• Title/Summary/Keyword: Low frequency ECT

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Development of New Low Frequency ECT Sensor to Detect Inner Defects(I) - Characteristic of Loss of Induced Electromotive Force - (내부결함 검출 가능한 저주파 ECT 센서개발(I) - 전자기 유도기전력 손실량의 특성-)

  • Park, Jeong-Ung;Jang, Mun-Seok;Gim, Guk-Ju;Kim, Beom-Ki
    • Journal of Welding and Joining
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    • v.33 no.4
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    • pp.57-62
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    • 2015
  • Non-destructive techniques are used widely in the metal industry in order to control the quality of materials. Eddy current testing(ECT) is one of the most extensively used non-destructive techniques for inspecting electrically conductive materials at very high speeds that does not require any contact between the test piece and the sensor. The New ECT sensor which can detect inner defects was developed regardless the condition of surface. This sensor is verified to do experiment which measure the loss of induced electromotive force. The loss of induced electromotive force was measured in 5.4% and this low frequency ECT device can detect internal defects at depth 20 mm.

Development of New Low Frequency ECT Sensor to Detect Inner Defects(II) - Application to Welding Specimens Included Defects - (내부결함 검출 가능한 저주파 ECT 센서개발(II) - 결함을 가진 소형 용접시험편에 적용 -)

  • Park, Jeong-Ung;Jang, Mun-Seok;Gim, Guk-Ju;Kim, Beom-Ki
    • Journal of Welding and Joining
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    • v.33 no.4
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    • pp.63-67
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    • 2015
  • Non-destructive techniques are used widely in the metal industry in order to control the quality of materials. Eddy current testing(ECT) is one of the most extensively used non-destructive techniques for inspecting electrically conductive materials at very high speeds that does not require any contact between the test piece and the sensor. The New ECT sensor which can detect inner defects was developed regardless the condition of surface. This sensor is verified to do experiment which measure the loss of induced electromotive force. The loss of induced electromotive force was measured in 5.4% and this low frequency ECT device can detect internal defects at depth 20 mm.

Simulation and Analysis of ECT Signals Obtained at Tubesheet and Tube Expansion Area

  • Song, Sung-Chul;Lee, Yun-Tai;Jung, Hee-Sung;Shin, Young-Kil
    • Journal of the Korean Society for Nondestructive Testing
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    • v.26 no.3
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    • pp.174-180
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    • 2006
  • Steam generator (SG) tubes are expanded inside tubesheet holes by using explosive or hydraulic methods to be fixed in a tubesheet. In the tube expansion process, it is important to minimize the crevice gap between expanded tube and tube sheet. In this paper, absolute and differential signals are computed by a numerical method for several different locations of tube expansion inside and outside a tubesheet and signal variations due to tubesheet, tube expansion and operating frequencies are observed. Results show that low frequency is good for detecting tubesheet location in both types of signals and high frequency is suitable for sizing of tube diameter as well as the detection of transition region. Also learned is that the absolute signal is good for measuring tube diameter, while the differential signal is good for locating the top of tubesheet and both ends of the transition region. In the case of mingled anomaly with tube expansion and tubesheet, low frequency inspection is found to be useful to analyze the mixed signal.

An Experimental Study on the Development of a Cabin Noise Reduction System for Improving Ship Habitability (선박 거주성 향상을 위한 선실 소음 저감 시스템 개발에 관한 실험적 연구)

  • Young-Choul Seo;Deug-Bong Kim;Chol-Seong Kim
    • Journal of the Korean Society of Marine Environment & Safety
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    • v.29 no.6
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    • pp.620-627
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    • 2023
  • Ship noise is one of the important factors for the living and health of seafarers, and ef orts to reduce ship noise are actively underway. There are two methods of noise reduction: passive noise Control (PNC) and active noise control (ANC). Unlike cars and airplanes, ANC is not widely used for noise reduction on ships. This study aimed to reduce the noise generated in the engine room by using soundproof panels and high-frequency vibration generators, as well as active noise control (ANC). For this purpose, an experimental model was made using an acrylic box, and the noise reduction effect was measured under four conditions. The experimental results are as follows: First, the soundproof panel had a noise reduction effect in all ranges from 55 dB to 85 dB. In the case of using a high-frequency vibration generator, there was no ef ect in the low noise range such as 55 dB(A), but there was a noise reduction effect in the high noise range such as 70.8 dB(A) and 85 dB(A).Second, when the soundproof panel and the high-frequency vibration generator were used simultaneously, the noise reduction ef ect was up to -2.2 dB(A). The results of this experiment were obtained from an experimental model made of acrylic, and they may be different from actual ships made of steel plate. In future studies, we plan to experiment using iron plate (considering the material, thickness, and structure) used in actual ships. We hope that this study will help to improve the living environment and health of seafarers on ships.