CN205139306U - Measurement of partial discharge system under ns level impulse voltage - Google Patents

Measurement of partial discharge system under ns level impulse voltage Download PDF

Info

Publication number
CN205139306U
CN205139306U CN201520962773.8U CN201520962773U CN205139306U CN 205139306 U CN205139306 U CN 205139306U CN 201520962773 U CN201520962773 U CN 201520962773U CN 205139306 U CN205139306 U CN 205139306U
Authority
CN
China
Prior art keywords
partial discharge
level
variable filter
power equipment
measurement system
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Withdrawn - After Issue
Application number
CN201520962773.8U
Other languages
Chinese (zh)
Inventor
姚鑫
谭向宇
谷红霞
刘小伟
王科
马仪
彭晶
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Electric Power Research Institute of Yunnan Power System Ltd
Original Assignee
Electric Power Research Institute of Yunnan Power System Ltd
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Electric Power Research Institute of Yunnan Power System Ltd filed Critical Electric Power Research Institute of Yunnan Power System Ltd
Priority to CN201520962773.8U priority Critical patent/CN205139306U/en
Application granted granted Critical
Publication of CN205139306U publication Critical patent/CN205139306U/en
Withdrawn - After Issue legal-status Critical Current
Anticipated expiration legal-status Critical

Links

Landscapes

  • Testing Relating To Insulation (AREA)

Abstract

本实用新型实施例公开了一种ns级冲击电压下局部放电测量系统,通过高频脉冲电流传感器、采集电容和MOSFET传感器采集待测量电力设备的局部放电脉冲信号,可变滤波器排除ns级冲击源引起的位移电流和起始时刻的干扰信号,增强抗干扰性;而且,光电倍增管采集局部放电光信号、并将所述光信号转换成电信号,示波器同时接收所述局部放电脉冲信号和所述光电倍增管发送的电信号,进行计算和显示以获得局部放电测量结果,有效结合了脉冲电流检测和光学检测的特点,提高抗干扰性;另外,所述ns级冲击电压下局部放电测量系统还具有操作简单,可靠耐用、方便的特点,将大大缩减系统搭建准备时间和人力,以缩短测量周期和劳动强度。

The embodiment of the utility model discloses a partial discharge measurement system under ns-level impulse voltage. The partial discharge pulse signal of the power equipment to be measured is collected through a high-frequency pulse current sensor, an acquisition capacitor and a MOSFET sensor, and the variable filter eliminates the ns-level impact. The displacement current caused by the source and the interference signal at the initial moment enhance the anti-interference; moreover, the photomultiplier tube collects the partial discharge optical signal and converts the optical signal into an electrical signal, and the oscilloscope simultaneously receives the partial discharge pulse signal and The electrical signal sent by the photomultiplier tube is calculated and displayed to obtain the partial discharge measurement result, which effectively combines the characteristics of pulse current detection and optical detection to improve anti-interference; in addition, the partial discharge measurement under the ns level impulse voltage The system also has the characteristics of simple operation, reliability, durability, and convenience, which will greatly reduce the preparation time and manpower for system construction to shorten the measurement cycle and labor intensity.

Description

一种ns级冲击电压下局部放电测量系统A Partial Discharge Measurement System under ns Level Impulse Voltage

技术领域technical field

本实用新型涉及电力检测设备技术领域,特别是涉及一种ns级冲击电压下局部放电测量系统。The utility model relates to the technical field of electric power detection equipment, in particular to a partial discharge measurement system under ns-level impulse voltage.

背景技术Background technique

局部放电是绝缘击穿、闪络的早期表现,是电力设备绝缘试验中发现局部缺陷和隐患的重要手段和绝缘可靠性及寿命评估的重要指标;所述电力设备在作现场交流耐压试验的同时测量局部放电,对发现现场安装完成后电力设备的绝缘缺陷发挥了重要作用。其中,利用ns级冲击电压试验进行局部放电测量以及绝缘故障诊断一直是国内外的研究热点。Partial discharge is an early manifestation of insulation breakdown and flashover. It is an important means to discover local defects and hidden dangers in the insulation test of power equipment and an important indicator of insulation reliability and life evaluation; Simultaneous measurement of partial discharge plays an important role in discovering insulation defects of electrical equipment after field installation is completed. Among them, the use of ns-level impulse voltage test for partial discharge measurement and insulation fault diagnosis has been a research hotspot at home and abroad.

目前,在ns级冲击电压下的局部放电测量一般使用脉冲电流法;每一次局部放电都会发生正负电荷中和,伴随有一个电流脉冲,通过测量每次脉冲电流来对局部放电进行测量的方法称为脉冲电流法;在具体实施时,一般通过测量阻抗在耦合电容侧或通过Rogowski线圈从电力设备的中性点或接地点测量局部放电所引起的脉冲电流,获得视在放电量、放电相位等放电信息。所述脉冲电流法具有灵敏度高、易于定量等特点,在局部放电检测领域逐渐成为主流的检测方法。At present, the pulse current method is generally used for partial discharge measurement under ns-level impulse voltage; each partial discharge will have positive and negative charge neutralization, accompanied by a current pulse, and the method of measuring partial discharge by measuring each pulse current It is called the pulse current method; in the specific implementation, the pulse current caused by partial discharge is generally measured by measuring the impedance on the coupling capacitor side or through the Rogowski coil from the neutral point or ground point of the power equipment to obtain the apparent discharge amount and discharge phase Wait for discharge information. The pulse current method has the characteristics of high sensitivity and easy quantification, and has gradually become the mainstream detection method in the field of partial discharge detection.

