CN100357763C - Resistivity and conductivity sensor used for high temperature and high pressure environment - Google Patents
Resistivity and conductivity sensor used for high temperature and high pressure environment Download PDFInfo
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- CN100357763C CN100357763C CNB2005101239241A CN200510123924A CN100357763C CN 100357763 C CN100357763 C CN 100357763C CN B2005101239241 A CNB2005101239241 A CN B2005101239241A CN 200510123924 A CN200510123924 A CN 200510123924A CN 100357763 C CN100357763 C CN 100357763C
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Abstract
The present invention relates to a resistivity and conductivity sensor used in high temperature and high pressure environments, which comprises a casing, wherein the casing is formed from an upper sealing cover and a lower sealing cover which are connected by screws or are clamped, the inner wall of the lower sealing cover is inserted or fixedly provided with an outer insulating sleeve, the inner upper part and the inner lower part of the outer insulating sleeve are provided with resistivity measuring devices and conductivity measuring devices, and the casing is provided with a fluid inlet and a fluid outlet which are used for flowing fluid. The fluid inlet and the fluid outlet are provided with three annular passages which are spaced, and sealing elements are arranged in the annular passages. First cavities communicated with the fluid inlet are formed among the resistivity measuring devices, the outer insulating sleeve and the upper sealing cover. Second cavities communicated with the first cavities are arranged in the resistivity measuring devices and the conductivity measuring devices. Third cavities communicated with the second cavities and the fluid outlet are formed among the resistivity measuring devices, the outer insulating sleeve and the sealing covers. The third cavities are connected with the fluid outlet. The present invention has the advantages of simple structure, simple installation and accurate measuring results.
Description
Technical field
The present invention relates to a kind of resistivity and conductivity sensor, in particular for the resistivity and conductivity sensor of high temperature and high pressure environment.
Background technology
Sensor is widely used in commercial production, type is various, especially the application of resistivity and/or conductivity sensor is the most general, their ultimate principle all is that it is inserted in the middle of the fluid, the resistivity of sensing fluid or conductivity, and then judge the parameter of needs according to environment for use, reach the purpose that the device of using this sensor is realized.
When carrying out oil exploitation, being most widely used of this sensor, well logging in the petroleum drilling operation (collecting and write down the process of geological information from earth depths) process is very necessary, general all is to adopt plug-in resistance rate or the conductivity sensor signal under inductively, which kind of material is size by resistivity or conductivity exist definitely down, is example with the oil, if the content of oil is higher, then resistivity is higher, and conductivity is less.In the parameter measurement pipe nipple, the resistivity sensor that adopts, generally comprise six electrodes, i.e. two emitting electrodes, two receiving electrodes and two equipotential electrodes, sensor is put into after the well by drill bit, obtain the information of mud resistivity by measurement receiving electrode voltage, and then determined whether that oil exists, determine next step production program again.And because mining environment is comparatively abominable, require the structure processing more complicated of electrode system, insulativity requires very high, and temperature sensor is set simultaneously generally, so that at any time to the temperature monitoring of detection system, the safe operation of assurance system, this temperature sensor is to constitute the test bridge by platinum-membrane resistor and super high precision resistance, obtain the temperature of mud by the resistance of measuring thermistor, because thermistor bearing requirements height, mounting structure is compact, and difficulty of processing is very big, and this has just increased cost of winning to a great extent.And generally just resistivity or conductivity are measured, can not be made judgement by very accurate material underground existence.
And existing conductivity sensor generally is to be made of the glass conductance cell of an inside with three platinum electrodes, put it in the time of use to measure conductivity of fluid in the solution, and then the composition that contains of convection cell judges.
Above-mentioned resistivity and conductivity sensor all can not adapt to the working environment of High Temperature High Pressure, thus a kind of working environment that can adapt to the harshness of High Temperature High Pressure, and can be accurately to underground contained material carry out measured sensor real for industry required.
Summary of the invention
The present invention solves resistivity of the prior art and conductivity sensor damages under high temperature and high pressure environment easily, and measure coarse technical matters, its goal of the invention provides a kind of resistivity and conductivity sensor, has the environment that structure is tight, measurement is accurate and be applicable to High Temperature High Pressure.
