This document describes two case studies on cable connections in low voltage underground power cable systems. Case 1 simulates an oil-impregnated paper cable and analyzes the effects of interconnecting different cable types. It examines the cable's modal characteristic impedances and propagation coefficients. Case 2 simulates partial discharges at a substation involving interconnected and branching cables connected in parallel. Network equations are provided to model the cable connections and terminations.
Cable sizing to withstand short circuit currentLeonardo ENERGY
In a cable a short circuit causes very extreme stresses which are proportional to the square of the current:
• A temperature rise in the conducting components subjected to current flow such as conductor, screen, metal sheath, armour. Indirectly the temperature of adjoining insulation and protective covers also increases,
• electro-magnetic forces between the current-carrying components.
The temperature rise is important for its effect on ageing, heat pressure characteristics etc., and should be limited to a permissible short-circuit temperature. The thermo-mechanical effects of the current shall also be considered.
For a given short-circuit duty therefore the short-circuit capacity of a cable installation is to be investigated with respect to all these parameters. For multi-core cables in most instances the thermal effect - related to the magnitude of fault current and clearance time - is the critical parameter, since the cable will normally have enough mechanical strength. With single-core cables however, in addition, the mechanical effect - related to the magnitude of the peak short-circuit current - is of such significance that, next to the thermal, the mechanical with- stand of both cable and its supports is to be investigated.
Also accessories must be rated with respect to thermal and mechanical short-circuit stresses.
The short-circuit withstand of a cable system is not quantitatively defined with regard to permissible number of repeated short circuits, degree of deformation or destruction or impairment quality. It is expected, however, that a cable installation will remain safe in operation and that any deformation remains within tolerable limits even after several short circuits.
Traditionally, with reference to line conductors, over certain sections the neutral conductor is downsized. Today, nearly every piece of electrical equipment generates harmonic currents. Harmonic currents cause many problems in electrical installations, including overheating of neutral conductor in power cables.
To ensure the safety and resilience of installations, designers and technicians shall therefore consider harmonics in neutral sizing.
This course gives a comprehensive and up-to-date overview of the subject. A case study is also presented.
2012 Aug - Ngo Khac Hoang - Solar panel circuit for charge controllerNgô Khắc Hoàng
In partial fulfillment of the requirements of the Undergraduate Research Attachment Programme
Department of Electrical and Computer Engineering
Faculty of Engineering, National University of Singapore.
Principles of Cable Sizing; current carrying capacity, voltage drop, short circuit.
Cables are often the last component considered during system design even if in many situations cables are the true system’s lifeline: if a cable fails, the entire system may stop. Cable reliability is therefore extremely important, then a cable system should be engineered to last the life of the system in the installation environment for the required application. Environments in which cable systems are being used are often challenging, as extreme temperatures, chemicals, abrasion, and extensive flexing. These variables have a direct impact on the materials used for cable insulation and jacketing as well as the construction of the cable. Using a systematic approach will help ensure that designer select the best cable for the required application in the installation environment. This lessons will provide students main guidelines for perform this approach.
Cable sizing to withstand short circuit currentLeonardo ENERGY
In a cable a short circuit causes very extreme stresses which are proportional to the square of the current:
• A temperature rise in the conducting components subjected to current flow such as conductor, screen, metal sheath, armour. Indirectly the temperature of adjoining insulation and protective covers also increases,
• electro-magnetic forces between the current-carrying components.
The temperature rise is important for its effect on ageing, heat pressure characteristics etc., and should be limited to a permissible short-circuit temperature. The thermo-mechanical effects of the current shall also be considered.
For a given short-circuit duty therefore the short-circuit capacity of a cable installation is to be investigated with respect to all these parameters. For multi-core cables in most instances the thermal effect - related to the magnitude of fault current and clearance time - is the critical parameter, since the cable will normally have enough mechanical strength. With single-core cables however, in addition, the mechanical effect - related to the magnitude of the peak short-circuit current - is of such significance that, next to the thermal, the mechanical with- stand of both cable and its supports is to be investigated.
Also accessories must be rated with respect to thermal and mechanical short-circuit stresses.
