Indonesian Journal of Electrical Engineering and Computer Science
This manuscript discusses the computation of electromagnetic forces on a disc-type winding due to... more This manuscript discusses the computation of electromagnetic forces on a disc-type winding due to a standard switching impulse (SSI). First, the resistances, inductances and capacitances (RLC) of a 30 MVA, 33/11 kV disc-type distribution transformer were estimated to obtain the winding equivalent circuit. The transient voltage waveforms for each of the disc layers and corresponding resonances of the windings under the SSI were then obtained in time domains. Next, the axial and radial force distributions in the disc winding due to the SSI were computed. The forces on each disc layer and along the disc windings due to the SSI were computed based on the analytical and numerical methods via the finite element method (FEM) respectively. The non-uniform switching impulse voltage distribution results in non-uniform force distribution along the disc winding. The magnitude of the axially directed force on the disc winding is found to be higher as compared to the radially directed force.
The Indonesian Journal of Electrical Engineering and Computer Science (IJEECS), 2023
This manuscript discusses the computation of electromagnetic forces on a disc-type winding due to... more This manuscript discusses the computation of electromagnetic forces on a disc-type winding due to a standard switching impulse (SSI). First, the resistances, inductances and capacitances (RLC) of a 30 MVA, 33/11 kV disctype distribution transformer were estimated to obtain the winding equivalent circuit. The transient voltage waveforms for each of the disc layers and corresponding resonances of the windings under the SSI were then obtained in time domains. Next, the axial and radial force distributions in the disc winding due to the SSI were computed. The forces on each disc layer and along the disc windings due to the SSI were computed based on the analytical and numerical methods via the finite element method (FEM) respectively. The non-uniform switching impulse voltage distribution results in non-uniform force distribution along the disc winding. The magnitude of the axially directed force on the disc winding is found to be higher as compared to the radially directed force.
2022 IEEE International Conference in Power Engineering Application (ICPEA), 2022
This paper presents the calculations and simulation of surge distributions and estimation of axia... more This paper presents the calculations and simulation of surge distributions and estimation of axial and radial forces experienced by a disc-type winding due to Switching Impulse (SI). Firstly, the resistance, inductance and capacitance (RLC) of the high voltage (HV) disc winding were computed to construct the winding equivalent circuit. A standard switching impulse wave generated from a switching impulse generator circuit was subjected to the HV winding to obtain the transient resonance affecting the disc windings. The force in axial and radial components was then calculated through the voltage surge distributions in the windings. It is found that the highest switching surge is experienced by the topmost disc winding. An uneven voltage distribution is detected among the topmost disc, disc 96 and disc 93, which results in voltage stress. A conclusion is drawn that the highest force would be exerted on the topmost disc, disc 96.
International Journal of Power Electronics and Drive System (IJPEDS), 2019
Monitoring and diagnosis of power transformer in power systems have been examined and debated sig... more Monitoring and diagnosis of power transformer in power systems have been examined and debated significantly in last few decades. Recently, more researchers have expressed their interest in these issues as the utilities and network operators operating under a rising cost-effecting pressure. Especially, in studying to monitor winding faults which is found to be the most common fault within transformers. This paper addresses the issue of the effect of inter-windings short circuit fault in a Dyn11 connected transformer. The specific aim is to study the effect of fault at winding of other phases to the response of measured phase. Frequency Response Analysis (FRA) which is discovered to be a powerful and sensitive method to examine and evaluate the condition, including the mechanical reliability of the transformer windings is used.
International Journal of Power Electronics and Drive System (IJPEDS) , 2020
Sweep frequency response analysis (SFRA) is a reliable method for detection and diagnosis of faul... more Sweep frequency response analysis (SFRA) is a reliable method for detection and diagnosis of faults in the active part of transformers. However, although SFRA is widely employed, the interpretation of SFRA signature is still a challenge and require experts to analyse them. This is due to lack of guideline and standard for SFRA signature interpretation and clarification. This paper presents the interpretation of SFRA signature by classification and quantification on inter-turn short circuit fault on the transformer winding. The short-circuited turns fault on HV winding phase "A" was practically simulated on three different units of three-phase transformers. The results of simulated fault are presented and discussed. A conclusion was drawn which provides the interpretation of the SFRA response due to inter-turn short circuit fault case by using a statistical indicator which is NCEPRI algorithm.
International Journal of Power Electronics and Drive System (IJPEDS), 2020
Different techniques for monitoring the transformer condition are continuously discussed. This is... more Different techniques for monitoring the transformer condition are continuously discussed. This is due to the fact that transformers are one of the most expensive components in the power system network. Not to mention the cost to fix any failure occurred in the transformer that have becoming more expensive nowadays. Frequency response analysis (FRA) is found to be the best method to monitor the transformer reliability. This paper presents a continuation of study presented in previous paper [1]. The study performed a laboratory test to show that the response of a normal winding phase A can be affected by short circuit fault which occurred at LV winding phase a, b, and c. To further investigate, current paper performed FRA measurement and applied fault on all phases. The same procedure is repeated on a distribution transformer to verify the findings. This is to examine the effect of fault at winding of other phases to the response of measured phase.
