narrow bandwidth is adjusted to make the corrected preset power be 20/0.5-40 megawatts, so that the actual power of the narrow-bandwidth laser after correction is 20 megawatts, and at the moment, the narrow-bandwidth laser with the actual power of 20 megawatts is used for re-measuring the characteristic gas in the gas sample to be measured, and obtaining the actual photoacoustic signal intensity generated after the characteristic gas in the gas sample to be detected absorbs the narrow-bandwidth laser with the power of 20 megawatts, thereby obtaining the actual concentration of the characteristic gas in the gas sample to be detected.

As shown in fig. 3, fig. 3 is a second structural schematic diagram of the oil-filled device oil-gas detection apparatus 20 provided in the embodiment of the present application.

In an embodiment, the oil and gas detection apparatus 20 further includes an alarm unit 206, where the alarm unit 206 is configured to issue an alarm.

Specifically, the control unit 205 is further configured to determine whether the second photoacoustic signal strength is lower than an alarm threshold.

If yes, the control unit 205 sends a measurement unit fault alarm to the alarm unit 206, and the alarm unit 206 sends an alarm according to the measurement unit fault alarm, and timely reminds a worker that a measurement result of the measurement unit 204 has a fault which cannot be corrected; if not, the control unit 205 determines whether the second photoacoustic signal intensity is the same as the standard photoacoustic signal intensity.

As shown in fig. 4, fig. 4 is a schematic view of a first structure of the measurement unit 204 according to the embodiment of the present application. The measurement unit 204 includes a laser unit 21, a light splitting unit 22, a first gas detection unit 23, and a second gas detection unit 24.

Specifically, the control unit 205 is further configured to send a light emission enable signal to the laser unit 21, and send a measurement enable signal to the first gas detection unit 23 and the second gas detection unit 24.

It should be noted that, when a gas sample to be measured is measured, the gas sample to be measured flows from the degassing unit 202 to the first gas detection unit 23 through the gas path unit 203, and the standard gas sample is pre-sealed in the second gas detection unit 24.

Specifically, the laser unit 21 is configured to emit a narrow bandwidth laser having a preset power and a preset wavelength according to the light emission enabling signal; the laser unit 21 may be a narrow bandwidth laser, such as a DFB laser.

Specifically, the light splitting unit 22 is configured to split the narrow bandwidth laser light into a first beam and a second beam according to a set power ratio.

It should be noted that the optical splitting unit 22 may be a coupler, and the optical splitting unit 22 may split the narrow-bandwidth laser into several paths according to a set power ratio, for example, the power of the narrow-bandwidth laser is 20 mw, the set power ratio is 1:1, and at this time, the powers of the first beam and the second beam split by the optical splitting unit 22 by the narrow-bandwidth laser are both 10 mw; the light splitting unit 22 may be a coupler.

It can be understood that the power of the first beam and the power of the second beam are both related in proportion to the power of the narrow-bandwidth laser light emitted by the laser unit 21, and therefore, after determining the power of the second beam through the strength of the second photoacoustic signal, the actual power of the narrow-bandwidth laser light and the power of the first beam can be obtained through simple scaling.

In one embodiment, the set power ratio is 1:1, i.e. the power of the first beam and the power of the second beam are the same.

In one embodiment, the light splitting unit 22 has two light outlets, and the narrow bandwidth laser light emitted by the light emitting unit is split by the light splitting unit 22 to form the first light beam and the second light beam, which are respectively emitted through the two light outlets.

Specifically, the first gas detection unit 23 is configured to receive the gas sample to be detected according to the measurement enable signal, and control the photoacoustic spectroscopy device in the first gas detection unit 23 to measure the characteristic gas in the gas sample to be detected by using the first light beam, and the photoacoustic spectroscopy device in the first gas detection unit 23 is configured to detect a first photoacoustic signal generated after the characteristic gas in the gas sample to be detected absorbs the first light beam, and feed back the first photoacoustic signal to the control unit 205.

Specifically, the second gas detecting unit 24 is configured to receive the standard gas sample, the second gas detecting unit 24 is further configured to control the photoacoustic spectroscopy device in the second gas detecting unit 24 to measure the characteristic gas in the standard gas sample by using the second light beam according to the measurement enable signal, and the photoacoustic spectroscopy device in the second gas detecting unit 24 is configured to detect that the characteristic gas in the standard gas sample generates a second photoacoustic signal after absorbing the second light beam, and feed back the second photoacoustic signal to the control unit 205.

Specifically, the control unit 205 is further configured to determine a first photoacoustic signal intensity of the characteristic gas in the gas sample to be measured and a second photoacoustic signal intensity of the characteristic gas in the standard gas sample according to the received first photoacoustic signal and the second photoacoustic signal.

Specifically, the first gas detection unit 23 includes a first photoacoustic cell 231 and a first microphone 232 disposed in the first photoacoustic cell 231; the first photoacoustic cell 231 is used for accommodating the gas sample to be detected, the first microphone 232 is used for detecting a first photoacoustic signal generated after the first photoacoustic signal is absorbed by the characteristic gas in the gas sample to be detected, and the first microphone 232 can convert a sound signal generated after the first photoacoustic signal is absorbed by the characteristic gas in the gas sample to be detected into an analog signal.

It is understood that the first photoacoustic cell 231 and the first microphone 232 form a photoacoustic spectroscopic device in the first gas detection unit 23.