然而,所述脉冲电流检测法的测量频率范围一般不超过1MHz,容易受到外界无线电等干扰噪声的影响,导致局部放电测量不准甚至造成误检,抗干扰性差。However, the measurement frequency range of the pulse current detection method generally does not exceed 1MHz, which is easily affected by interference noise such as external radio, which leads to inaccurate partial discharge measurement or even false detection, and poor anti-interference performance.

实用新型内容Utility model content

本实用新型实施例中提供了一种ns级冲击电压下局部放电测量系统,以解决现有技术中的局部放电测量抗干扰差的问题。The embodiment of the utility model provides a partial discharge measurement system under ns level impulse voltage to solve the problem of poor anti-interference in partial discharge measurement in the prior art.

为了解决上述技术问题,本实用新型实施例公开了如下技术方案:In order to solve the above technical problems, the embodiment of the utility model discloses the following technical solutions:

本实用新型实施例公开了一种ns级冲击电压下局部放电测量系统,包括ns级冲击电压局部放电装置和局部放电测量装置,其中:The embodiment of the utility model discloses a partial discharge measurement system under ns-level impulse voltage, including an ns-level impulse voltage partial discharge device and a partial discharge measurement device, wherein:

所述ns级冲击电压局部放电装置,包括:The ns-level impulse voltage partial discharge device includes:

与待测量电力设备的一端相连接的ns级冲击电压发生器;A ns-level impulse voltage generator connected to one end of the power equipment to be measured;

与待测量电力设备的另一端相连接的高频脉冲电流传感器;以及,a high-frequency pulsed current sensor connected to the other end of the electrical equipment to be measured; and,

与所述高频脉冲电流传感器相连接且相互并联的采集电容和MOSFET场效应晶体管;A collection capacitor and a MOSFET field effect transistor connected in parallel with the high-frequency pulse current sensor;

所述局部放电测量装置,包括:The partial discharge measuring device includes:

与所述采集电容、所述MOSFET(MetalOxideSemiconductorFieldEffectTransistor,金属氧化物半导体场效应晶体管)场效应晶体管以及所述高频脉冲电流传感器均相连接的可变滤波器;A variable filter connected to the collection capacitor, the MOSFET (MetalOxideSemiconductorFieldEffectTransistor, Metal Oxide Semiconductor Field Effect Transistor) field effect transistor, and the high-frequency pulse current sensor;

与所述可变滤波器相连接的示波器;an oscilloscope connected to the variable filter;

与所述示波器相连接的光电倍增管;所述光电倍增管与所述待测量电力设备对应设置,位于能够摄取所述待测量电力设备光信号的位置;以及,A photomultiplier tube connected to the oscilloscope; the photomultiplier tube is set corresponding to the power equipment to be measured, and is located at a position where the optical signal of the power equipment to be measured can be picked up; and,

与所述示波器和所述ns级冲击电压发生器均相连接的分压器。A voltage divider connected to both the oscilloscope and the ns-level impulse voltage generator.

优选地,所述ns级冲击下局部放电测量系统还包括外壳,所述高频脉冲电流传感器、所述采集电容、所述MOSFET场效应晶体管以及所述光电倍增管均设置于所述外壳内。Preferably, the ns-level impact partial discharge measurement system further includes a casing, and the high-frequency pulse current sensor, the collection capacitor, the MOSFET field effect transistor, and the photomultiplier tube are all arranged in the casing.

优选地,,所述可变滤波器包括第一可变滤波器和第二可变滤波器;所述第一可变滤波器的一端与所述高频脉冲电流传感器相连接、另一端与所述示波器相连接;所述第二可变滤波器的一端与所述采集电容和所述MOSFET场效应晶体管相连接、另一端与所述示波器相连接。Preferably, the variable filter includes a first variable filter and a second variable filter; one end of the first variable filter is connected to the high-frequency pulse current sensor, and the other end is connected to the The oscilloscope is connected; one end of the second variable filter is connected with the collection capacitor and the MOSFET field effect transistor, and the other end is connected with the oscilloscope.

优选地,所述采集电容的电容值为20pF-100pF。Preferably, the capacitance value of the collection capacitor is 20pF-100pF.

优选地,所述MOSFET场效应晶体管为VMOSFET场效应晶体管。Preferably, the MOSFET field effect transistor is a VMOSFET field effect transistor.

