• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    SUMMARY Method for determining a dielectric parameter of an electrical insulation of a power system component, comprises the following steps: determining the activation energy of the electrical insulation, determining the actual temperature (Ti) of the electrical insulation and the temperature (T2) to which the supply must be corrected, that a correction factor (Axy) is calculated by means of the Arrhenius equation, that the electrical insulation is stimulated with a DC voltage stimulation signal, that a response of the power system to the DC voltage stimulation signal is determined at the actual temperature and that the parameter of the electrical insulation at the temperature to which the supply is to be corrected based on the response modified by the correction factor. This takes into account the individual characteristics of the power system device. A device for determining a dielectric parameter of an electrical insulation of a power system component is also provided.
    公开号:SE1300282A1
    申请号:SE1300282
    申请日:2013-04-16
    公开日:2014-10-17
    发明作者:Peter Werelius;Mats Öhlen;Alan Lye Purton
    申请人:Megger Ltd;
    IPC主号:
    专利说明:

    [1] The present invention relates generally to the supply and determination of a dielectric parameter of an electrical insulation of a power system component and more specifically to a method and apparatus for determining parameters which take into account the characteristics of individual insulation properties.
    [2] Testing of the insulation system has power system components, such as transformers, rotating machines and cables, can be performed by connecting a test equipment to two conductors separated by an isolation system and exciting one conductor with the other conductor as a reference with electrical signals, either with a DC signal, an AC signal or an arbitrary waveform signal.
    [3] It is edge that an increase in temperature leads to a decrease in the insulation resistance. The temperature has a strong effect on insulation resistance feeds and the results should be corrected to a base temperature. The base temperature is usually in the range 15-40 ° C, e.g. 20 ° C.
    [4] It is also an edge to use tables with temperature correction factors with the default values to correct the results to a base temperature. However, these factors do not take into account the characteristics of the insulation properties, which may change with age with the specific device.
    [5] An object of the present invention is to provide a method and apparatus for determining power system isolation parameters, taking into account the individual characteristics of the power system device isolation. 2
    [6] According to a first aspect of the invention, there is provided a method for determining a dielectric parameter of an electrical insulation of a power system component, comprising the steps of: determining the activation energy of the electrical insulation, determining the actual temperature of the electrical insulation and the temperature to which the supply is to be corrected, that a correction factor is calculated by means of the Arrhenius equation, that the electrical insulation is stimulated with a DC voltage stimulation signal, that a response of the power system to the DC voltage stimulation signal is determined at the actual temperature and that the electrical parameter is determined. at the temperature to which the feed is to be corrected based on the response modified by the correction factor. This takes into account the individual characteristics of the power system device.
    [7] In a preferred embodiment, the step of determining the parameter is performed having the electrical insulation in the frequency domain.
    [8] [0008] In a preferred embodiment, the frequencies are shifted by the correction factor.
    [9] In a preferred embodiment, the step of determining the parameter is performed having the electrical insulation in the time domain.
    [10] In a preferred embodiment, the time is shifted by the correction factor and the amplitude is scaled for insulation resistance / current reading by the correction factor.
    [11] In a preferred embodiment, the electrical insulation comprises a single material, and wherein the parameter has the electrical insulation determined based on the response modified with the correction factor calculated based on a single activation energy.
    [12] In a preferred embodiment, the electrical insulation comprises at least two materials. 3
    [13] In a preferred embodiment, the steps of performing a feed of dielectric response as a function of time at the actual temperature of the electrical insulation are included, and dividing the feed data into data for first, second and usual additional materials.
    [14] In a preferred embodiment, the step of dividing the math data into data for the first, second and habit additional materials is performed by means of a mathematical model, such as the XY model for dielectric frequency response feeds.
    [15] In a preferred embodiment, the temperature correction is used for conventional materials, the method comprising the further step of determining the total dielectric response at the temperature to which the feed is to be corrected.
    [16] In a preferred embodiment, the dielectric parameter is any of the following: insulation resistance, dielectric absorption ratio and polarization index.