Wherein the first photoacoustic cell 231 comprises a first resonant cavity 231a and a first gas inlet 231b and a first gas outlet 231c communicated with the first resonant cavity 231 a; the first resonant cavity 231a is used for accommodating the gas sample to be measured; the first gas inlet 231b may be in communication with the gas path unit 203 through a pipeline, so as to be used for introducing the gas sample to be tested in the gas path unit 203 into the first resonant cavity 231 a; the first gas outlet 231c may be communicated with the gas circuit unit 203 through a pipeline to allow a gas sample to be measured after measurement to flow into the gas circuit unit 203 from the first resonant cavity 231a, the gas sample to be measured may contain a pollutant gas which pollutes the environment, and the gas sample to be measured after measurement is discharged after being processed by the gas circuit unit 203, so as to prevent the environment from being polluted by the gas to be measured.

Wherein the first photoacoustic cell 231 has a transparent window, and the first light beam passes through the transparent window of the first photoacoustic cell 231 to enter the first resonant cavity 231 a.

Specifically, the second gas detection unit 24 includes a second photoacoustic cell 241 and a second microphone 242 disposed in the second photoacoustic cell 241; the second photoacoustic cell 241 is configured to accommodate the standard gas sample, the second microphone 242 is configured to detect a second photoacoustic signal generated after the characteristic gas in the standard gas sample absorbs the second photoacoustic signal, and the second microphone 242 may convert an acoustic signal generated after the characteristic gas in the gas sample to be detected absorbs the second photoacoustic signal into an analog signal.

It will be appreciated that the second photoacoustic cell 241 and the second microphone 242 form a photoacoustic spectroscopy device in the second gas detection cell 24.

Wherein the second photoacoustic cell 241 comprises a second resonant cavity 241a, the second resonant cavity 241a is used for accommodating the standard gas sample, and the second resonant cavity 241a is sealed.

Wherein the photoacoustic cell also has a transparent window, and the second light beam passes through the transparent window of the second photoacoustic cell 241 to enter the second resonant cavity 241 a.

In an embodiment, the measurement unit 204 further includes a collimation unit 25, and the collimation unit 25 is configured to perform a collimation and aggregation process on the first light beam and the second light beam emitted from the light splitting unit 22, control the first light beam to enter the first gas detection unit 23, and control the second light beam to enter the second gas detection unit 24.

The collimating unit 25 may include a first collimator 251 for performing a collimating and converging process on the first light beam and a second collimator 252 for performing a collimating and converging process on the second light beam.

In one embodiment, the laser unit 21 includes a temperature control unit 211 and a laser assembly 212.

In particular, the laser assembly 212 is configured to emit a narrow bandwidth laser.

Specifically, the temperature control unit 211 is configured to receive the light-emitting enable signal sent by the control unit 205, and control the laser module 212 to emit the narrow-bandwidth laser corresponding to each temperature-controlled temperature under the control of a plurality of temperature-controlled temperatures according to the light-emitting enable signal.

Specifically, the control unit 205 is further configured to record a first photoacoustic signal intensity corresponding to each temperature-controlled temperature, and record a temperature-controlled temperature corresponding to the maximum first photoacoustic signal intensity as a preset temperature, where the preset temperature corresponds to the preset wavelength.

Specifically, the control unit 205 is further configured to send a light emitting enable signal corresponding to the preset temperature to the temperature control unit 211.

Specifically, the temperature control unit 212 is further configured to control the laser assembly 211 to emit a narrow-bandwidth laser with a preset power and a preset wavelength under the control of the preset temperature according to a light-emitting enable signal corresponding to the preset temperature.

It should be noted that, in the laser unit 21, such as a DFB laser, the temperature control unit 211 may control the temperature of the laser component 212, the laser component 212 includes a bragg grating and a medium formed by a semiconductor material, and by changing the temperature of the medium, the wavelength of the narrow-bandwidth laser light emitted by the DFB laser can be changed, so that the temperature of the medium can be controlled, so that the DFB laser emits the narrow-bandwidth laser light with a set wavelength, and the temperature control temperature of the medium corresponds to the wavelength of the narrow-bandwidth laser light emitted by the DFB laser one-to-one, whereas under the condition that the power of the narrow-bandwidth laser light and the concentration of the characteristic gas are not changed, the wavelength of the narrow-bandwidth laser light is closer to the absorption peak of the characteristic gas, the intensity of the photoacoustic signal generated by the characteristic gas is higher, and when the first photoacoustic signal intensity is maximum, the temperature at this time is recorded as the preset temperature, and the preset, at the moment, the preset wavelength of the narrow-bandwidth laser is closest to the absorption peak of the characteristic gas in the gas sample to be measured, so that the intensity of the photoacoustic signal generated when the characteristic gas in the gas sample to be measured absorbs the narrow-bandwidth laser with the preset wavelength is higher, and the measurement precision is improved.

Referring to fig. 5 and fig. 6, fig. 5 is a schematic structural diagram of a temperature control unit 211 provided in the embodiment of the present application, and fig. 6 is a schematic diagram of a temperature adjusting circuit in the temperature control unit 211 provided in the embodiment of the present application, where the temperature control unit 211 is used for adjusting and controlling the temperature of the laser element 212.

In one embodiment, the temperature control unit 211 includes a voltage controller 211a, a voltage regulator 211b, a voltage comparator 211c, a micro-program controller 211d, and a temperature regulator 211 f. The voltage controller 211a, the voltage stabilizer 211b, the voltage comparator 211c, and the micro-program controller 211d constitute a temperature adjusting circuit TC of the temperature control unit 211.