优选地,所述局部放电测量装置包括多个光电倍增管;多个所述光电倍增管均设置于所述待测量电力设备的对应位置,且所述光电倍增管均与所述示波器相连接。Preferably, the partial discharge measurement device includes a plurality of photomultiplier tubes; the plurality of photomultiplier tubes are arranged at corresponding positions of the power equipment to be measured, and the photomultiplier tubes are all connected to the oscilloscope.

由以上技术方案可见,本实用新型实施例提供的ns级冲击电压下局部放电测量系统,通过高频脉冲电流传感器、采集电容和MOSFET传感器获得待测量电力设备的局部放电脉冲信号,可变滤波器排除ns级冲击源引起的位移电流和起始时刻的干扰信号,增强抗干扰性;而且,光电倍增管采集局部放电光信号、并将所述光信号转换成电信号,示波器同时接收所述局部放电脉冲信号和所述光电倍增管发送的电信号,进行计算和显示以获得局部放电测量结果,有效结合了脉冲电流检测和光学检测的特点,提高抗干扰性;另外,所述ns级冲击电压下局部放电测量系统还具有操作简单,可靠耐用、方便的特点,将大大缩减系统搭建准备时间和人力,以缩短测量周期和劳动强度。It can be seen from the above technical solutions that the partial discharge measurement system under the ns-level impulse voltage provided by the embodiment of the utility model obtains the partial discharge pulse signal of the power equipment to be measured through the high-frequency pulse current sensor, the collection capacitor and the MOSFET sensor, and the variable filter Eliminate the displacement current caused by the ns-level impact source and the interference signal at the initial moment to enhance the anti-interference; moreover, the photomultiplier tube collects the partial discharge optical signal and converts the optical signal into an electrical signal, and the oscilloscope simultaneously receives the partial discharge optical signal. The discharge pulse signal and the electrical signal sent by the photomultiplier tube are calculated and displayed to obtain the partial discharge measurement result, which effectively combines the characteristics of pulse current detection and optical detection to improve anti-interference; in addition, the ns-level impulse voltage The lower partial discharge measurement system also has the characteristics of simple operation, reliability, durability, and convenience, which will greatly reduce the preparation time and manpower for system construction to shorten the measurement cycle and labor intensity.

附图说明Description of drawings

为了更清楚地说明本实用新型实施例或现有技术中的技术方案,下面将对实施例或现有技术描述中所需要使用的附图作简单地介绍,显而易见地,对于本领域普通技术人员而言,在不付出创造性劳动的前提下,还可以根据这些附图获得其他的附图。In order to more clearly illustrate the technical solutions in the embodiments of the present invention or the prior art, the following will briefly introduce the accompanying drawings that need to be used in the description of the embodiments or the prior art. Obviously, for those of ordinary skill in the art In other words, other drawings can also be obtained from these drawings under the premise of not paying creative work.

图1为本实用新型实施例提供的一种ns级冲击电压下局部放电测量系统的结构示意图;Fig. 1 is a schematic structural diagram of a partial discharge measurement system under an ns-level impulse voltage provided by an embodiment of the present invention;

图1的符号表示为:The symbolic representation of Figure 1 is:

1-ns级冲击电压发生器,2-高频脉冲电流传感器,3-采集电容,4-MOSFET场效应晶体管,5-可变滤波器,6-示波器,7-光电倍增管,8-分压器,9-待测电力设备,10-外壳。1-ns level impulse voltage generator, 2-high frequency pulse current sensor, 3-acquisition capacitor, 4-MOSFET field effect transistor, 5-variable filter, 6-oscilloscope, 7-photomultiplier tube, 8-voltage divider Device, 9-power equipment to be tested, 10-housing.

具体实施方式detailed description

为了使本技术领域的人员更好地理解本实用新型中的技术方案,下面将结合本实用新型实施例中的附图,对本实用新型实施例中的技术方案进行清楚、完整地描述,显然,所描述的实施例仅仅是本实用新型一部分实施例,而不是全部的实施例。基于本实用新型中的实施例,本领域普通技术人员在没有做出创造性劳动前提下所获得的所有其他实施例,都应当属于本实用新型保护的范围。In order to enable those skilled in the art to better understand the technical solution in the utility model, the technical solution in the utility model embodiment will be clearly and completely described below in conjunction with the accompanying drawings in the utility model embodiment. Obviously, The described embodiments are only some of the embodiments of the present utility model, but not all of them. Based on the embodiments of the present utility model, all other embodiments obtained by persons of ordinary skill in the art without making creative efforts shall fall within the protection scope of the present utility model.

参见图1,为本实用新型实施例提供的一种ns级冲击电压下局部放电测量系统的结构示意图,所述ns级冲击电压下局部放电测量系统包括ns级冲击电压局部放电装置和局部放电测量装置。Referring to Fig. 1, it is a schematic structural diagram of a partial discharge measurement system under ns-level impulse voltage provided by an embodiment of the present invention. The partial discharge measurement system under ns-level impulse voltage includes an ns-level impulse voltage partial discharge device and a partial discharge measurement system. device.