Technical scheme of the present invention is such:
A kind of down-hole exploration resistivity and conductivity sensor, it is inserted in the body, comprise shell, this shell by be spirally connected or engage on, lower sealing cover constitutes, be arranged at intervals with through hole on this shell for fluid flow, fluid intake and fluid egress point on described through hole and the body are complementary, described through hole and described fluid intake or fluid egress point form at least three circular passages, seal element is set in the circular passage, plug or be set with external insulation sleeve on the lower sealing cover inwall, on in the external insulation sleeve, have resistivity test device and conductivity measuring apparatus, described resistivity test device is provided with a seal element near a side of top cover labyrinth, wherein, described resistivity test device is near the seal element of top cover labyrinth, form first cavity that communicates with fluid intake between external insulation sleeve and the top cover labyrinth, the inside of resistivity test device and conductivity measuring apparatus has second cavity with the first cavity conducting, conductivity measuring apparatus, be formed with the 3rd cavity that is connected with second cavity and fluid egress point between external insulation sleeve and the lower sealing cover, described the 3rd cavity is connected with fluid egress point.
Described resistivity test device comprises insulation inner core, transmitting coil, receiving coil, shading ring and interior pressure-bearing pipe, should be located at insulation inner core outside by interior pressure-bearing pipe box, outside the pressure-bearing pipe, described shading ring was set in outside two coils in described transmitting coil and receiving coil were set in.
Described insulation inner core is a hollow tubular; The pressure-bearing pipe is nonmetallic materials in described; Described shading ring is made up of cylindrical shape shielding plate and the toroidal membrane that inwardly forms, and described receiving coil and transmitting coil are located at respectively in two cells that are made of shading ring and interior pressure-bearing pipe.
Described shading ring is arranged with the pressure-bearing cover outward, and this pressure-bearing puts and has an axial groove, is used to place the cabling that emission and receiving coil are connected with external circuit.
The sealing ring that described pressure-bearing cover and shading ring are combined closely with frictionally between insulation inner core and external insulation sleeve towards the one side of top cover labyrinth is pushed down fixing.
Described conductivity measuring apparatus comprises interior insulation sleeve, metal inner core and metal sealer, the second interior cavity of second cavity that forms between insulation sleeve and the metal sealer in described and resistivity test device is communicated with, described metal inner core and metal sealer constitute the two poles of the earth of electric capacity, the coupling of fluid through between the 3rd cavity between the two.
Described metal inner core is fixed by the insulated enclosure seat.
Described seal element is O-ring seal or sealing gasket or fluid sealant.
By above technical scheme as can be known, technique effect of the present invention is significant, this scheme is integrated at one with the sensor of resistance and conductivity, structure is tight, volume is little, and adopt metal material and good seal performance, can high temperature high voltage resistant, be specially adapted to the test of convection cell resistivity and conductivity under the high temperature hyperbaric environment such as petroleum drilling.
Description of drawings
Fig. 1 is the structure cut-open view of resistivity and conductivity sensor of the present invention.
Embodiment
The present invention proposes a kind of resistivity and conductivity sensor, be illustrated in figure 1 as the structure cut-open view of sensor of the present invention, this sensor comprises shell, resistivity test device and conductivity measuring apparatus, wherein shell includes top cover labyrinth 5 and lower sealing cover 20, and external insulation sleeve 12 compositions that are inserted in lower sealing cover 20 inwalls.The present invention in use, it need be inserted into that (this body is the parts in the pick-up unit in the body 11, be used for installing the present invention), wherein go up, respectively be provided with the fluid intake 31 of one group of four through hole on the lower sealing cover with internal cavity and body 11, fluid egress point 31 is connected, be formed with at least three circular passages (when in use on the body 11 outside fluid intake 31 and fluid egress point 32, can number of channels be set according to seal request), two stream sockets are provided with at interval, seal element is set, to guarantee that fluid is being circulated in sensor of the present invention by stream socket under the situation of High Temperature High Pressure smoothly in the circular passage.The seal element that the present invention adopts can be O-ring seal or sealing gasket or fluid sealant etc., also can realize sealing function by other existing mechanical or magnetic seal technology.