Specifically, the voltage controller 211a is configured to provide a reference voltage, where the reference voltage is an optimal value of a preset effective operating voltage of the laser assembly 212, that is, when the effective operating voltage of the laser assembly 212 is equal to the reference voltage, the laser assembly 212 may emit a narrow-bandwidth laser with a set frequency and a set power, so as to be used for detecting the concentration of the characteristic gas in the gas sample to be measured, so that the measurement accuracy and the sensitivity of the measurement unit 204 are both optimal; furthermore, the closer the effective operating voltage of the laser assembly 212 is to the reference voltage, the higher the accuracy and sensitivity of the measurement unit 204 to the concentration measurement of the characteristic gas.

The input end of the voltage stabilizer 211b is electrically connected to the output end of the voltage controller 211a, and is configured to stabilize the reference voltage provided by the voltage controller 211a, eliminate fluctuation of the reference voltage, and improve stability and consistency of the reference voltage.

The first input terminal of the voltage comparator 211c is electrically connected to the output terminal of the voltage regulator 211b, the second input terminal of the voltage comparator 211c is electrically connected to the output terminal of the voltage obtaining module 211g, and the voltage comparator 211c is configured to compare the effective working voltage of the laser device 212 with the voltage value of the reference voltage provided by the voltage controller 211a, and transmit the comparison result to the micro-program controller 211 d.

The input end of the micro-program controller 211d is electrically connected with the output end of the voltage comparator 211c, and is used for receiving and analyzing the comparison result and sending a corresponding temperature regulation instruction to the temperature regulator 211f according to the comparison result; specifically, when the comparison result is that the effective working voltage of the laser component 212 is smaller than the reference voltage, the micro-program controller 211d sends a temperature adjustment instruction for reducing the temperature of the laser component 212 to the temperature adjuster 211 f; when the comparison result is that the effective working voltage of the laser component 212 is greater than the reference voltage, the micro-program controller 211d sends a temperature adjusting instruction for increasing the temperature of the laser component 212 to the temperature adjuster 211 f; when the comparison result is that the effective working voltage of the laser component 212 is equal to the reference voltage, the micro-program controller 211d sends a temperature adjustment instruction for maintaining the temperature of the laser component 212 to the temperature adjuster 211 f. The input end of the temperature regulator 211f is electrically connected to the output end of the micro-program controller 211d, and is configured to regulate and control the temperature of the laser assembly 212 under the control of the temperature regulating instruction, so that the laser assembly 212 works within a preset temperature range.

In an embodiment, as shown in fig. 7, fig. 7 is a schematic diagram of a second structure of a measurement unit 204 provided in an embodiment of the present application, where the measurement unit 204 includes a plurality of non-interfering gas detection units 26.

Specifically, the gas circuit unit 203 is configured to control the gas sample to be detected to flow into all the gas detection units 26 from the gas circuit unit 203 according to the measurement enable signal.

The gas detection unit 26 is configured to measure the concentration of the characteristic gas to be detected by the gas detection unit 26 using a narrow-bandwidth laser corresponding to the characteristic gas according to the measurement enable signal.

The characteristic gas to be measured by the gas detection unit 26 refers to the characteristic gas to be measured by the gas detection unit 26; the gas detection unit 26 controls the photoacoustic spectroscopy device in the gas detection unit 26 to use a narrow-bandwidth laser corresponding to the characteristic gas to be measured by the gas detection unit 26 according to the measurement enable signal.

It should be noted that, each gas detection unit 26 can independently realize the measurement of a characteristic gas, all pour into the gas sample that awaits measuring in a plurality of gas detection units 26, can utilize a plurality of gas detection units 26 of mutual noninterference to measure the characteristic gas in the gas sample that awaits measuring simultaneously, different kinds of characteristic gas correspond with the narrow bandwidth laser of different wavelengths, different gas detection units 26 can use the narrow bandwidth laser of different wavelengths to measure different kinds of characteristic gas in the gas sample that awaits measuring to can measure the concentration of multiple characteristic gas in the gas sample that awaits measuring simultaneously.

In one embodiment, a plurality of the gas detection units 26 are connected in series, which may also be understood as a plurality of the gas detection units 26 connected in cascade; the gas circuit unit 203 is configured to control the gas sample to be detected to sequentially flow into all the gas detection units 26 from the gas circuit unit 203 according to the measurement enabling signal.

The gas detection units 26 in two adjacent stages are communicated through a connecting pipe 271, and a valve is arranged on the connecting pipe 271, so that a gas sample to be detected can flow into the gas detection units 26 in sequence, and meanwhile, all the gas detection units 26 can be ensured not to be interfered with each other.

It should be noted that each gas detection unit 26 is provided with a gas inlet 261 and a gas outlet 262, when the measurement unit 204 includes m gas detection units 26, the m gas detection units 26 are connected in cascade, and the gas inlet 261 of the first-stage gas detection unit 26 may also be communicated with the gas path unit 203 through a connecting pipe 271 provided with a valve, so as to be used for accessing the gas sample to be detected flowing out from the gas path unit 203; after the gas sample to be detected flows into the first-stage gas detection unit 26, the gas sample to be detected sequentially flows into all the gas detection units 26 through the connecting pipe 271; the gas outlet 262 of the last gas detection unit 26 can also be communicated with the gas circuit unit 203 through a connecting pipe 271 provided with a valve, so that a gas sample to be detected after measurement is flowed into the gas circuit unit 203 from the gas detection unit 26, and the gas sample to be detected after measurement is discharged after being processed by the gas circuit unit 203, thereby avoiding the pollution of the gas to be detected to the environment.