The short-circuit withstand of a cable system is not quantitatively defined with regard to permissible number of repeated short circuits, degree of deformation or destruction or impairment quality. It is expected, however, that a cable installation will remain safe in operation and that any deformation remains within tolerable limits even after several short circuits.
Traditionally, with reference to line conductors, over certain sections the neutral conductor is downsized. Today, nearly every piece of electrical equipment generates harmonic currents. Harmonic currents cause many problems in electrical installations, including overheating of neutral conductor in power cables.
To ensure the safety and resilience of installations, designers and technicians shall therefore consider harmonics in neutral sizing.
This course gives a comprehensive and up-to-date overview of the subject. A case study is also presented.
2012 Aug - Ngo Khac Hoang - Solar panel circuit for charge controllerNgô Khắc Hoàng
In partial fulfillment of the requirements of the Undergraduate Research Attachment Programme
Department of Electrical and Computer Engineering
Faculty of Engineering, National University of Singapore.
Principles of Cable Sizing; current carrying capacity, voltage drop, short circuit.
Cables are often the last component considered during system design even if in many situations cables are the true system’s lifeline: if a cable fails, the entire system may stop. Cable reliability is therefore extremely important, then a cable system should be engineered to last the life of the system in the installation environment for the required application. Environments in which cable systems are being used are often challenging, as extreme temperatures, chemicals, abrasion, and extensive flexing. These variables have a direct impact on the materials used for cable insulation and jacketing as well as the construction of the cable. Using a systematic approach will help ensure that designer select the best cable for the required application in the installation environment. This lessons will provide students main guidelines for perform this approach.
Accendo GloGreen Digital HID (DHID) Ballast B600W-240M Electrical Test ReportAccendo Electronics Ltd.
Accendo commits to the success of your lighting retrofit/upgrade, or new Green lighting project with high-quality, safety approved products. Accendo products are manufactured to the utmost of quality assurance standards. All GloGreen Series Digital HID (DHID) ballasts undergo a thorough inspection before leaving the factory.
The following are examples of test reports completed for the GloGreen Series 50W, 70W, 150W, 200W/250W, 400W, 575W, 600W, 750W and 1000W DHID ballasts. Each individual GloGreen Series ballast must undergo a burn-in period after final assembly to ensure the DHID ballast is operational at its intended specification. Please note, these tested GloGreen Series ballasts can operate either Metal Halide (MH) or High-Pressure Sodium (HPS) bulbs; as indicated, and with equal energy efficiency.
Accendo GloGreen Digital HID (DHID) Ballast B600W-277M Electrical Test ReportAccendo Electronics Ltd.
Accendo commits to the success of your lighting retrofit/upgrade, or new Green lighting project with high-quality, safety approved products. Accendo products are manufactured to the utmost of quality assurance standards. All GloGreen Series Digital HID (DHID) ballasts undergo a thorough inspection before leaving the factory.
The following are examples of test reports completed for the GloGreen Series 50W, 70W, 150W, 200W/250W, 400W, 575W, 600W, 750W and 1000W DHID ballasts. Each individual GloGreen Series ballast must undergo a burn-in period after final assembly to ensure the DHID ballast is operational at its intended specification. Please note, these tested GloGreen Series ballasts can operate either Metal Halide (MH) or High-Pressure Sodium (HPS) bulbs; as indicated, and with equal energy efficiency.
NXP has announced a new 1800 W RF power transistor, the MRFX1K80. Click through and explore how NXP’s extra high voltage 65 V LDMOS process gives rise to a new generation of our MRFX series products.
•Designed a two stage OPAMP with a current mirror amplifier and a second CS stage along with miller compensation to provide sufficient Phase margin for stability.The circuit is also provided with temperature independent self-biased startup circuit.
•Our OPAMP exhibited a gain of 82.74dB, OVSR of 1.57V, Slew rate of 9.79V/us, Phase margin of 60 deg, GBW of 18.6 MHz, CMRR of 88.473dB, Power dissipation of 0.22mW with a 1.8V power supply.
FPC-Security provide the door access control system/devices at very affordable prices with free shipping like
Electromagnetic lock, Mag lock, Magnetic lock, Electric Lock one door.
Accendo GloGreen Digital HID (DHID) Ballast B600W-240M Electrical Test ReportAccendo Electronics Ltd.