In the present embodiment, the O-ring seal of an annular is arranged all on the both sides up and down of two groups of above-mentioned through holes and the lid between them, structure of the present invention is played sealing function.In the present embodiment, be formed with cable hole on the lower sealing cover 20, be used to place the cabling that sensor leads to external circuit, this cable hole can be blocked with sealing-plug 16, to avoid circuit the being damaged assurance line security under rigorous environment such as High Temperature High Pressure.
The upper and lower part of external insulation sleeve 12 inside in the shell of the present invention is equiped with resistivity test device and conductivity measuring apparatus respectively, wherein is formed with first a cavity a who is connected with fluid intake 31 between resistivity test device, external insulation sleeve 12 and the top cover labyrinth 5; The inside of resistivity test device and conductivity measuring apparatus is formed with the second cavity b that is communicated with the first cavity a; Be formed with the 3rd cavity c that is connected with the second cavity b and fluid egress point 32 between conductivity measuring apparatus, external insulation sleeve 12 and the lower sealing cover 20.After the present invention is installed on the pick-up unit, be placed in the well, fluid can be flowed among the described first cavity a, the second cavity b and the 3rd cavity c by fluid intake 31, flow out by fluid egress point 32 again, resistivity test device and conductivity measuring apparatus can be sent to external circuit with the data of measuring by lead according to the situation of fluid, by external circuit it are handled again.
Resistivity test device described in the present invention comprises the insulation inner core 6 of tubulose, these insulation inner core 6 outer interior pressure-bearing pipes 33 that are arranged with nonmetallic materials, be used for the auxiliary pressure that bears insulation inner core 6 inner fluids, the shading ring 30 that the toroidal membrane that is inwardly formed by cylindrical shape shielding plate and its middle part that interior pressure-bearing pipe 33 is outer to be arranged with also that metal material makes is formed, in two cells that between by this shading ring 30 and interior pressure-bearing pipe 33, form transmitting coil 9 and receiving coil 10 are set respectively, the shading ring 30 outer pressure-bearing covers 8 that put again, have an axial groove on this pressure-bearing cover 8, be used to place two coils and be connected to outside cabling.The sealing ring 7 that pressure-bearing cover 8 and shading ring 30 are combined closely with frictionally between insulation inner core 6 and external insulation sleeve 12 towards the one side of top cover labyrinth 5 is pushed down, thereby is fixed.During work, the electromagnetic wave of transmitting coil 9 emissions is received by receiving coil 10 after the fluid coupling of 6 of insulation inner cores, and via line is delivered to external circuit again, and external circuit is judged to the received signal, realizes the measurement to resistivity.
Conductivity measuring apparatus among the present invention comprises interior insulation sleeve 15, should be arranged with interior seal 17 outside the interior insulation sleeve 15, sealing body 17 is to be made by metal material, seal 17 is provided with metal inner core 21, when the cavity of fluid in this conductivity measuring apparatus 3 flows, metal inner core 21 and seal 17 constitute the two poles of the earth of electric capacity, are coupled by fluid between the 3rd cavity between two electrodes of electric capacity, and then determine the size of detected conductivity of fluid according to the value of resultant electric capacity.In concrete installation process, adopt 19 pairs of metal inner cores of insulated enclosure seat to fix.
In the well logging process, adopt the present invention to carry out sensing, transmitting coil 9 launching electromagnetic waves in the resistivity test device of the present invention, electromagnetic wave is through after the coupling of liquid, receive by receiving coil 10, and this signal sent, outside treatment circuit can calculate the resistivity of fluid by analyzing the power of received signal.And conductivity measuring apparatus is the two poles of the earth that the metal inner core 21 that separated by insulating material and seal 17 have formed electric capacity in the middle of the structure of the present invention, two interpolars have fluid to flow through, the conductivity of fluid size directly has influence on the size of electric capacity, with this capacitance series in oscillatory circuit, can measure electric capacity according to oscillation frequency, thereby derive conductivity of fluid.