The gas inlet 261 and the gas outlet 262 may be located on the same side of the gas detection unit 26, so that the gas detection units 26 in two adjacent stages are communicated through a connecting pipe 271.

Referring to fig. 8, fig. 8 is a schematic structural diagram of a third measurement unit 204 according to an embodiment of the present disclosure.

In one embodiment, the measurement unit 204 further includes a housing 272, and all of the gas sensing units 26 are disposed within the housing 272.

In one embodiment, the box 272 may have a square structure, a plurality of slide rails 273 for supporting the gas detection unit 26 are disposed on an inner wall of the box 272, the plurality of slide rails 273 are arranged at intervals along a height direction of the box 272, and the gas detection units 26 correspond to the slide rails 273 one by one; the gas detection unit 26 and the slide rail 273 are connected in a sliding manner along the length direction of the slide rail 273, so that the gas detection unit 26 can be maintained and replaced, if one gas detection unit 26 fails, a worker can pull out the gas detection unit 26 from the box 272 for maintenance, and when the gas detection unit 26 cannot be repaired, the gas detection unit 26 with normal functions can be used for replacing the failed gas detection unit 26, so that the measurement unit 204 cannot work when a single gas detection unit 26 fails.

In an embodiment, the box 272 is further provided with an interface 274, at least one of the interfaces 274 is connected to the control unit 205, the gas detection unit 26 is provided with a connector 275 matched with the interface 274, and the connector 275 is inserted into the interface 274. An information interaction bridge is set up through the butt joint of the interface 274 and the joint 275, so that information interaction between the control unit 205 and the gas detection unit 26 is realized, and therefore control of the control unit 205 on the gas detection unit 26 and information feedback of the gas detection unit 26 on the control unit 205 are realized.

In one embodiment, each gas detection unit 26 includes a separate laser for emitting a narrow bandwidth laser, which may be a narrow bandwidth laser, such as a DFB laser, based on the emission enable signal sent by the control unit 205.

Wherein, all the gas detecting units 26 can be used to simultaneously use the corresponding lasers to output the narrow-bandwidth laser light corresponding to each characteristic gas to measure the concentration of the corresponding characteristic gas, so as to improve the detection efficiency.

In one embodiment, referring to fig. 9 to 13, the measurement unit 204 further includes a signal processing circuit including a photoelectric conversion circuit 281, a first signal amplification circuit 282, a band-pass filter circuit 283, a second signal amplification circuit 284, and an a/D conversion circuit 285.

Fig. 9 is a schematic circuit diagram of a photoelectric conversion circuit of an oil-gas detection device of an oil-immersed device according to an embodiment of the present application; the photoelectric conversion circuit 281 is configured to convert an optical signal into an electrical signal, where the electrical signal is an analog signal, and the photoelectric conversion circuit 281 includes an integrated circuit LTC6268, where the integrated circuit LTC6268 converts a phase change of the optical signal into a phase change before and after the analog signal together with each circuit element, and then converts the phase change before and after the analog signal into a concentration of the characteristic gas through subsequent processing of the circuit unit.

Fig. 10 is a schematic circuit diagram of a first signal amplification circuit of an oil-gas detection device of an oil-immersed device according to an embodiment of the present application; the first signal amplifying circuit 282 is connected to the output end of the photoelectric conversion circuit 281, and is configured to amplify the analog quantity of the optical signal, since the analog quantity of the optical signal is weak, the optical signal can be further processed conveniently after being amplified, and the amplifier of the first signal amplifying circuit 282 employs AD 8629.

FIG. 11 is a schematic circuit diagram of a band-pass filter circuit of the oil-gas detection device of the oil-immersed equipment according to the embodiment of the present application; the input terminal of the band-pass filter 283 is connected to the output terminal of the first signal amplifier 282, the band-pass filter 283 is used for filtering the signal outputted from the first signal amplifier 282 for the purpose of filtering out unnecessary high-frequency and low-frequency signals and extracting a useful intermediate-frequency signal, and the band-pass filter 283 is an integrated circuit LT 1067.

Fig. 12 is a schematic circuit diagram of a second signal amplification circuit of the oil-gas detection device of the oil-immersed device according to the embodiment of the present application; the input end of the second signal amplifying circuit 284 is connected to the output end of the band-pass filter circuit 283, and the output signal of the band-pass filter circuit 283 is amplified and transmitted to the a/D conversion circuit 285, which is equivalent to a secondary amplification signal, in order to make the signal obtained by the a/D conversion circuit 285 more accurate and more convenient for conversion, the second signal amplifying circuit 284 also adopts an integrated circuit LT 1067.

FIG. 13 is a schematic circuit diagram of an A/D conversion circuit of the oil-gas detection device of the oil-immersed device according to the embodiment of the present application; the input terminal of the a/D conversion circuit 285 is connected to the output terminal of the second signal amplification circuit 284, and is used to convert the analog quantity output by the second signal amplification circuit 284 into a digital quantity, that is, a process of changing discrete quantity into continuous quantity, so as to use the integrated circuit AD7980 for the a/D conversion circuit 285.

As shown in fig. 14, fig. 14 is a third schematic structural diagram of the oil-filled device oil-gas detection apparatus 20 provided in the embodiment of the present application.