Accendo commits to the success of your lighting retrofit/upgrade, or new Green lighting project with high-quality, safety approved products. Accendo products are manufactured to the utmost of quality assurance standards. All GloGreen Series Digital HID (DHID) ballasts undergo a thorough inspection before leaving the factory.
The following are examples of test reports completed for the GloGreen Series 50W, 70W, 150W, 200W/250W, 400W, 575W, 600W, 750W and 1000W DHID ballasts. Each individual GloGreen Series ballast must undergo a burn-in period after final assembly to ensure the DHID ballast is operational at its intended specification. Please note, these tested GloGreen Series ballasts can operate either Metal Halide (MH) or High-Pressure Sodium (HPS) bulbs; as indicated, and with equal energy efficiency.
Accendo GloGreen Digital HID (DHID) Ballast B600W-277M Electrical Test ReportAccendo Electronics Ltd.
Accendo commits to the success of your lighting retrofit/upgrade, or new Green lighting project with high-quality, safety approved products. Accendo products are manufactured to the utmost of quality assurance standards. All GloGreen Series Digital HID (DHID) ballasts undergo a thorough inspection before leaving the factory.
The following are examples of test reports completed for the GloGreen Series 50W, 70W, 150W, 200W/250W, 400W, 575W, 600W, 750W and 1000W DHID ballasts. Each individual GloGreen Series ballast must undergo a burn-in period after final assembly to ensure the DHID ballast is operational at its intended specification. Please note, these tested GloGreen Series ballasts can operate either Metal Halide (MH) or High-Pressure Sodium (HPS) bulbs; as indicated, and with equal energy efficiency.
NXP has announced a new 1800 W RF power transistor, the MRFX1K80. Click through and explore how NXP’s extra high voltage 65 V LDMOS process gives rise to a new generation of our MRFX series products.
•Designed a two stage OPAMP with a current mirror amplifier and a second CS stage along with miller compensation to provide sufficient Phase margin for stability.The circuit is also provided with temperature independent self-biased startup circuit.
•Our OPAMP exhibited a gain of 82.74dB, OVSR of 1.57V, Slew rate of 9.79V/us, Phase margin of 60 deg, GBW of 18.6 MHz, CMRR of 88.473dB, Power dissipation of 0.22mW with a 1.8V power supply.
FPC-Security provide the door access control system/devices at very affordable prices with free shipping like
Electromagnetic lock, Mag lock, Magnetic lock, Electric Lock one door.
Resumen
RISC:
RISC es una filosofía de diseño de CPU para computadoras que está a favor de conjuntos de instrucciones pequeñas y simples que toman menor tiempo para ejecutarse.
Características
Modelo de conjunto de instrucciones Load/Store (Cargar/Almacenar).
Arquitectura no destructiva de tres direcciones.
Instrucciones simples.
Ausencia de microcódigo.
Ejecución en conductos (pipelined).
Ejecución en ciclos únicos.
Principios
1. Analizar las aplicaciones para encontrar las operaciones claves.
2. Diseñar un bus de datos que sea óptimo para esas operaciones claves.
3. Diseñar instrucciones que realicen las operaciones clave utilizando el bus de datos.
4. Agregar nuevas instrucciones sólo si no hacen más lenta a la máquina.
5. Repetir el proceso para otros recursos.
Multiproceso
Es el uso de dos o más procesadores (CPU) en una computadora para la ejecución de uno o varios procesos (programas corriendo).
El sistema en que la memoria está conectada a los nodos de proceso establece el primer nivel de distinción entre diferentes sistemas multiprocesador:
Multiprocesadores de memoria distribuida
El sistema en que la memoria está conectada a los nodos de proceso establece el primer nivel de distinción entre diferentes sistemas multiprocesador:
Multiprocesadores de memoria distribuida
Son sistemas con múltiples procesadores que comparten un único espacio de direcciones de memoria.
Memoria Caché
Los sistemas de memoria multinivel (caché) son un esfuerzo para evitar el número de peticiones realizadas por cada CPU al bus.
La forma en que la memoria es actualizada por los caches locales puede tener un gran impacto en las prestaciones de un sistema multiprocesador. Básicamente hay dos métodos:
Escritura continua: Requiere que todas las escrituras realizadas en el caché actualicen asimismo los datos de la memoria principal.