The described sensor of the foregoing description can be applied under the environment of High Temperature High Pressure, for example in field of oil drilling.The present invention also can be applied in the other field, according to the operating mode difference, under the High Temperature High Pressure situation, the circular passage can be set on shell when in use O-ring seal is installed, and its principle of work is same as the previously described embodiments, is not giving unnecessary details at this.
Sensor of the present invention gets final product its grafting when installing in regular turn in the enclosure, and is easy for installation, and compact conformation is easy to use in measuring process; In addition, because the resistivity that employing resistivity sensor and conductivity sensor are measured and the scope of conductivity are inequality, so the present invention combines both, structure integrates, just can when measuring, measure two parameters simultaneously,, especially be applied in the oil exploitation process to obtain accurate measurement result, measure simultaneously, improve very much the precision of measuring on the large program; Of the present invention in addition simple in structure, compactness, easy for installation, have very strong practicality.
Claims (8)
1, a kind of down-hole exploration resistivity and conductivity sensor, it is inserted in the body, comprise shell, it is characterized in that, this shell by be spirally connected or engage on, lower sealing cover constitutes, be arranged at intervals with through hole on this shell for fluid flow, fluid intake and fluid egress point on described through hole and the body are complementary, described through hole and described fluid intake or fluid egress point form at least three circular passages, seal element is set in the circular passage, plug or be set with external insulation sleeve on the lower sealing cover inwall, on in the external insulation sleeve, have resistivity test device and conductivity measuring apparatus, described resistivity test device is provided with a seal element near a side of top cover labyrinth, wherein, described resistivity test device is near the seal element of top cover labyrinth, form first cavity that communicates with fluid intake between external insulation sleeve and the top cover labyrinth, the inside of resistivity test device and conductivity measuring apparatus has second cavity with the first cavity conducting, conductivity measuring apparatus, be formed with the 3rd cavity that is connected with second cavity and fluid egress point between external insulation sleeve and the lower sealing cover, described the 3rd cavity is connected with fluid egress point.
2, exploration resistivity and conductivity sensor in down-hole according to claim 1, it is characterized in that, described resistivity test device comprises insulation inner core, transmitting coil, receiving coil, shading ring and interior pressure-bearing pipe, should be located at insulation inner core outside by interior pressure-bearing pipe box, outside the pressure-bearing pipe, described shading ring was set in outside two coils in described transmitting coil and receiving coil were set in.
3, resistivity and conductivity sensor is used in down-hole exploration according to claim 2, it is characterized in that described insulation inner core is a hollow tubular; The pressure-bearing pipe is nonmetallic materials in described; Described shading ring is made up of cylindrical shape shielding plate and the toroidal membrane that inwardly forms, and described receiving coil and transmitting coil are located at respectively in two cells that are made of shading ring and interior pressure-bearing pipe.
4, exploration resistivity and conductivity sensor in down-hole according to claim 3, it is characterized in that, described shading ring is arranged with the pressure-bearing cover outward, and this pressure-bearing puts and has an axial groove, is used to place the cabling that emission and receiving coil are connected with external circuit.
5, exploration resistivity and conductivity sensor in down-hole according to claim 4, it is characterized in that the sealing ring that described pressure-bearing cover and shading ring are combined closely with frictionally between insulation inner core and external insulation sleeve towards the one side of top cover labyrinth is pushed down fixing.
6, exploration resistivity and conductivity sensor in down-hole according to claim 1, it is characterized in that, described conductivity measuring apparatus comprises interior insulation sleeve, metal inner core and metal sealer, the second interior cavity of second cavity that forms between insulation sleeve and the metal sealer in described and resistivity test device is communicated with, described metal inner core and metal sealer constitute the two poles of the earth of electric capacity, the coupling of fluid through between the 3rd cavity between the two.
7, resistivity and conductivity sensor is used in down-hole exploration according to claim 6, it is characterized in that described metal inner core is fixed by the insulated enclosure seat.
8, resistivity and conductivity sensor is used in down-hole exploration according to claim 1, it is characterized in that described seal element is O-ring seal or sealing gasket or fluid sealant.