In one embodiment, the process of separating oil from gas by headspace degassing of a cooling oil sample comprises four stages.

In the first stage, the pressure in the oil tank 201a is pumped to the first target pressure, so that a negative pressure is formed between the oil-filled device 10 and the oil tank 201a, and the cooled oil sample in the oil-filled device 10 enters the oil tank 201 a. First, the control unit 205 controls the driving piston 2021b of the first driving motor 2021a in the air extractor 2021 in the degassing unit 202 to suck the gas in the oil tank 201a into the cylinder 2021c in the air extractor 2021, and discharges the gas in the cylinder 2021c through the X of the air passage unit 203 to form a negative pressure in the oil tank 201 a.

The air path unit 203 includes a first air valve 2031, a second air valve 2032, a third air valve 2033, and a fourth air valve 2034. For example, the first port 2031a and the second port 2031b of the first air valve 2031 are communicated, the air extracting device 2021 extracts part of the air in the oil tank 201a into the cylinder 2021c, then the first port 2031a and the third port 2031c of the first air valve 2031 are communicated, and the air in the cylinder 2021c is exhausted through the third air valve 2033. The above steps are repeated, so that the pressure in the oil tank 201a is reduced to a first target pressure, for example, the outside atmospheric pressure is 100Kpa, the first target pressure in the oil tank 201a may be 2Kpa, and the pressure in the oil tank 201a may be directly obtained by the pressure sensor 201 d.

In a second phase, a pressure difference between the oil tank 201a and the oil-filled device 10 causes a cooling oil sample inside the oil-filled device 10 to enter said oil tank 201 a. First, the control unit 205 controls the first valve 2035 to open so as to communicate the oil-filled device 10 with the oil tank 201a, and the cooling oil sample in the oil-filled device 10 enters the oil tank 201a due to a pressure difference between the oil-filled device 10 and the oil tank 201 a; when the cooling oil sample in the oil tank 201a reaches the height measured by the upper level sensor 201b, the control unit 205 controls the first valve 2035 to be closed. The height of the upper liquid level sensor 201b may be set according to the height of the oil tank 201a, for example, the height of the upper liquid level sensor 201b may be 75% of the height of the oil tank 201a, or the height of the upper liquid level sensor 201b may be set according to the stirring speed of the stirring member 2022 in the oil tank 201a, for example, when the stirring speed of the stirring member 2022 is 2400rpm, the height of the upper liquid level sensor 201b may be 75% of the height of the oil tank 201a, and when the stirring speed of the stirring member 2022 is 3000rpm, the height of the upper liquid level sensor 201b may be 70% of the height of the oil tank 201a, so as to avoid that the liquid level exceeds the critical height of the oil tank 201a when the cooling oil sample is stirred due to the excessively fast rotation speed of the stirring member 2022; alternatively, the height of the upper liquid level sensor 201b may be set according to the stirring temperature of the cooling oil sample in the oil tank 201a, and for example, when the stirring temperature of the cooling oil sample is 50 ℃, the height of the upper liquid level sensor 201b may be 75% of the height of the oil tank 201a, and when the stirring temperature of the cooling oil sample is 70 ℃, the height of the upper liquid level sensor 201b may be 70% of the height of the oil tank 201 a.

In the third stage, the gas to be measured in the cooling oil sample enters the measurement unit 204 through the pumping device 2021 and the gas circuit unit 203. First, the control unit 205 controls the first port 2031a and the second port 2031b of the first air valve 2031 to communicate with the air extracting device 2021 and the oil tank 201a, then the control unit 205 controls the stirring member 2022 to stir the cooling oil sample in the oil tank 201a, then the air extracting device 2021 pumps the gas to be measured in the cooling oil sample into the air cylinder 2021c in the air extracting device 2021, then the control unit 205 controls the first port 2031a and the second port 2031b of the first air valve 2031 to be disconnected, and controls the first port 2031a and the third port 2031c of the first air valve 2031 to communicate, opens the second air valve 2032 and the fourth air valve 2034, closes the third air valve 2033, so that the gas sample to be measured enters the measurement unit 204 through the air circuit unit 203; next, the above steps are repeated until the pressure in the oil tank 201a reaches the second target pressure, the above air suction step is stopped, and the first air valve 2031 is in a closed state. The second target pressure may be equal to or different from the first target pressure, and the specific value of the second target pressure may be defined according to actual conditions.

In a fourth phase, the cooling oil sample in the oil tank 201a flows back into the oil-filled device 10. First, the control unit 205 controls the second valve 2036 to open to communicate the inside of the oil-filled device 10 with the oil tank 201a, then controls the oil pump to pump the cooling oil sample in the oil tank 201a into the oil-filled device 10, and when the liquid level of the cooling oil sample in the oil tank 201a reaches the height measured by the lower liquid level sensor 201c in the oil tank 201a, the control unit 205 controls the oil pump to stop operating and the second valve 2036 to close. The height measured by the lower liquid level sensor 201c may be the bottom end of the oil tank 201a, and the specific position is not limited in detail in this application.

According to the operation process of the oil-gas detection device 20 of the oil-immersed device, since the gas to be detected in the oil tank 201a needs to be degassed within the target degassing time, the stirring speed of the stirring member 2022 directly affects the degassing rate of the gas to be detected. For sample oil with different viscosity or temperature and at different stirring speed, the degassing rate of the gas to be detected in the sample oil separating from the oil-gas separation device in the oil-immersed device oil-gas detection device 20 is different. The conventional oil-gas detection device 20 for the oil-gas separation device cannot accurately set the stirring speed of the stirring component 2022 in the oil-gas separation device, so that the gas to be detected in the sample oil cannot be separated from the oil-gas separation device within a target time. The present embodiment determines the first stirring speed of the stirring member 2022 mainly by the predicted concentration of the gas to be measured in the cooling oil sample.