其中,所述ns级冲击电压局部放电装置包括ns级冲击电压发生器1、高频脉冲电流传感器2、采集电容3和MOSFET场效应晶体管4。所述ns级冲击电压发生器1与待测量电力设备9的一端相连接,用于产生ns级冲击电压,并将所述ns级冲击电压作用于所述待测量电力设备9;所述待测量电力设备9在所述ns级冲击电压的作用下发生局部放电现象,所述高频脉冲电流传感器2与所述待测量电力设备9的另一端相连接,所述采集电容3和所述MOSFET场效应晶体管4并联连接、且与所述高频脉冲电流传感器2相连接,所述高频脉冲电流传感器2、所述采集电容3以及所述MOSFET场效应晶体管4组成局部放电脉冲电流采集电路,用于采集所述待测量电力设备9的局部放电脉冲信号。优选地,所述采集电容3的电容值为20pF-100pF,当然在具体实施时,本领域技术人员可以根据实际测量需求,选择超出上述范围的任意电容值的电容作为所述采集电容3。为了提高所述MOSFET场效应晶体管4的耐压和耐电流能力,以保证所述局部放电测量的正常进行,所述MOSFET场效应晶体管4一般选用VMOSFET(verticalMOSFET)场效应晶体管,利用所述VMOSFET垂直导电的结构来提高场效应晶体管的耐压性和耐电流性。Wherein, the ns-level impulse voltage partial discharge device includes an ns-level impulse voltage generator 1 , a high-frequency pulse current sensor 2 , a collection capacitor 3 and a MOSFET field effect transistor 4 . The ns-level impulse voltage generator 1 is connected to one end of the power equipment to be measured 9 for generating ns-level impulse voltages, and the ns-level impulse voltages are applied to the power equipment to be measured 9; the to-be-measured The power equipment 9 undergoes a partial discharge phenomenon under the action of the ns-level impulse voltage, the high-frequency pulse current sensor 2 is connected to the other end of the power equipment 9 to be measured, and the collection capacitor 3 and the MOSFET field The effect transistor 4 is connected in parallel and is connected with the high-frequency pulse current sensor 2, the high-frequency pulse current sensor 2, the collection capacitor 3 and the MOSFET field-effect transistor 4 form a partial discharge pulse current collection circuit. To collect the partial discharge pulse signal of the power equipment 9 to be measured. Preferably, the capacitance value of the collection capacitor 3 is 20pF-100pF. Of course, in actual implementation, those skilled in the art can choose a capacitor with any capacitance value beyond the above range as the collection capacitor 3 according to actual measurement requirements. In order to improve the withstand voltage and current capability of the MOSFET field effect transistor 4, to ensure the normal progress of the partial discharge measurement, the MOSFET field effect transistor 4 generally selects a VMOSFET (verticalMOSFET) field effect transistor, and utilizes the VMOSFET vertical The conductive structure is used to improve the withstand voltage and current resistance of the field effect transistor.