    [17] In a preferred embodiment, the power system component is any of the following: a rotating machine, a transformer, a bushing and a power cable.
    [18] In a preferred embodiment, a correction is made for several temperatures in a range to determine the temperature dependence of the dielectric parameter, preferably insulation resistance and polarization index.
    [19] According to a second aspect of the invention, there is provided a device for determining a dielectric parameter of an electrical insulation of a power system component, comprising a test control unit, a stimulator circuit arranged to stimulate the insulation of the power system component, a detector circuit arranged to detect, register and / or supply the answer has the power system component, an input device adapted to input the text value and / or the parameter value for commanding the stimulator circuit, and an output device, which is characterized in that the test control unit is arranged to control the device for performing the method according to the invention. 4
    [20] According to a third aspect of the invention, there is provided a computer program, comprising computer readable code means, which, when executed in a device, causes the device to perform the method according to the invention.
    [21] According to a fourth aspect of the invention, there is provided a computer program product comprising a computer program comprising computer readable code means, which, when executed in a device, causes the device to perform the method according to the invention.
    [22] The invention will now be described, by way of example, with reference to the accompanying drawings, in which:
    [23] Fig. 1 is a block diagram showing an apparatus according to the invention for determining power system parameters;
    [24] Fig. 2 is a diagram showing the possible temperature dependence of a material cla it is fed into the frequency domain;
    [25] Fig. 3 is a graph showing possible temperature dependence of a material cla it is fed into the time domain;
    [26] Fig. 4 is a graph showing the loss factor as a function of frequency;
    [27] FIG. 5 is a diagram showing the insulation resistance as a function of time and
    [28] Fig. 6 is a graph showing the insulation resistance at 60 seconds as a function of temperature.
    [29] In the following, a detailed description of a method and an apparatus for determining a parameter will have a power system component given.
    [30] The temperature dependence in many insulation materials can be described by the Arrhenius equations: a "= 7.0 = where kb is Boltzman's constant = 1.3806488 x -23 m2 kg s-2K-1 and Exy is the activation energy, e.g. 0.90 eV (1 eV (electron volt) = 1.60217657 x -19 joules).
    [31] A correction in the frequency domain, where CO represents the frequency, is performed as follows.
    [32] For insulation materials that follow the Arrhenius equation, Ax = Ay = Axy and sa: x (co / A „(T1, T2), Ti) (2) where x (co, T) represents the contribution to the real and imaginary part perm itivity in a single polarization process. For most insulation materials, if the conductivity can be neglected, a polarization process usually dominates the losses and the method is also valid for the measured loss factor (DF), ie: DF (0), 12) = DF (co / A (T1, T2), Ti) (3)
    [33] If DF is to be corrected to 50 Hz and 20 ° C from the feed at Ti = 40 ° C, then the feed is performed at about 485 Hz (50 / 0.103 = 485Hz). Measured DF at 11 = 40 ° C is then corrected back: (1) DF (2 * 7 * 50, 293.15) = DF (2 * 7 * 50 / 0.103, 313.15)
    [34] Or, since in this formula the angular frequency / frequency, temperature on a Celsius / Kelvin scale are the same: 6 DF (50, 20) = DF (50 / 0.103, 40) = DF (485, 40)
    [35] DF, e.g. 0.0023, matt at Ti = 40 ° C and at the frequency 485 Hz is the same as DF at the frequency 50 Hz for the temperature T2 = 20 ° C (ie also eg 0.0023). This is exemplified in Fig. 4, which shows the loss factor as a function of frequency. You can see how the carpet losses at 40 ° C are adjusted with the Arrhenius or correction factor to obtain the loss factor at 20 ° C.