In an embodiment, the concentration value of the characteristic gas actually obtained by the measurement unit 204 is generally larger than the initial predicted concentration due to various uncertain factors, and since the cooling oil samples belong to the same batch of cooling oil samples, the stirring speed of the stirring member 2022 of the next cycle can be adjusted according to the difference between the concentration value of the characteristic gas of the current cycle and the predicted concentration, and the step can include: acquiring a first difference value between the concentration of the characteristic gas in the current measurement period and the predicted concentration of the gas to be measured in the cooling oil sample; judging whether the first difference value is larger than a first threshold value or not; if the first difference is greater than the first threshold, determining a second stirring speed of the stirring member 2022 for the next measurement period based on the first difference and the target degassing time according to the correlation between the concentration, the degassing time, and the stirring speed; if the first difference is smaller than the first threshold, the first stirring speed of the stirring element 2022 is the target stirring speed of the stirring element 2022 in the current measurement period.

In one embodiment, when a first difference between the concentration of the characteristic gas in the current measurement period and the predicted concentration of the gas to be measured in the cooling oil sample is greater than a first threshold, the stirring speed needs to be adjusted, and the stirring speed of the stirring component 2022 has an upper limit of increase, i.e., a critical stirring speed, and if a difference between the concentration of the characteristic gas in the current measurement period and the predicted concentration of the gas to be measured in the cooling oil sample is greater, the stirring speed of the stirring component 2022 needs to be increased to a second stirring speed that exceeds the critical stirring speed, the limitation of the stirring speed needs to be compensated by adjusting other adjustment factors.

Specifically, in this embodiment, through the relationship between the temperature and the stirring speed, in the case that the stirring speed cannot be increased, the stirring temperature of the stirring member 2022, that is, the temperature of the cooling oil sample, is adjusted to compensate for the limitation of the stirring speed, and the step may include: judging whether the second stirring speed is greater than the critical stirring speed of the stirring member 2022; if the second stirring speed is greater than the critical stirring speed of the stirring element 2022, which is the target stirring speed of the stirring element 2022 in the next measurement period, determining the initial temperature of the cooling oil sample in the next measurement period based on the critical stirring speed and the concentration of the characteristic gas according to the correlation between the temperature, the concentration and the stirring speed; if the second stirring speed is less than the critical stirring speed of the stirring element 2022, the second stirring speed is the target stirring speed of the stirring element 2022 in the next measurement period.

In one embodiment, when a first difference between the concentration of the characteristic gas and the predicted concentration of the gas to be measured in the cooling oil sample in the current measurement period is greater than a first threshold value, the stirring speed needs to be adjusted; and after the stirring speed of the stirring member 2022 is increased, the liquid level of the cooling oil sample in the corresponding oil tank 201a will increase, and since the oil tank 201a is connected to the corresponding oil-gas pipeline, the increase of the liquid level of the cooling oil sample may cause the cooling oil sample to enter other devices through the oil-gas pipeline, so that the cooling oil sample in the oil tank 201a has a critical liquid level to avoid the cooling oil sample entering other components, and therefore the step may include: acquiring the liquid level height of the cooling oil sample in the current measurement period; judging whether the liquid level height of the cooling oil sample is larger than the critical liquid level height of the cooling oil sample; if the liquid level height of the cooling oil sample is greater than the critical liquid level height of the cooling oil sample, which is the liquid level height of the cooling oil sample in the next measurement period, determining the stirring speed of the stirring component 2022 in the next measurement period based on the critical liquid level height and the concentration of the characteristic gas according to the correlation between the liquid level height, the concentration and the stirring speed; if the liquid level height of the cooling oil sample is less than the critical liquid level height of the cooling oil sample, the second stirring speed is the target stirring speed of the stirring member 2022 in the next measurement period.

In one embodiment, the degassing time of the current measurement cycle is also an important reference value set for the stirring speed, the degassing time represents the degassing rate of the gas to be measured in the cooling oil sample, the degassing time is short, the degassing rate of the gas to be measured is high, and the stirring speed of the next measurement cycle needs to be reduced corresponding to the higher stirring speed so that the degassing time of the gas to be measured is equal to the target degassing time; if the degassing time is long, the degassing rate of the gas to be measured is small, and the stirring speed of the next measurement period needs to be increased corresponding to a smaller stirring speed, so that the degassing time of the gas to be measured is equal to the target degassing time, and therefore the step may include: acquiring the degassing time of the gas to be measured in the cooling oil sample in the current measurement period; judging whether the degassing time in the current measurement period is equal to the target degassing time or not; if the degassing time in the current measurement period is not equal to the target degassing time, the stirring speed of the stirring member 2022 in the next measurement period is determined based on the concentration of the characteristic gas in the current measurement period and the target degassing time according to the correlation among the concentration, the degassing time and the stirring speed.

In an embodiment, the pumping pressure and the pumping speed of the pumping device 2021 in the oil tank 201a can also be used as variables for adjusting the degassing speed, which will not be described in detail herein.