所述局部放电测量装置包括可变滤波器5、示波器6、光电倍增管7和分压器8。所述可变滤波器5与所述采集电容3、所述MOSFET场效应晶体管4以及上述高频脉冲电流传感器2均相连接,在本实用新型实施例中,所述可变滤波器5包括第一可变滤波器51和第二可变滤波器52;所述第一可变滤波器51的一端与所述高频脉冲电流传感器2相连接、另一端与所述示波器6相连接;所述第二可变滤波器52的一端与所述采集电容3和所述MOSFET场效应晶体管4相连接、另一端与所述示波器6相连接。所述可变滤波器5将采集到的局部放电脉冲信号中ns级冲击源引起的位移电流和起始时刻的干扰信号滤掉,以保证所述局部放电脉冲信号的准确性,排除外界无线电等干扰信号对所述局部放电脉冲信号的干扰。所述光电倍增管7与所述待测量电力设备9对应设置,位于能够摄取所述待测量电力设备9光信号的位置,例如所述光电倍增管可以设置于所述待测量电力设备9的侧面周围等;所述光电倍增管7与所述示波器6相连接,所述光电倍增管7采集所述待测量电力设备9局部放电产生的光信号,并将所述光信号转换成电信号传输到所述示波器6上。在本实用新型实施例中,所述局部放电测量装置包括1个光电倍增管7,当然,本领域技术人员可以设置任意多个所述光电倍增管7,并将多个所述光电倍增管7设置于所述待测量电力设备9的对应位置,以便于采集所述待测量电力设备9局部放电产生的光信号,多个所述光电倍增管7均与所述示波器6相连接、向所述示波器6传送信号。所述分压器8与所述ns级冲击电压发生器1以及所述示波器6均相连接,所述分压器8可以为电阻式分压器、电容式分压器和阻容混合式分压器中的一种,所述示波器6通过所述分压器8得到ns级冲击电压信号。所述示波器6对所述局部放电脉冲信号、所述ns级冲击电压信号以及所述光电倍增管7的电信号进行记录,进一步计算得出放电量、放电相位、以及显示局部放电的波形等,得到局部放电测量结果。为了方便携带,所述ns级冲击电压下局部放电测量系统的还包括外壳10,所述高频脉冲电流传感器2、所述采集电容3、所述MOSFET场效应晶体管4以及所述光电倍增管7均设置于所述外壳10内,所述外壳10能够进一步防止外界环境可能对所述ns级冲击电压局部放电测量系统的干扰和破坏,进一步提高抗干扰性和耐用性。The partial discharge measurement device includes a variable filter 5 , an oscilloscope 6 , a photomultiplier tube 7 and a voltage divider 8 . The variable filter 5 is connected to the collection capacitor 3, the MOSFET field effect transistor 4, and the above-mentioned high-frequency pulse current sensor 2. In the embodiment of the utility model, the variable filter 5 includes the first A variable filter 51 and a second variable filter 52; one end of the first variable filter 51 is connected with the high-frequency pulse current sensor 2, and the other end is connected with the oscilloscope 6; the One end of the second variable filter 52 is connected to the collection capacitor 3 and the MOSFET field effect transistor 4 , and the other end is connected to the oscilloscope 6 . The variable filter 5 filters out the displacement current caused by the ns-level impact source and the interference signal at the initial moment in the collected partial discharge pulse signal, so as to ensure the accuracy of the partial discharge pulse signal and exclude external radio, etc. An interference signal interferes with the partial discharge pulse signal. The photomultiplier tube 7 is arranged corresponding to the power equipment to be measured 9, and is located at a position capable of picking up the light signal of the power equipment to be measured 9, for example, the photomultiplier tube can be arranged on the side of the power equipment to be measured 9 around; the photomultiplier tube 7 is connected with the oscilloscope 6, and the photomultiplier tube 7 collects the optical signal generated by the partial discharge of the power equipment 9 to be measured, and converts the optical signal into an electrical signal and transmits it to 6 on the oscilloscope. In the embodiment of the present utility model, the partial discharge measuring device includes a photomultiplier tube 7, certainly, those skilled in the art can arrange any number of photomultiplier tubes 7, and combine a plurality of photomultiplier tubes 7 It is arranged at the corresponding position of the power equipment to be measured 9, so as to collect the optical signal generated by the partial discharge of the power equipment to be measured 9, and a plurality of the photomultiplier tubes 7 are connected to the oscilloscope 6 and connected to the oscilloscope 6. The oscilloscope 6 transmits the signal. The voltage divider 8 is connected to the ns-level impulse voltage generator 1 and the oscilloscope 6, and the voltage divider 8 can be a resistive voltage divider, a capacitive voltage divider or a resistance-capacitance hybrid divider. One of voltage regulators, the oscilloscope 6 obtains an ns-level impulse voltage signal through the voltage divider 8 . The oscilloscope 6 records the partial discharge pulse signal, the ns-level impulse voltage signal and the electrical signal of the photomultiplier tube 7, and further calculates the discharge amount, the discharge phase, and the waveform of the partial discharge, etc., Obtain partial discharge measurement results. For portability, the partial discharge measurement system under ns-level impulse voltage also includes a housing 10, the high-frequency pulse current sensor 2, the collection capacitor 3, the MOSFET field effect transistor 4 and the photomultiplier tube 7 All are arranged in the housing 10, and the housing 10 can further prevent the external environment from interfering and destroying the ns-level impulse voltage partial discharge measurement system, and further improve the anti-interference and durability.

通过上述实施例的描述,所述示波器6通过所述可变滤波器5,获得所述高频脉冲电流传感器2、所述采集电容3以及所述MOSFET场效应晶体管4采集得到的待测量电力设备9的局部放电脉冲信号,所述可变滤波器5有效过滤掉干扰信号以提高所述ns级冲击电压下局部放电测量系统的抗干扰性能;而且,所述示波器6与所述光电倍增管7相连接,所述光电倍增管7能够对所述待测量电力设备局部放电进行光学检测,具有很强的抗干扰性能,不会受到周围环境如无线电等干扰噪声的影响,本实用新型实施例通过使用光学检测和脉冲电流检测结合的方式,有效提高了所述ns级冲击电压下局部放电测量系统的抗干扰性能;另外,本实用新型提供的ns级冲击电压下局部放电测量系统还具有操作简单,可靠耐用、方便的特点,将大大缩减搭建局部放电测量系统的准备时间和人力,以缩短测量周期和劳动强度。Through the description of the above embodiment, the oscilloscope 6 obtains the power equipment to be measured collected by the high frequency pulse current sensor 2, the collection capacitor 3 and the MOSFET field effect transistor 4 through the variable filter 5 9 partial discharge pulse signals, the variable filter 5 effectively filters out interference signals to improve the anti-interference performance of the partial discharge measurement system under the ns level impulse voltage; and, the oscilloscope 6 and the photomultiplier tube 7 connected, the photomultiplier tube 7 can optically detect the partial discharge of the power equipment to be measured, has strong anti-interference performance, and will not be affected by interference noises such as radio in the surrounding environment. Embodiments of the present invention pass The combination of optical detection and pulse current detection effectively improves the anti-interference performance of the partial discharge measurement system under ns-level impulse voltage; in addition, the partial discharge measurement system under ns-level impulse voltage provided by the utility model also has the advantages of simple operation , Reliable, durable, and convenient features will greatly reduce the preparation time and manpower for building a partial discharge measurement system, so as to shorten the measurement cycle and labor intensity.