    [36] A correction in the time domain is performed according to the following: f (t, T2) = Ay (T1, T2) * f (A, (T1, T2) * t, Ti)
    [37] For insulation materials that follow the Arrhenius equation, Ax = Ay = Axy and sá f (t, T2) = A (T1, T2) * f (Axy (T1, T2) * t, Ti) (4) wherein f (t, T) represents the contribution to current, scaled with voltage and the geometry of the sample, for a single polarization process. For the most insulating materials, if the conductivity can be neglected, a polarization process usually dominates current but in the time interval of interest and therefore I (t, T2) = A, y (T1, T2) * I (A (T1, T2) * t, Ti ) (5) The insulation resistance (IR) is defined as IR (t, 12) = U / 1 (t, T2) where U is kept constant. Darr & IR (t, T2) = 1 / A, y (T1, T2) * IR (Axy (T1, T2) * t, Ti) (6)
    [38] If IR is to be corrected to 60 s and 20 ° C, Ors said feeding of the insulation resistance at approx. 6.2 s (0.103 * 60 = 6.2). Measured data at Ti = 40 ° C are then corrected back: IP (60, 293.15) = 1 / 0.103 * IP (0.103 * 60, 313.15) 7 or, since the temperature in the Celsius / Kelvin scale is the same IP (60, 20) = 1 / 0.103 * IP (0.103 * 60, 40)
    [39] IR, e.g. 1.0 GOhm, matt at Ti = 40 ° C and at the time 6.2 s is the same as IR = 9.7 GOhm (1.0 GOhm / 0.103) at the time = 60 s for the temperature T2 = 20 ° C.
    [40] Referring now to Fig. 1, there is shown an apparatus for determining isolation parameters, generally designated 10. The apparatus 10 includes a test controller 11, a stimulator circuit 12, a detector circuit 13, an input device 14, an output device or display 15, and optionally a database. The device may be connected to an electrical power system device by means of a wiring or the like (not shown).
    [41] The test controller 11 may comprise a computer program comprising computer readable code means, which, when executed in a device, cause the device to perform the method described below. The test controller may also include a computer program product comprising such a computer program.
    [42] The stimulator circuit 12 stimulates or excites the isolation of the power system component during testing with a stimulation signal. For example, the stimulator circuit 12 may generate a DC voltage signal (DC voltage signal) to stimulate the component during testing.
    [43] The detector circuit 13 detects, registers and / or measures the response of the component during testing of the stimulation signal output by the stimulator 12. The detector circuit 13 may comprise one or more analog-to-digital converters for periodically recording the voltage and / or the current. output on the component during tests and other circuit arrangements to store the digital values in a memory. In one embodiment, the detector circuit 13 may also include other circuit arrangements or processing functionality for analyzing the recorded response to determine a test result parameter, e.g. polarization current, depolarization current, insulation resistance, dielectric absorption ratio and polarization index. Alternatively, the detector circuit 13 provides raw data to the test controller 11, which analyzes the raw data to determine the test result parameter.
    [44] The test controller 11 performs the test by controlling the stimulator circuit 12 and the detector circuit 13. The test controller 11 receives inputs from the input device 14 which the test controller 11 uses to define the test value and / or parameter value to command the stimulator circuit 12. The input signals may define a test temperature. and / or an ambient temperature has the environment surrounding the power system component under test.
    [45] The input device 14 may be a keyboard and / or keypad and / or touch screen. The display device 15 can be a flat display, a liquid crystal display (LCD) or another display.
    [46] The device 10 may be connected to a local AC supply and to a printer at the test site, in the field, for printing on-site test results.
    [47] A method for determining a dielectric parameter having an electrical insulation having a power system component will now be described in detail. The method described in a general manner comprises the following steps. Even if these steps are described in a specific order, it will be appreciated that the order may change without departing from the spirit of the invention.
    [48] The testing is assumed to be performed at the temperature Ti, i.e. the actual temperature of the sample, while in the following the temperature you would like to "correct" your input data to is denoted T2.
    [49] The activation energy Exy for the electrical insulation has the power system component to be tested determined. The activation energy is about 0.9 eV for oil-impregnated cellulose, such as kraft paper and press pan, and is about 0.4 - 0.5 eV Mr transformer oil. The activation energy for other materials can be found in the literature or by feeding. 9
    [50] The actual temperature Ti of the electrical insulation is also determined. This can be done in many ways known to those skilled in the art. The temperature T2 to which the supply is to be corrected is also determined. Typically, T2 = 40 ° C is used for rotary machines and T2 = 20 ° C for transformers, while T2 = 16 ° C (60 ° F) for cables.
