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论文:2019,Vol:37,Issue(3):547-551 |
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引用本文: |
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梁波, 侯帅, 白梅娟, 刘建辉, 耿华, 刘继通. 双缝隙喷嘴射流冲击正弦形状带材过程压力系数的研究[J]. 西北工业大学学报 |
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LIANG Bo, HOU Shuai, BAI Meijuan, LIU Jianhui, GENG Hua, LIU Jitong. Study on Pressure Coefficient in Process of Double Slot Nozzle Jet Impingement on Sinusoidal Colliding Strip[J]. Northwestern polytechnical university |
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| 双缝隙喷嘴射流冲击正弦形状带材过程压力系数的研究 |
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| 梁波1, 侯帅2, 白梅娟2, 刘建辉2, 耿华2, 刘继通2 |
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1. 西北工业大学 自动化学院, 陕西 西安 710072;
2. 河北工程大学 信息与电气工程学院, 河北 邯郸 056038 |
| 摘要: |
| 气垫炉广泛应用于铝带、铜带和硅钢的热处理过程,而双缝隙喷嘴是气垫炉装置的核心部件。研究悬浮带材表面的压力系数分布特性,可以为气垫炉的高效高值生产奠定重要理论依据。研究了Re=48 194~12 048、高度H/D=1~3、间距L/D=17.2和正弦幅值A=0~30 mm时,双缝隙喷嘴射流冲击正弦形状带材表面的压力系数分布规律。研究结果表明:雷诺数Re对压力系数Cp以及主驻点与第二驻点的压力系数差值影响并不明显;压力系数Cp随着H/D的增大而减小,而双缝隙喷嘴驻点处的压力系数与非驻点处的压力系数差值随着H/D的增大而增大。随着正弦幅值A的增大,主驻点位置逐渐向x/D=0移动;压力系数Cp随着正弦幅值A的增加而减小;随着L/D的减小,主驻点位置向喷嘴的几何中心线移动,第二驻点的压力系数逐渐增大。 |
| 关键词:
气垫炉
双缝隙喷嘴
压力系数
雷诺数
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| Study on Pressure Coefficient in Process of Double Slot Nozzle Jet Impingement on Sinusoidal Colliding Strip |
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| LIANG Bo1, HOU Shuai2, BAI Meijuan2, LIU Jianhui2, GENG Hua2, LIU Jitong2 |
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1. School of Automation, Northwestern Polytechnical University, Xi'an 710072, China;
2. School of Information and Electrical Engineering, Hebei University of Engineering, Handan 056038, China |
| Abstract: |
| Air cushion furnace is widely used in the heat treatment process of aluminum strip, copper strip and silicon steel, and the double slot nozzle is the core part of the air cushion furnace device. Studying the distribution characteristics of the surface pressure coefficient of the strip during the suspension process could provide important theoretical references for the high-efficiency and high-value production of the air-cushion furnace. In this paper, the distribution of pressure coefficients is studied under the conditions of Re=48 194~12 048, high H/D=1~3, spacing L/D=17.2 and sinusoidal amplitude A=0~30 mm. The results show that with the decrease of L/D, the position of the main stop point moves to the center line of the nozzle, and the value of the second stop point increases gradually, and with the increase of the sinusoidal amplitude A, the position of the main stop point moves gradually to x/D=0. The pressure coefficient Cp decreases with the increase of sinusoidal amplitude A, the pressure coefficient Cp decreases with the increase of H/D, and the difference between the pressure coefficient at the stationary point of the double-slot nozzle and the pressure coefficient at the non-stationary point increases with the increase of H/D. This study provides an important theoretical basis for the design of double slot nozzles in air cushion furnace. |
| Key words:
air cushion furnace
dual-slot nozzle
pressure coefficient
Reynolds number
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| 收稿日期: 2018-05-20
修回日期:
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| DOI: 10.1051/jnwpu/20193730547 |
| 基金项目: 河北省自然科学基金(E2017402115)资助 |
| 通讯作者:
Email: |
| 作者简介: 梁波(1984-),西北工业大学副研究员、博士,主要从事从热处理装备、电力电子及电力传动研究。
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| 作者相关文章 |
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| 梁波 在本刊中的所有文章 |
| 侯帅 在本刊中的所有文章 |
| 白梅娟 在本刊中的所有文章 |
| 刘建辉 在本刊中的所有文章 |
| 耿华 在本刊中的所有文章 |
| 刘继通 在本刊中的所有文章 |
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