与上述实施例提供的ns级冲击电压下局部放电测量系统相对应,本实用新型实施例还提供了一种ns级冲击电压下局部放电测量方法,所述测量方法包括以下步骤:Corresponding to the partial discharge measurement system under ns-level impulse voltage provided by the above-mentioned embodiments, the embodiment of the present utility model also provides a partial discharge measurement method under ns-level impulse voltage, and the measurement method includes the following steps:

选取上述ns级冲击电压下局部放电测量系统;Select the above-mentioned partial discharge measurement system under ns-level impulse voltage;

将待测量电力设备9与所述ns级冲击电压放电装置和所述局部放电测量装置相连接;在具体实施时,将所述待测量电力设备9与所述ns级冲击电压发生器1和所述高频脉冲电流传感器2相连接,以保证所述ns级冲击电压发生器1能够将ns级冲击电压作用于所述待测量电力设备9,以及所述高频脉冲电流传感器2能够采集所述待测量电力设备9产生的局部放电脉冲信号。Connect the power equipment 9 to be measured with the ns-level impulse voltage discharge device and the partial discharge measurement device; during specific implementation, connect the power equipment 9 to be measured with the ns-level impulse voltage generator 1 and the The high-frequency pulse current sensor 2 is connected to ensure that the ns-level impulse voltage generator 1 can apply the ns-level impulse voltage to the power equipment 9 to be measured, and the high-frequency pulse current sensor 2 can collect the The partial discharge pulse signal generated by the power equipment 9 to be measured.

所述高频脉冲电流传感器2、所述采集电容3和所述MOSFET场效应晶体管4采集局部放电脉冲信号,经可变滤波器滤波5排除ns级冲击源引起的位移电流和起始时刻的干扰信号后传送至示波器6;所述高频脉冲电流传感器2的一端与待测量电力设备9相连接、另一端与相互并联的所述采集电容3和所述MOSFET场效应晶体管4均相连接,组成局部放电脉冲信号采集电路;采集到的局部放电脉冲信号发送至可变滤波器5处,所述可变滤波器5将所述局部放电脉冲信号中的冲击源引起的位移电流和起始时刻的干扰信号过滤掉,保证所述局部放电脉冲信号的正确性、排除干扰,并将过滤后的所述局部放电脉冲信号发送至示波器6。The high-frequency pulse current sensor 2, the collection capacitor 3 and the MOSFET field effect transistor 4 collect partial discharge pulse signals, which are filtered by a variable filter 5 to eliminate the displacement current caused by the ns-level impact source and the interference at the initial moment After the signal is transmitted to the oscilloscope 6; one end of the high-frequency pulse current sensor 2 is connected to the power equipment 9 to be measured, and the other end is connected to the collection capacitor 3 and the MOSFET field effect transistor 4 connected in parallel to form a Partial discharge pulse signal acquisition circuit; the collected partial discharge pulse signal is sent to the variable filter 5, and the variable filter 5 uses the displacement current caused by the impact source in the partial discharge pulse signal and the displacement current at the initial moment Interference signals are filtered out to ensure the correctness of the partial discharge pulse signal, eliminate interference, and send the filtered partial discharge pulse signal to the oscilloscope 6 .

所述光电倍增管7采集所述待测电力设备9的局部放电光信号,并将所述光信号转换成电信号传送至示波器6;所述待测电力设备9在ns级冲击电压的作用下发生局部放电,并产生光辐射,所述光电倍增管7能够采集所述待测电力设备9产生的光信号,并将所述光信号转换成电信号,传送至示波器6,完成度待测电力设备9局部放电的光学检测。The photomultiplier tube 7 collects the partial discharge optical signal of the power equipment under test 9, and converts the light signal into an electrical signal and transmits it to the oscilloscope 6; the power equipment under test 9 is under the action of ns level impulse voltage When partial discharge occurs and light radiation is generated, the photomultiplier tube 7 can collect the light signal generated by the power equipment to be tested 9, convert the light signal into an electrical signal, and transmit it to the oscilloscope 6 to complete the power to be tested. Device 9 for optical detection of partial discharges.

所述示波器6对所述局部放电脉冲信号和来自所述光电倍增管7的电信号进行计算处理,得出局部放电测量结果;具体地,所述示波器6同时获得所述可变滤波器5滤波之后的局部放电脉冲信号和来自所述光电倍增管7的电信号,并对上述信号进行计算处理,展示波形图或者计算放电量、放电相位等,获得局部放电测量结果。The oscilloscope 6 calculates and processes the partial discharge pulse signal and the electrical signal from the photomultiplier tube 7 to obtain a partial discharge measurement result; specifically, the oscilloscope 6 obtains the variable filter 5 filtering Subsequent partial discharge pulse signals and electrical signals from the photomultiplier tube 7 are calculated and processed to display waveform diagrams or calculate discharge volume, discharge phase, etc., to obtain partial discharge measurement results.