    [51] Using the values of Exy, Ti, and T2 in the Arrhenius equation, calculate the temperature dependence or the Arrhenius factor Axy (Ti, T2) which is used as a correction factor.
    [52] The electrical isolation is stimulated with a DC voltage stimulation signal for a lamp time, such as 6.2 seconds, 60 seconds or other lamp time. The answer is that the electrical isolation of the DC voltage stimulation signal is then determined. Finally, based on the response, modified using the correction factor, the parameter of a power system component is determined.
    [53] FIG. 2 shows a possible temperature dependence of a material when it is fed into the frequency domain (AC). In the frequency domain, the frequencies are shifted by the factor Axy calculated by the Arrhenius equation based on Ti and T2 and the activation energy is given to the specific insulation material.
    [54] For example, if an oil impregnated insulation system measured at 40 ° C has a hazard factor of 0.0021 at 50 Hz and about 0.0028 at 485Hz, it will have about 0.0028 at 50 Hz and 20 ° C. 20 ° C difference meant a factor of about 1 / 0.103 in frequency father an insulation material with the activation energy 0.9 eV.
    [55] Fig. 3 shows the monthly temperature dependence of a material when it is measured in the time domain (DC). In the time domain, the same scaling factor is used as that used in the frequency domain, but the time is shifted and the amplitude is scaled for insulation resistance / tightening.
    [56] For example, the same oil-impregnated insulation system as above was measured at 40 ° C. If a food result of e.g. 1 GOhm at a time of 6.2 s, the equivalent discharge is now 9.7 GOhm (1 GOhm / 0.103) at 60 seconds (6.2 / 0.103) for 20 ° C. In other words, if an insulation resistance reading at a specific time is of interest, e.g. at 60 s at 20 ° C, and the insulation temperature is not 20 ° C, the insulation resistance is measured at another time, at which the scaling factor is determined by the temperature difference T1 - T2 and the activation energy and the insulation resistance / current are multiplied / divided by the same scaling factor. This is exemplified in Fig. 5, where the insulation resistance is shown as a function of time. The lower curve is the insulation resistance measured at 40 ° C and by adjusting it in time and scaling with the Arrhenius or correction factor, the Upper curve is obtained which represents the insulation resistance at 20 ° C.
    [57] In the example above, in which the electrical insulation comprises a single material, the parameter of the electrical insulation at T2 is determined based on the response modified by the correction factor for the single material, i.e. with a single activation energy. If the electrical insulation comprises two or more materials, the method must be applied individually for each of the two or more materials according to the following.
    [58] First, a dielectric parameter, insulation resistance (IR), polarization current or depolarization current is fed, in a time interval at the actual temperature of the insulation, T1, and dielectric response is obtained as a function of time. Then, with the help of a model, such as the known XY model for dielectric frequency response feeds, the feed data is divided into data for first, second and habit additional materials.
    [59] Using the Arrhenius factor for conventional materials, it is determined how the response is to be transformed for a given temperature change to temperature 12.
    [60] Finally, the total dielectric response is determined using the same model as when the materials were separated, e.g. The XY model, at the temperature to which the feed would be corrected.
    [61] The result can be used to calculate an equivalent dielectric parameter, e.g. insulation resistance and polarization index, for a single insulation material. Furthermore, the dielectric response can be determined, e.g. 11 insulation resistance and polarization index, for a number of different temperatures and the dielectric response is plotted in, for example, the insulation resistance at 60 seconds as a function of temperature. This is exemplified in Fig. 6, which shows the insulation resistance at 60 seconds as a function of temperature.
    [62] Preferred embodiments of a method and a device according to the invention have been described. It will be appreciated by those skilled in the art that the power system component tester can be easily used to test dielectric properties in power system components, including power transformers, instrument transformers, cables, generators and other rotating machines, circuit breakers and others, in some cases after making appropriate modifications in the stimulation circuit 12. 13 or the test controller 11.