Priority Applications (1)
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CNB2005101239241A CN100357763C (en) | 2005-11-24 | 2005-11-24 | Resistivity and conductivity sensor used for high temperature and high pressure environment |
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CNB2005101239241A CN100357763C (en) | 2005-11-24 | 2005-11-24 | Resistivity and conductivity sensor used for high temperature and high pressure environment |
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CN100357763C true CN100357763C (en) | 2007-12-26 |
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Families Citing this family (6)
Publication number | Priority date | Publication date | Assignee | Title |
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CN102520247B (en) * | 2011-10-26 | 2014-04-02 | 中国石油集团西部钻探工程有限公司 | Slurry resistivity measuring device |
CN102426184B (en) * | 2011-11-14 | 2013-12-11 | 中国海洋石油总公司 | Conductivity sensor |
CN102809695B (en) * | 2012-08-03 | 2014-11-05 | 中国石油天然气股份有限公司 | Electrical isolation unit for measuring rock resistivity |
CN104931465B (en) * | 2014-03-21 | 2018-02-09 | 中国石油化工股份有限公司 | For the device and method for the dissolved state for monitoring the oil gas water in dissolution kettle |
WO2017091406A1 (en) * | 2015-11-25 | 2017-06-01 | Videojet Technologies Inc. | Ink quality sensor and a condition monitoring system for an inkjet printer |
CN113629652B (en) * | 2021-08-10 | 2022-11-04 | 江苏锐高捷电气科技有限公司 | High-voltage induction electricity-taking temperature-measuring insulating plug |
Citations (6)
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SU646297A1 (en) * | 1977-01-27 | 1979-02-05 | Московский Ордена Трудового Красного Знамени Геологоразведочный Институт Им.Серго Орджоникидзе | Induction well-logging apparatus |
RU2179637C1 (en) * | 2001-05-08 | 2002-02-20 | Чикин Андрей Егорович | Procedure determining characteristics of well, face zone and pool and device for its realization |
CN2479516Y (en) * | 2001-04-11 | 2002-02-27 | 西安石油勘探仪器总厂 | Cable romote transmitting logging unit |
WO2003076968A1 (en) * | 2002-03-04 | 2003-09-18 | Baker Hughes Incorporated | An apparatus and method for wellbore resistivity determination and imaging using capacitive coupling |
FR2837869A1 (en) * | 2002-04-02 | 2003-10-03 | Baker Hughes Inc | Nuclear magnetic resonance based downhole instrumentation, measures formation properties including fluid mobility, saturation level and relative permeability |
CN1559011A (en) * | 2001-08-03 | 2004-12-29 | Method and apparatus for a multi-component induction instrument measuring system for geosteering and formation resistivity data interpretation in horizontal, vertical and deviated wells |
-
2005
- 2005-11-24 CN CNB2005101239241A patent/CN100357763C/en not_active Expired - Fee Related
Patent Citations (6)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
SU646297A1 (en) * | 1977-01-27 | 1979-02-05 | Московский Ордена Трудового Красного Знамени Геологоразведочный Институт Им.Серго Орджоникидзе | Induction well-logging apparatus |
CN2479516Y (en) * | 2001-04-11 | 2002-02-27 | 西安石油勘探仪器总厂 | Cable romote transmitting logging unit |
RU2179637C1 (en) * | 2001-05-08 | 2002-02-20 | Чикин Андрей Егорович | Procedure determining characteristics of well, face zone and pool and device for its realization |
CN1559011A (en) * | 2001-08-03 | 2004-12-29 | Method and apparatus for a multi-component induction instrument measuring system for geosteering and formation resistivity data interpretation in horizontal, vertical and deviated wells | |
WO2003076968A1 (en) * | 2002-03-04 | 2003-09-18 | Baker Hughes Incorporated | An apparatus and method for wellbore resistivity determination and imaging using capacitive coupling |
FR2837869A1 (en) * | 2002-04-02 | 2003-10-03 | Baker Hughes Inc | Nuclear magnetic resonance based downhole instrumentation, measures formation properties including fluid mobility, saturation level and relative permeability |
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