在本实用新型实施例中,所述可变滤波器5将采集到的局部放电脉冲信号中的ns级冲击源引起的位移电流和初始时刻的干扰信号滤除,有效保证了所述局部放电脉冲信号的正确性,具有很强的抗干扰性;同时结合脉冲电流检测方法和光学检测方法,由于光学检测法具有很好的抗干扰性,通过上述结合进一步提高局部放电测量的抗干扰性。In the embodiment of the utility model, the variable filter 5 filters out the displacement current caused by the ns-level impact source in the collected partial discharge pulse signal and the interference signal at the initial moment, effectively ensuring that the partial discharge pulse The correctness of the signal has strong anti-interference; at the same time, the combination of pulse current detection method and optical detection method, because the optical detection method has good anti-interference, through the above combination to further improve the anti-interference of partial discharge measurement.

需要说明的是,在本文中,诸如术语“包括”、“包含”或者其任何其他变体意在涵盖非排他性的包含,从而使得包括一系列要素的过程、方法、物品或者设备不仅包括那些要素,而且还包括没有明确列出的其他要素,或者是还包括为这种过程、方法、物品或者设备所固有的要素。在没有更多限制的情况下,由语句“包括一个……”限定的要素,并不排除在包括所述要素的过程、方法、物品或者设备中还存在另外的相同要素。It should be noted that, in this document, terms such as "comprising", "comprising" or any other variation thereof are intended to cover a non-exclusive inclusion such that a process, method, article or apparatus comprising a set of elements includes not only those elements , but also includes other elements not expressly listed, or also includes elements inherent in such process, method, article or equipment. Without further limitations, an element defined by the phrase "comprising a ..." does not exclude the presence of additional identical elements in the process, method, article or apparatus comprising said element.

以上所述仅是本实用新型的具体实施方式,使本领域技术人员能够理解或实现本实用新型。对这些实施例的多种修改对本领域的技术人员来说将是显而易见的,本文中所定义的一般原理可以在不脱离本实用新型的精神或范围的情况下,在其它实施例中实现。因此,本实用新型将不会被限制于本文所示的这些实施例,而是要符合与本文所公开的原理和新颖特点相一致的最宽的范围。The above descriptions are only specific implementation methods of the present utility model, so that those skilled in the art can understand or realize the present utility model. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the general principles defined herein may be implemented in other embodiments without departing from the spirit or scope of the invention. Therefore, the present invention will not be limited to these embodiments shown herein, but will conform to the widest scope consistent with the principles and novel features disclosed herein.

Claims (6)

1. a Partial Discharge Measurement System under ns level surge voltage, is characterized in that, ns level surge voltage shelf depreciation device and partial-discharge measuring device, wherein:
Described ns level surge voltage shelf depreciation device, comprising:
The ns level impulse voltage generator (1) be connected with one end of power equipment to be measured (9);
The high-frequency electrical pulses flow sensor (2) be connected with the other end of power equipment to be measured (9); And,
Be connected and collection electric capacity (3) parallel with one another and MOSFET field effect transistor (4) with described high-frequency electrical pulses flow sensor (2);
Described partial-discharge measuring device, comprising:
The variable filter (5) be all connected with described collection electric capacity (3), described MOSFET field effect transistor (4) and described high-frequency electrical pulses flow sensor (2);
The oscillograph (6) be connected with described variable filter (5);
The photomultiplier (7) be connected with described oscillograph (6); Described photomultiplier (7) is corresponding with described power equipment to be measured (9) to be arranged, and is positioned at the position can absorbing described power equipment to be measured (9) light signal; And,
The voltage divider (8) be all connected with described ns level impulse voltage generator (1) with described oscillograph (6).
2. Partial Discharge Measurement System under ns level surge voltage according to claim 1, it is characterized in that, described ns level is impacted lower Partial Discharge Measurement System and is also comprised shell (10), and described high-frequency electrical pulses flow sensor (2), described collection electric capacity (3), described MOSFET field effect transistor (4) and described photomultiplier (7) are all arranged in described shell (10).
3. Partial Discharge Measurement System under ns level surge voltage according to claim 1, is characterized in that, described variable filter (5) comprises the first variable filter (51) and the second variable filter (52); One end of described first variable filter (51) is connected with described high-frequency electrical pulses flow sensor (2), the other end is connected with described oscillograph (6); One end of described second variable filter (52) is connected with described MOSFET field effect transistor (4) with described collection electric capacity (3), the other end is connected with described oscillograph (6).
4. Partial Discharge Measurement System under ns level surge voltage according to claim 1, is characterized in that, the capacitance of described collection electric capacity (3) is 20pF-100pF.
5. Partial Discharge Measurement System under ns level surge voltage according to claim 1, is characterized in that, described MOSFET field effect transistor (4) is VMOSFET field effect transistor.
6. Partial Discharge Measurement System under ns level surge voltage according to claim 1, it is characterized in that, described partial-discharge measuring device comprises multiple photomultiplier (7); Multiple described photomultiplier (7) is all arranged at the correspondence position of described power equipment to be measured (9), and described photomultiplier (7) is all connected with described oscillograph (6).
CN201520962773.8U 2015-11-26 2015-11-26 Measurement of partial discharge system under ns level impulse voltage Withdrawn - After Issue CN205139306U (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN201520962773.8U CN205139306U (en) 2015-11-26 2015-11-26 Measurement of partial discharge system under ns level impulse voltage