    权利要求:
    Claims (13)
    [1]
    1. to determine the activation energy of the electrical insulation, 2. to determine the actual temperature (Ti) of the electrical insulation and the temperature (T2) to which the supply is to be corrected, 3. to calculate a correction factor (Axy) by means of Arrhenius the equation, 4. to stimulate the electrical insulation with a DC voltage stimulation signal, 5. to determine a response of the power system to the DC voltage stimulation signal at the actual temperature and 6. to determine the parameter has the electrical insulation at the temperature to which the supply is to be corrected based on the answer modified with the correction factor, whereby the determination of the parameter has the electrical insulation carried out in the time domain.
    [2]
    Method according to claim 1, in which the time is shifted by the correction factor (Axy) and the amplitude is scaled for insulation resistance / current reading with the correction factor (Axy).
    [3]
    A method according to any one of claims 1-2, wherein the electrical insulation comprises a single material, and wherein the parameter has the electrical insulation determined based on the response modified with the correction factor calculated based on a single activation energy.
    [4]
    A method according to any one of claims 1-3, wherein the electrical insulation comprises atm instone two materials. 12 13
    [5]
    The method of claim 4, comprising the steps of performing a dielectric response feed as a function of time at the actual temperature (T1) of the electrical insulation, and dividing the feed data into data for first, second and usual additional materials.
    [6]
    The method of claim 5, wherein the step of dividing the data of data into data for first, second and usual additional materials is performed by a mathematical model, as the XY model receives dielectric frequency response feeds.
    [7]
    A method according to claim 5 or 6, wherein the temperature correction is applied to conventional material, the method comprising the further step of determining the total dielectric response at the temperature to which the feed is to be corrected.
    [8]
    A method according to any one of claims 1-7, wherein the dielectric parameter is something of the following: insulation resistance, dielectric absorption ratio and polarization index.
    [9]
    A method according to any one of claims 1-8, wherein the power system component is any of the following: a rotating machine, a transformer, a bushing and a power cable.
    [10]
    A method according to any one of claims 1-9, wherein a correction is made if several temperatures in a range are used to determine the temperature dependence of the dielectric parameter, preferably insulation resistance and polarization index.
    [11]
    An apparatus for determining a dielectric parameter of an electrical insulation of a power system component, comprising a test controller (11), a stimulator circuit (12) arranged to stimulate the insulation of the power system component, a detector circuit (13) arranged to detect, register and / or supply the response has the power system component, an input device (14) arranged to input the text value and / or the parameter value may command the stimulator circuit (12), and an output device (15), characterized in that the test control unit (11) is arranged to control the device according to the claim. 1. 14
    [12]
    A computer program, comprising computer readable code means, which, when executed in a device, causes the device to perform the method according to any one of claims 1-10.
    [13]
    A computer program product comprising a computer program according to claim 12. 12 14 11 13 16
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    同族专利:
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    US20160041219A1|2016-02-11|
    LT2986993T|2018-06-25|
    EP2986993A1|2016-02-24|
    TR201807880T4|2018-06-21|
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    引用文献:
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    法律状态:
    优先权:
    申请号 | 申请日 | 专利标题
    SE1300282A|SE537145C2|2013-04-16|2013-04-16|Method and apparatus for determining power system parameters|SE1300282A| SE537145C2|2013-04-16|2013-04-16|Method and apparatus for determining power system parameters|
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    PCT/EP2014/057586| WO2014170306A1|2013-04-16|2014-04-15|Method and device for determining power system parameters|
    NO14732822A| NO2986993T3|2013-04-16|2014-04-15|
    TR2018/07880T| TR201807880T4|2013-04-16|2014-04-15|Methods and tools for determining power system parameters.|
    LTEP14732822.3T| LT2986993T|2013-04-16|2014-04-15|Method and device for determining power system parameters|
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    US14/883,655| US20160041219A1|2013-04-16|2015-10-15|Method and device for determining power system parameters|
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