Copia posterior: En este caso, la CPU puede modificar la línea de caché sin necesidad de actualizar inmediatamente la memoria principal.
Hay dos métodos para mantener cada línea de caché idéntica a las demás:
1. Escritura radiada: Requiere que la CPU que modifica los datos compartidos actualice los otros caches, para lo cual escribe en el bus la dirección de los datos, y los datos mismos, de modo que todos los dispositivos interesados (otras CPU’s) los capturen.
2. Escritura invalidada: Impide a una CPU modificar los datos compartidos en su caché hasta que otros caches han invalidado sus copias.
La arquitectura RISC también cuenta con sus ventajas y desventajas y esto lo hacen que no sea una arquitectura perfecta.
A Soft Switched Dual Buck Inverter with Series Connected Diodes and Single In...paperpublications3
Abstract: In an inversion system, high reliability is one of the main targets pursuing. Some problems will threaten the reliability of the system, such as, the shoot through issue and the failure of reverse recovery. The dual buck inverters can solve the above problems without adding dead time. A new topology of dual buck inverter with series connected diodes and a single inductor is presented here. The system retains the advantage of no reverse recovery of body diode. The inverter has just one filter inductor, which can make the volume and weight of the system decreased observably and improve the integration. By providing soft switching techniques the power loss can be well reduced. A resonant circuit contributes to reduced switching loss by providing ZVS property. The whole system is simulated in PSIM environment. This inverter retains the advantage of high reliability. A PIC microcontroller is used to generate control pulses since it is fast and easy to implement program when we compare with other microcontrollers. The ease of programming and interfacing with other peripherals make PIC a successful microcontroller. A two level inverter output can be well verified at the output of the dual buck inverter without any reverse recovery loss.
Keywords: Body diode, PSIM, Reverse recovery, Soft Switching, SPWM, ZCS, ZVS.
Title: A Soft Switched Dual Buck Inverter with Series Connected Diodes and Single Inductor
Author: Alaka K, Prof. Jeena Joy, Prof. Kavitha Issac
ISSN 2349-7815
International Journal of Recent Research in Electrical and Electronics Engineering (IJRREEE)
Paper Publications
Threshold voltage model for hetero-gate-dielectric tunneling field effect tra...IJECEIAES
In this paper, a two dimensional analytical model of the threshold voltage for HGD TFET structure has been proposed. We have also presented the analytical models for the tunneling width and the channel potential. The potential model is used to develop the physics based model of threshold voltage by exploring the transition between linear to exponential dependence of drain current on the gate bias. The proposed model depends on the drain voltage, gate dielectric near the source and drain, silicon film thickness, work function of gate metal and oxide thickness. The accuracy of the proposed model is verified by simulation results of 2-D ATLAS simulator. Due to the reduction of the equivalent oxide thickness, the coupling between the gate and the channel junction enhances which results in lower threshold voltage. Tunneling width becomes narrower at a given gate voltage for the optimum channel concentration of 10 16 /cm 3 . The higher concentration in the source (N s ) causes a steep bending in the conduction and valence bands compared to the lower concentration which results in smaller tunneling width at the source-channel interface.
The MSc defense ceremony was held on 6-7-2017 in Mansoura University, Faculty of Engineering. This presentation is shared to help MSc students in Faculty of Engineering prepare their thesis presentation and ease their tension before their presentation time
IJRET : International Journal of Research in Engineering and Technology is an international peer reviewed, online journal published by eSAT Publishing House for the enhancement of research in various disciplines of Engineering and Technology. The aim and scope of the journal is to provide an academic medium and an important reference for the advancement and dissemination of research results that support high-level learning, teaching and research in the fields of Engineering and Technology. We bring together Scientists, Academician, Field Engineers, Scholars and Students of related fields of Engineering and Technology
4. Content
Introduction
Signal transmission in LV cables
Case 1: Interconnection
• 1. Simulation OIP cable
• 2. Interconnection network
Case 2: Simulated partial discharge at substation
• 1. Interconnection
• 2. Branching
• 3. Parallel cables connect at the substation
Conclusion
EES PAGE 326-2-2016
5. Case studies on cable connections
• Case 1
To analyze the effects
when different types of
4-conductor cables are
used in interconnection.
