日本語フィールド
著者:Faming Sun, Yongning Bian, Hirofumi Arima, Yasuyuki Ikegami and Xinsheng Xu題名:Strength characteristics of the self-sustained wave in grooved channels with different groove length発表情報:Heat and Mass Transfer 巻: 46 ページ: 1229-1237キーワード:概要:抄録:The self-sustained oscillations arising in a series of grooved channels are investigated experimentally. Pressure drop, time-averaged and time-various local pressure in the grooved channels with six kinds of groove length are measured with the differential transducer and the pressure sensor, respectively, and the flow structures are visualized using the aluminum dust method. The local pressure signal shows that the self-sustained wave appears in the first or second frequency, and the Strouhal number, based on the nature frequency of the self-sustained wave, is almost equivalent for the first or second frequency in the same channel. Meanwhile, the Strouhal number for each channel decreases monotonously with the groove length. Furthermore, it is found that increasing pressure will result in higher amplitude of the self-sustained wave, this behavior is significant for the efficient heat transfer in practical engineering.英語フィールド
Author:Faming Sun, Yongning Bian, Hirofumi Arima, Yasuyuki Ikegami and Xinsheng XuTitle:Strength characteristics of the self-sustained wave in grooved channels with different groove lengthAnnouncement information:Heat and Mass Transfer Vol: 46 Page: 1229-1237An abstract:The self-sustained oscillations arising in a series of grooved channels are investigated experimentally. Pressure drop, time-averaged and time-various local pressure in the grooved channels with six kinds of groove length are measured with the differential transducer and the pressure sensor, respectively, and the flow structures are visualized using the aluminum dust method. The local pressure signal shows that the self-sustained wave appears in the first or second frequency, and the Strouhal number, based on the nature frequency of the self-sustained wave, is almost equivalent for the first or second frequency in the same channel. Meanwhile, the Strouhal number for each channel decreases monotonously with the groove length. Furthermore, it is found that increasing pressure will result in higher amplitude of the self-sustained wave, this behavior is significant for the efficient heat transfer in practical engineering.