In this step, the concentration of the characteristic gas in the gas sample to be measured, which is obtained by the measurement unit 204, is compared with the predicted concentration of the gas to be measured, and the stirring speed or/and temperature and the like in the next measurement period are adjusted according to the difference between the two concentrations, so that the gas to be measured in the cooling oil sample in the next measurement period is separated from the degassing unit 202 within the target degassing time.

In the foregoing embodiments, the descriptions of the respective embodiments have respective emphasis, and for parts that are not described in detail in a certain embodiment, reference may be made to related descriptions of other embodiments.

The principle and the implementation of the present application are explained by applying specific examples, and the above description of the embodiments is only used to help understanding the technical solution and the core idea of the present application; those of ordinary skill in the art will understand that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; such modifications or substitutions do not depart from the spirit and scope of the present disclosure as defined by the appended claims.

Claims (10)

1. The utility model provides an oil-immersed equipment oil gas detection device which characterized in that, includes the control unit, oil circuit unit, degasification unit, gas circuit unit and measuring unit, wherein:

the control unit is used for sending a sampling enabling signal, a degassing enabling signal and a measurement enabling signal;

the oil circuit unit is used for receiving the sampling enabling signal and the degassing enabling signal, and is also used for acquiring a cooling oil sample from the oil-immersed equipment according to the sampling enabling signal and controlling the cooling oil sample to flow into the degassing unit according to the degassing enabling signal;

the degassing unit is used for receiving the degassing enabling signal and the measurement enabling signal, degassing the cooling oil sample according to the degassing enabling signal to obtain a gas sample to be measured, and controlling the gas sample to be measured to flow into the gas circuit unit according to the measurement enabling signal;

the gas circuit unit is used for receiving the measurement enabling signal and controlling the gas sample to be measured to flow into the measuring unit from the gas circuit unit according to the measurement enabling signal;

the measurement unit is used for receiving the measurement enabling signal, and controlling a photoacoustic spectroscopy device in the measurement unit according to the measurement enabling signal to respectively measure a first photoacoustic signal of a characteristic gas in the gas sample to be measured and a second photoacoustic signal of the characteristic gas in a standard gas sample by using narrow-bandwidth laser with preset power and preset wavelength, and feeding the first photoacoustic signal and the second photoacoustic signal back to the control unit;

the control unit is further used for determining a first photoacoustic signal intensity of the characteristic gas in the gas sample to be measured and a second photoacoustic signal intensity of the characteristic gas in the standard gas sample according to the first photoacoustic signal and the second photoacoustic signal, and obtaining the actual concentration of the characteristic gas in the gas sample to be measured according to the second photoacoustic signal intensity, the standard photoacoustic signal intensity of the characteristic gas in the standard gas sample and the first photoacoustic signal intensity;

the control unit is further used for determining the operation fault type of the oil-immersed device according to the actual concentration.

2. The oil-filled device hydrocarbon detection device of claim 1, wherein:

the control unit is further used for determining a photoacoustic signal intensity attenuation value caused by power attenuation of narrow-bandwidth laser light under the standard concentration of the sample according to the second photoacoustic signal intensity and the standard photoacoustic signal intensity when the second photoacoustic signal intensity is judged to be different from the standard photoacoustic signal intensity of the characteristic gas in the standard gas sample;

the control unit is further used for determining the narrow-bandwidth laser power attenuation value according to the corresponding relation between the gas concentration, the narrow-bandwidth laser power attenuation value and the photoacoustic signal intensity attenuation value;

the control unit is further configured to send a correction enable signal to the measurement unit according to the narrow bandwidth laser power attenuation value;

the measuring unit is further used for correcting the preset power according to the correction enabling signal;

the measuring unit is further used for controlling the photoacoustic spectroscopy device to use the narrow-bandwidth laser with the corrected preset power to measure the characteristic gas in the gas sample to be measured again so as to obtain the actual photoacoustic signal intensity of the characteristic gas in the gas sample to be measured;

the control unit is further configured to determine the actual concentration corresponding to the actual photoacoustic signal intensity according to a correspondence between a gas concentration, a narrow bandwidth laser power, and the photoacoustic signal intensity.

3. The oil-filled device hydrocarbon detection device of claim 1, wherein:

the control unit is further used for sending an adjustment enabling signal to the measuring unit when the second photoacoustic signal strength is judged to be different from the standard photoacoustic signal strength of the characteristic gas in the standard gas sample;

the measuring unit is further used for dynamically adjusting the preset power according to the adjustment enabling signal until the intensity of the second photoacoustic signal is the same as that of the standard photoacoustic signal;

the measuring unit is further used for controlling the photoacoustic spectroscopy device to use the narrow-bandwidth laser with the adjusted preset power to measure the characteristic gas in the gas sample to be measured again so as to obtain the actual photoacoustic signal intensity of the characteristic gas in the gas sample to be measured;

the control unit is further configured to determine the actual concentration corresponding to the actual photoacoustic signal intensity according to a correspondence between a gas concentration, a narrow bandwidth laser power, and the photoacoustic signal intensity.

4. The oil-filled device hydrocarbon detection device of claim 1, wherein:

the control unit is further configured to determine, according to a correspondence between a gas concentration, a narrow bandwidth laser power, and a photoacoustic signal intensity, a sample standard concentration of a characteristic gas in a standard gas sample corresponding to the standard photoacoustic signal intensity, a sample measurement concentration of the characteristic gas in the standard gas sample corresponding to the second photoacoustic signal intensity, and a measurement concentration of the characteristic gas in the gas sample to be measured corresponding to the first photoacoustic signal intensity;

the control unit is further used for determining a concentration measurement error according to the sample standard concentration and the sample measurement concentration when the second photoacoustic signal intensity is judged to be different from the standard photoacoustic signal intensity of the characteristic gas in the standard gas sample;

and the control unit is also used for correcting the measured concentration according to the concentration measurement error to obtain the actual concentration.