EES PAGE 426-2-2016
Oil-impregnated-paper(OIP)
insulated cable
PVC cable
6. Case 1: Simulation OIP cable
EES PAGE 526-2-2016
Cross-section of the cable used in software
• Cable Under Test (CUT)
Lead
Oil-impregnated-paper(OIP)
Copper
12. Case 1: Simulation OIP cable
EES PAGE 1126-2-2016
• Propagation coefficients
γ 𝒙 = α 𝒙 + 𝒋β 𝒙
𝒗 𝒑,𝒙 =
β 𝒙
ω
α 𝒙 is the attenuation coefficient
for mode x
𝒗 𝒑,𝒙 is the phase velocity for
mode x
13. Case 1: Interconnection network
• Schematic of simulated interconnection network
EES PAGE 1226-2-2016
𝑽 𝒄𝒂𝒃𝒍𝒆
𝒕𝒆𝒓𝒎𝒊𝒏𝒂𝒕𝒊𝒐𝒏/𝒊𝒏𝒕𝒆𝒓𝒄𝒐𝒏𝒏𝒆𝒄𝒕𝒊𝒐𝒏
𝑰 𝒄𝒂𝒃𝒍𝒆
𝒕𝒆𝒓𝒎𝒊𝒏𝒂𝒕𝒊𝒐𝒏/𝒊𝒏𝒕𝒆𝒓𝒄𝒐𝒏𝒏𝒆𝒄𝒕𝒊𝒐𝒏
14. Case 1: Interconnection network
• Relation between the beginning and end of a cable
𝑰(𝟎)
− 𝑰(𝒍)
=
𝒀 𝑺 𝒀 𝑴
𝒀 𝑴 𝒀 𝑺
𝑽(𝟎)
𝑽(𝒍)
EES PAGE 1326-2-2016
22. Content
Introduction
Signal transmission in LV cables
Case 1: Interconnection
• 1. Simulation OIP cable
• 2. Interconnection network
Case 2: Simulated partial discharge at substation
• 1. Interconnection
• 2. Branching
• 3. Parallel cables connect at the substation
Conclusion
EES PAGE 2126-2-2016
23. Case studies on cable connections
PAGE 2226-2-2016
• Case 2
To analyze the effects of the discharges which will
be observed in the substation for different network
models of the cable.
24. Case 2: Interconnection network
PAGE 2326-2-2016
A resistance of 5.1 mΩ and reactance of 56 µH in series per phase.
EES
Transformer
substation
Current
source
at 130 m
25. Case 2: Branching
PAGE 2426-2-2016EES
A 10 kVA household branch is jointed at 50 meters of the main cable
Transformer
substation
Current
source
at 130 m
26. Case 2: Simulated PD
• The current at the substation is calculated by the
admittance of the cable and voltage:
𝑰 𝒔𝒖𝒃 = 𝒀 𝑺 𝑽 𝒔𝒖𝒃 + 𝒀 𝑴 𝑽 𝒄𝒂𝒃𝒍𝒆_𝒆𝒏𝒅
𝑽 𝒔𝒖𝒃 is the voltage at the substation, 𝑽 𝒄𝒂𝒃𝒍𝒆_𝒆𝒏𝒅 is the
voltage at the node where the cable to the substation
is connected.
PAGE 2526-2-2016EES
27. Case 2: Simulated PD (Result)
PAGE 2626-2-2016
Current(mA)
Without PVC cable
Interconnection
Branching
Time (ms)
30. Case 2: Parallel cables at the substation
PAGE 2926-2-2016
The simplified model of
the substation which is
connected with five
cables at the bus-bar.
The impedance of the
parallel cables is equal
to the characteristic
impedance of the cable
divided by 4.
EES
31. Case 2: Simulated PD (Result)
PAGE 3026-2-2016
Current(mA)
Without PVC cable
Interconnection
Branching
Time (ms)
32. Case 2: Simulated PD (Result)
EES PAGE 3126-2-2016
Comparison of different network models, the parallel cables are either
included or not included
33. Conclusions
The effect is not significant, since the PVC section
makes up only for a short length in the complete
connection.
