低压干燥条件下热湿氧协同输送管道摩擦阻力特性
Frictional resistance characteristics of heat-moisture-oxygen co-conveying pipelines under low-pressure drying conditions
摘要:
青藏高原低压缺氧干燥的特殊气候条件使建筑室内有加湿增氧的需求,而现有研究未考虑低压和加湿增氧导致空气组分变化对管道摩擦阻力特性的影响。本文以输送热湿氧直管道为对象,研究了大气压力、入口流速、湿氧浓度、管径、壁面粗糙度等因素对摩擦阻力的影响。结果表明:当管道仅送热时,5 km海拔下管道单位管长摩擦阻力约为常压下的62%;当热湿氧协同输送时,供氧浓度升高可使管道单位管长摩擦阻力增大约8.4%,而增大相对湿度对单位管长摩擦阻力影响较小,仅减小2%;单位管长摩擦阻力随入口流速的增大而增大,最大可增大约16倍;在壁面粗糙度较小时(K=0.03~0.20 mm),处于水力光滑区,阻力不随粗糙度的增大而变化;当进入混合摩擦区(K>0.40 mm)时,阻力开始随粗糙度的增大而增大,最大可增大约45%。最后给出了低压条件下热湿氧协同输送管道在不同工况下的摩擦阻力推荐值。
Abstract:
The special climatic conditions of the Qinghai-Xizang Plateau, which are low-pressure, oxygen-deficient and dry, make the need for humidification and oxygenation in buildings, while the existing studies have not considered the effects of changes in the air components due to low-pressure and humidification and oxygenation on the frictional resistance characteristics of pipelines. In this paper, the effects of atmospheric pressure, inlet velocity, wet oxygen concentration, pipeline diameter, wall roughness and other factors on the frictional resistance are studied in a straight pipeline transporting heat, moisture and oxygen. The results show that when the pipeline only supplies heat, the frictional resistance per unit pipeline length at an altitude of 5 kilometers is about 62% of that at normal pressure. When the heat, moisture and oxygen are transported together, the increase of the oxygen concentration can increase the frictional resistance per unit pipeline length by about 8.4%, while increasing relative humidity has little effect on the frictional resistance per unit pipeline length, which only reduces 2%. The frictional resistance per unit pipeline length increases with the increase of inlet velocity, and can increase by about 16 times at most. When the wall roughness is small (K=0.03-0.20 mm), the resistance in the hydraulic smooth zone does not change with the increase of roughness. When entering the mixed friction zone (K>0.40 mm), the resistance begins to increase with the increase of roughness, and the maximum increase can be about 45%. Finally, the recommended values of frictional resistance of the heat-moisture-oxygen co-conveying pipeline under different working conditions are given under low-pressure conditions.
Keywords:frictional resistance; low pressure; plateau; heat-moisture-oxygen synergy; pipeline; wall roughness; inlet velocity