5. The oil-filled device hydrocarbon detection device of claim 1, wherein:

the control unit is further configured to determine an actual power of the narrow-bandwidth laser corresponding to the second photoacoustic signal intensity according to a correspondence between a gas concentration, a narrow-bandwidth laser power, and a photoacoustic signal intensity;

the control unit is further used for determining a power attenuation ratio of the laser power according to the actual power and the preset power when the second photoacoustic signal intensity is judged to be different from the standard photoacoustic signal intensity of the characteristic gas in the standard gas sample;

the control unit is also used for sending a correction enabling signal to the measuring unit according to the power attenuation ratio;

the measuring unit is further used for correcting the preset power according to the correction enabling signal;

the measuring unit is further used for controlling the photoacoustic spectroscopy device to use the narrow-bandwidth laser with the corrected preset power to measure the characteristic gas in the gas sample to be measured again so as to obtain the actual photoacoustic signal intensity of the characteristic gas in the gas sample to be measured;

the control unit is further configured to determine the actual concentration corresponding to the actual photoacoustic signal intensity according to a correspondence between a gas concentration, a narrow bandwidth laser power, and the photoacoustic signal intensity.

6. The oil-filled device oil-gas detection device according to claim 1, wherein the measurement unit comprises a laser unit, a light splitting unit, a first gas detection unit and a second gas detection unit, wherein:

the control unit is also used for sending a light-emitting enabling signal to the laser unit and sending a measurement enabling signal to the first gas detection unit and the second gas detection unit;

the laser unit is used for emitting narrow-bandwidth laser with preset power and preset wavelength according to the light-emitting enabling signal;

the light splitting unit is used for splitting the narrow-bandwidth laser into a first light beam and a second light beam according to a set power proportion;

the first gas detection unit is used for receiving the gas sample to be detected according to the measurement enabling signal and controlling a photoacoustic spectroscopy device in the first gas detection unit to measure the characteristic gas in the gas sample to be detected by using the first light beam, and the photoacoustic spectroscopy device in the first gas detection unit is used for detecting a first photoacoustic signal generated after the characteristic gas in the gas sample to be detected absorbs the first light beam and feeding back the first photoacoustic signal to the control unit;

the second gas detection unit is used for accommodating the standard gas sample, the second gas detection unit is further used for controlling the photoacoustic spectroscopy device in the second gas detection unit to measure the characteristic gas in the standard gas sample by using the second light beam according to the measurement enabling signal, and the photoacoustic spectroscopy device in the second gas detection unit is used for detecting that the characteristic gas in the standard gas sample generates a second photoacoustic signal after absorbing the second light beam and feeding the second photoacoustic signal back to the control unit;

the control unit is further used for determining a first photoacoustic signal intensity of the characteristic gas in the gas sample to be measured and a second photoacoustic signal intensity of the characteristic gas in the standard gas sample according to the received first photoacoustic signal and the second photoacoustic signal.

7. The oil-filled device hydrocarbon detection apparatus of claim 6, wherein the measurement unit further comprises a collimation unit, wherein:

the collimation unit is used for carrying out collimation polymerization treatment on the first light beam and the second light beam emitted by the light splitting unit, controlling the first light beam to be emitted into the first gas detection unit and controlling the second light beam to be emitted into the second gas detection unit.

8. The oil-filled device hydrocarbon detection device of claim 6, wherein the laser unit comprises a laser assembly and a temperature control unit, wherein:

the laser assembly is used for emitting narrow-bandwidth laser;

the temperature control unit is used for receiving the light-emitting enabling signal sent by the control unit and controlling the laser assembly to emit narrow-bandwidth laser corresponding to each temperature control temperature under the control of a plurality of temperature control temperatures according to the light-emitting enabling signal;

the control unit is further used for recording first photoacoustic signal intensity corresponding to each temperature-controlled temperature, and recording the temperature-controlled temperature corresponding to the maximum first photoacoustic signal intensity as a preset temperature, wherein the preset temperature corresponds to the preset wavelength;

the temperature control unit is further used for controlling the laser assembly to emit the narrow-bandwidth laser with the preset power and the preset wavelength under the control of the preset temperature according to the light-emitting enabling signal corresponding to the preset temperature.

9. The oil and gas detection device according to any one of claims 1 to 8, wherein:

the control unit is further configured to determine, according to a correspondence between a gas concentration, a narrow bandwidth laser power, and a photoacoustic signal intensity, a measured concentration of a characteristic gas in the to-be-measured gas sample corresponding to the first photoacoustic signal intensity, and obtain the actual concentration, when it is determined that the second photoacoustic signal intensity is the same as the standard photoacoustic signal intensity.

10. The oil-filled device hydrocarbon detection device of claim 9, further comprising an alarm unit, wherein:

the control unit is further used for judging whether the strength of the second photoacoustic signal is lower than an alarm threshold value;

if yes, the control unit sends a measurement unit fault alarm to the alarm unit;

if not, the control unit judges whether the second photoacoustic signal intensity is the same as the standard photoacoustic signal intensity.

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