The branching point is effected the PDs.
More parallel cables will be effected the PDs.
In the future?
PAGE 3226-2-2016EES
Good morning, Thank you for coming my final presetion, my graduated project is serval case studies on low voltage cable connections.
I’m going to start with a introduction part. Then second part is a detailed explanation focus on the two case studies. Finally the conclusions will be given.
Let’s beginning from introduction. This picture is a simplified low voltage grid. The electrical(扣) power will be delivered from medium voltage system. then through the transformer substation become the low voltage electrical power and distribute(特) power to homes and businesses. Compared with the medium and high voltage systems, low voltage system is regarded as the most reliable electric power distribution system. because the few customers are connected to a feed(扁嘴:飞的) cable, so the impact(因怕) of cable failure in the low voltage system on the power grid operator is lower. That’s why the research and attention(饿ten神) on the condition monitoring (重音在前)of the low voltage cable are so limited. but, as the working life of the cable is extending(以可四ten订), it was found that the number of failures in low voltage cable is increasing slowly but steadily(四带的李).Therefore, it is necessary to study an effective way of condition monitoring of low voltage cables.
In order to monitor the cable system, the first thing is need to analyze the transmission characteristics of the cable.
In the Netherlands, OIP cable has been used in the low voltage power system for many years. When a cable failure, the new cable need to replace the fault section. however, due to environmental and health with manufacturing issues, OIP cable is not produced any more. PVC is used for insulation in new cables, and is used to replace OIP cable when faults happen.
But the two cables present different cable characteristics due to different applied materials. Therefore, when these two cables are connected, the new transmission line characteristics need to be known. The PVC cable already was modeled in previous research. the model of OIP insulated cables is simulated in this project.
The cable under test consists of four copper conductors, a lead(里的) earth screen and OIP insulation. For high-frequency signals the cable can be considered as a 4-fold rotation symmetric(涩买track) transmission line with earth screen. The number definition(带for 内神) for the four currents and voltages are shown in figure.
The model(麻都) is base on mulit-conductor transmission line theory.
The theory gives the differential equations of the voltage and current which are related with impedance and admittance.
impedance and admittance are four-by-four matrice(美垂死) of per-unit length parameters of resistance, inductance, conductance and capacitance. These per-unit parameters are measured in electromagnetic field simulation software.
voltage and current are four dimensional(带门神no) vectors(外) at position z along the length of the cable.
In order to find out the voltage and current at any point along the Z-axis. The relation between the actual and modal(某都)voltages and currents need to be understood. The objective is to decouple these second-order equations by finding a appropriate Tv and Ti. Tv and Ti need to diagonalize(带艾格no来自) the product by ZY. This part will be equal to the supare of the gamma, so gamma is a diagonal matrix.
According to Tv and Ti, the voltage can be divided four mode. because of the symmetry(塞米吹) of the cable, the second and third mode have equal properties. Therefore, in the following analysis will focuses on three different modes, show with 1,2 and 3.
Red
the characteristic impedance matrix is related with per-unit-length parameters, transformation matrix and gamma. And also can use the transformation matrice to get the modal charactersitc impednace matrix.
Here is the simulated modal characteristic impedance for the three modes. Compare with PVC previous reach, the impedance of OIP is lower than PVC cable.
As the frequency increase, the propagation velocities increase become a steady value at high frequency. They are similar for all propagation modes, since homogenous (厚某真你啊四) insulation material is assumed.
The attenuation coefficient is realted to losses in the dielectrics(带) and losses in conductor and earth screen. These losses also increase with higher frequency.
the transmission line characteristic for OIP and PVC cable are known. the interconnection network can be simulated in matlab. The network model include two OIP cables and one PVC cable. This model consists of four network. At the termination connect with 50 Ohm impedances.
the relation between the beginning and end of cable for currents and voltages are given also from multi-conductor transmission line theory. Ys is the self admittance and Ym is the mutual(谬 戳) admittance of the cable.
And current can be presented by voltage and self and mutul(谬 戳) admittance. And a source vector P can be defined for all sources at the network. The final equation can be presented the relation for each cable section at each network.
each network equations need to satisfied with the kirchhoff’s(可吃hoff) voltage and current law. The constraint(肯四坠t) conditions set 1 for column(call) of Y means that V has a corresponding(course 帮顶) voltage fore each cable line. Set 1 for a column of Z means that I has a corresponding current and a corresponding voltage for each cable line. They are added together should be equal the source vector.