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN201520962773.8U CN205139306U (en) 2015-11-26 2015-11-26 Measurement of partial discharge system under ns level impulse voltage

Publications (1)

Publication Number Publication Date
CN205139306U true CN205139306U (en) 2016-04-06

Family

ID=55625084

Family Applications (1)

Application Number Title Priority Date Filing Date
CN201520962773.8U Withdrawn - After Issue CN205139306U (en) 2015-11-26 2015-11-26 Measurement of partial discharge system under ns level impulse voltage

Country Status (1)

Country Link
CN (1) CN205139306U (en)

Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN105301462B (en) * 2015-11-26 2018-11-13 云南电网有限责任公司电力科学研究院 Partial Discharge Measurement System and method under a kind of ns grades of surge voltage
CN109471004A (en) * 2018-09-30 2019-03-15 中国电力科学研究院有限公司 A system and method for detecting the type and amount of discharge in a GIS
CN110174600A (en) * 2019-07-03 2019-08-27 云南电网有限责任公司电力科学研究院 GIS detection device and application based on μ PMT combining ultrasonic sensor
CN110514973A (en) * 2019-10-14 2019-11-29 云南电网有限责任公司电力科学研究院 Photon counting device and method for detecting partial discharge light radiation intensity
CN111880137A (en) * 2020-08-06 2020-11-03 新纳传感系统有限公司 Current sensor test system

Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN105301462B (en) * 2015-11-26 2018-11-13 云南电网有限责任公司电力科学研究院 Partial Discharge Measurement System and method under a kind of ns grades of surge voltage
CN109471004A (en) * 2018-09-30 2019-03-15 中国电力科学研究院有限公司 A system and method for detecting the type and amount of discharge in a GIS
CN110174600A (en) * 2019-07-03 2019-08-27 云南电网有限责任公司电力科学研究院 GIS detection device and application based on μ PMT combining ultrasonic sensor
CN110514973A (en) * 2019-10-14 2019-11-29 云南电网有限责任公司电力科学研究院 Photon counting device and method for detecting partial discharge light radiation intensity
CN111880137A (en) * 2020-08-06 2020-11-03 新纳传感系统有限公司 Current sensor test system

Similar Documents

Publication Publication Date Title
CN105301462B (en) Partial Discharge Measurement System and method under a kind of ns grades of surge voltage
CN205139306U (en) Measurement of partial discharge system under ns level impulse voltage
CN106990340B (en) Partial discharge monitoring system and method
CN104090214B (en) A kind of Cable fault examination and aging analysis method
CN103954890B (en) DC partial discharge detection device and method for converter transformer
CN103675623B (en) GIS partial discharge detection method and system under a kind of surge voltage
CN104749498A (en) Portable partial discharge detecting and diagnosing device
CN103558521A (en) Device for detecting partial discharge of transformer under surge voltage
CN102914731B (en) Device for detecting point discharge in transformer oil under impulse voltage based on dual electrodes
CN107797033B (en) Detection platform for simulating partial discharge test of transformer
CN107831404A (en) Method and system based on the legal position XLPE cable partial discharge position of high-frequency pulse current
CN104614648A (en) Electroacoustic combined DC local discharging detecting device
CN107621595A (en) A device and method for evaluating the insulation state of a power cable
CN204462317U (en) A kind of non-local discharge test system
CN106093737B (en) A kind of test method and fault diagnosis method of transformer partial discharge signal propagation characteristics
CN102981110A (en) Data measurement and storage system and method for achieving high frequency and ultra-high frequency partial discharge monitoring of transformer
CN108732472A (en) Compound field based on high-frequency method couples paper oil insulation partial discharge detecting system
CN206400038U (en) A Signal Injection and Protection Circuit for Live Detection of Transformer Winding Deformation
CN108680836A (en) Multiple physical field based on high-frequency method couples paper oil insulation partial discharge detecting system
CN201707419U (en) Coil turn-to-turn insulation detector
CN105866644A (en) System for automatically collecting transformer oil paper insulation return voltage and testing method
CN104459497A (en) A Partial Discharge Measurement and Analysis Device under Impulse Voltage
CN203037802U (en) Data measuring storage system achieving transformer high-frequency and ultrahigh-frequency partial discharge monitoring
CN204964656U (en) Portable insulator intellectual detection system appearance
CN109085483B (en) A high frequency damping oscillation impulse voltage generating device

Legal Events

Date Code Title Description
C14 Grant of patent or utility model
GR01 Patent grant
AV01 Patent right actively abandoned

Granted publication date: 20160406

Effective date of abandoning: 20181113

AV01 Patent right actively abandoned