Indonesian Journal of Electrical Engineering and Computer Science
This manuscript discusses the computation of electromagnetic forces on a disc-type winding due to... more This manuscript discusses the computation of electromagnetic forces on a disc-type winding due to a standard switching impulse (SSI). First, the resistances, inductances and capacitances (RLC) of a 30 MVA, 33/11 kV disc-type distribution transformer were estimated to obtain the winding equivalent circuit. The transient voltage waveforms for each of the disc layers and corresponding resonances of the windings under the SSI were then obtained in time domains. Next, the axial and radial force distributions in the disc winding due to the SSI were computed. The forces on each disc layer and along the disc windings due to the SSI were computed based on the analytical and numerical methods via the finite element method (FEM) respectively. The non-uniform switching impulse voltage distribution results in non-uniform force distribution along the disc winding. The magnitude of the axially directed force on the disc winding is found to be higher as compared to the radially directed force.
The Indonesian Journal of Electrical Engineering and Computer Science (IJEECS), 2023
This manuscript discusses the computation of electromagnetic forces on a disc-type winding due to... more This manuscript discusses the computation of electromagnetic forces on a disc-type winding due to a standard switching impulse (SSI). First, the resistances, inductances and capacitances (RLC) of a 30 MVA, 33/11 kV disctype distribution transformer were estimated to obtain the winding equivalent circuit. The transient voltage waveforms for each of the disc layers and corresponding resonances of the windings under the SSI were then obtained in time domains. Next, the axial and radial force distributions in the disc winding due to the SSI were computed. The forces on each disc layer and along the disc windings due to the SSI were computed based on the analytical and numerical methods via the finite element method (FEM) respectively. The non-uniform switching impulse voltage distribution results in non-uniform force distribution along the disc winding. The magnitude of the axially directed force on the disc winding is found to be higher as compared to the radially directed force.
2022 IEEE International Conference in Power Engineering Application (ICPEA), 2022
This paper presents the calculations and simulation of surge distributions and estimation of axia... more This paper presents the calculations and simulation of surge distributions and estimation of axial and radial forces experienced by a disc-type winding due to Switching Impulse (SI). Firstly, the resistance, inductance and capacitance (RLC) of the high voltage (HV) disc winding were computed to construct the winding equivalent circuit. A standard switching impulse wave generated from a switching impulse generator circuit was subjected to the HV winding to obtain the transient resonance affecting the disc windings. The force in axial and radial components was then calculated through the voltage surge distributions in the windings. It is found that the highest switching surge is experienced by the topmost disc winding. An uneven voltage distribution is detected among the topmost disc, disc 96 and disc 93, which results in voltage stress. A conclusion is drawn that the highest force would be exerted on the topmost disc, disc 96.
International Journal of Power Electronics and Drive System (IJPEDS), 2019
Monitoring and diagnosis of power transformer in power systems have been examined and debated sig... more Monitoring and diagnosis of power transformer in power systems have been examined and debated significantly in last few decades. Recently, more researchers have expressed their interest in these issues as the utilities and network operators operating under a rising cost-effecting pressure. Especially, in studying to monitor winding faults which is found to be the most common fault within transformers. This paper addresses the issue of the effect of inter-windings short circuit fault in a Dyn11 connected transformer. The specific aim is to study the effect of fault at winding of other phases to the response of measured phase. Frequency Response Analysis (FRA) which is discovered to be a powerful and sensitive method to examine and evaluate the condition, including the mechanical reliability of the transformer windings is used.
International Journal of Power Electronics and Drive System (IJPEDS) , 2020
Sweep frequency response analysis (SFRA) is a reliable method for detection and diagnosis of faul... more Sweep frequency response analysis (SFRA) is a reliable method for detection and diagnosis of faults in the active part of transformers. However, although SFRA is widely employed, the interpretation of SFRA signature is still a challenge and require experts to analyse them. This is due to lack of guideline and standard for SFRA signature interpretation and clarification. This paper presents the interpretation of SFRA signature by classification and quantification on inter-turn short circuit fault on the transformer winding. The short-circuited turns fault on HV winding phase "A" was practically simulated on three different units of three-phase transformers. The results of simulated fault are presented and discussed. A conclusion was drawn which provides the interpretation of the SFRA response due to inter-turn short circuit fault case by using a statistical indicator which is NCEPRI algorithm.
International Journal of Power Electronics and Drive System (IJPEDS), 2020
Different techniques for monitoring the transformer condition are continuously discussed. This is... more Different techniques for monitoring the transformer condition are continuously discussed. This is due to the fact that transformers are one of the most expensive components in the power system network. Not to mention the cost to fix any failure occurred in the transformer that have becoming more expensive nowadays. Frequency response analysis (FRA) is found to be the best method to monitor the transformer reliability. This paper presents a continuation of study presented in previous paper [1]. The study performed a laboratory test to show that the response of a normal winding phase A can be affected by short circuit fault which occurred at LV winding phase a, b, and c. To further investigate, current paper performed FRA measurement and applied fault on all phases. The same procedure is repeated on a distribution transformer to verify the findings. This is to examine the effect of fault at winding of other phases to the response of measured phase.
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