At the tremination network, all cables are terminated in 50ohm impedances , so 50 is placed into Z, meanwhile, set Vs(t) into P as the corresponding equation.
Total The admittance matrix related with voltage and source vector
The input voltage source is a Gaussian(高神) signal with a pulse width(po四 胃子(咬舌))of 30 nanosecond(纳no)in time domain. In the simulation, the voltage measured with a the phase-to-phase and phase-to-ground. Because the results have same properties, so take the phase-to-phase result as an example. In order to compare the PVC section effect of the voltage signal, the OIP cable without PVC cable section also be simulated. The solid(骚里的) lines is with PVC section. Dashed(带是t) line is without PVC section.
The solid(骚里的) lines is with PVC section. Dashed(带是t) line is without PVC section.
because the PVC section will increase loss and damping, the output voltage decrease slightly with the length of the PVC section is increasing. And observe the reflected signal, a larger part is reflected back with decreasing the length of last OIP section and transmitted remainder(瑞闷der) is less(来s).
Condition monitoring(重音在前) actually is to monitor the signal transient(穿znt). In these systems, certain discharges may happen at damage points. These discharges induce fast current transients. Such signals can be measured at substation. in case 2, mainly simulated the effects of the discharges which will be observed in the substation for different network models.
This partial discharge signal is extracted from previous experiments for an artificially(儿提飞show里) damaged PVC cable. this fault will induced partial discharge. In this simulation is cut off a part of the signal inject into the different network model.
a power transformer replaces the voltage source, the total length of the cable still 150 meters. First OIP cable is 70 meters. PVC cable section is 10 meters and last OIP cable section is 70 meters. Inserting(因色儿厅) a fault signal as a current source at a distance of 130 meters. the other side is terminated with 10 kilo-ohm resistance as an open circuit state. The current signal source is in parallel with a an infinite impedance.
An other model is an OIP cable with a household branch(不软吃). The OIP cable with 150 meters and with 10 meters branch cable length. The household branch is jointed at 50 meters of the main cable.
The current at the substation is calculated by previous equation.
In order to compare the PVC section effect of the voltage signal, the OIP cable without PVC cable section also be simulated. The current shape of OIP cable without PVC cable and interconnection cable are similar. But the model of the OIP cable with a household branch(不软吃), the signal loss at the substation is largest and can be seen as distortion(第四到神).
Can be analyzed three model separately. Due to the reflection equation, in the model without PVC cable. the current signal will be reflected between the substation and the end of the cable. at the model of interconnection, the reflected signal also will be produced at the joint cable. at the branching(不软) model, the substation and the branch section can be seen as parallel circuits. The signal will go into two cables separately. Therefore, the different reflection and transmission coefficient will affect the signal. The superposition is produced by the injected current and reflected current at the branching point. A large attenuation and distortion(第四到神) of the signal will happen.
In a practical(铺ruai提扣) situation, many cables are in parallel to transport electricity from substation. therefore, the impact of the parallel cables on the substation is also simulated.
This is a simplified model of the substation which is connected with five cables at the bus-bar. The one at the bottom is the configurations are connected with different network model. In this simulation, the parallel cables are regards as the impedance. so the impedance of the substation will be changed.
From the results can be seen that parallel cables have strong impact on the current signal at the substation.
The rms value is taken to compare. In real low voltage transformer substation, more than five cables can be connected to one bus-bar. And many branches will be connected to the cable in an actual low voltage grid. The signal will be flowed to these cables and produced reflated and transmitted signals. Therefore, it would make it more attenuation and distortion(第四到神) of the signal .
The PVC cable will effect the signal transmission in interconnection network because more losses and damping will happen in PVC cable. However, the effect is not significant(say个你飞肯t), since the PVC section makes up only for a short length in the complete connection.
In the future, the branch connect with interconnect network. The PD signal become short circuit, what signal can be observed at the substation. 10 kilo-power household. If connected a factory or more branches connect with one main cable. how the signal changes.