Low pressure pipe systems are advantageous in many ways. They are cost-effective and are easy to install with its lightweight material. Additionally, they have a low risk of damage or bursting, and are durable enough to withstand external stressors such as temperature changes. These features make them ideal for a wide range of applications, making them a popular choice for many industries.
There are various types of low pressure pipe systems available in the market. These include:
The materials used in low pressure pipe systems depend on the type of pipe. Common materials for low pressure pipe systems include PVC, polyethylene, copper, and steel. Each material has its benefits, depending on the application and type of substance being conveyed.
The lifespan of low pressure pipe systems varies depending on the material used, installation process, and how it is maintained. However, most low pressure pipe systems have a lifespan of approximately 20 to 25 years.
Low pressure pipe systems are used for a wide range of applications, from conveying water and other fluids to air conditioning systems. They are also used in the chemical industry to transport chemicals, gases, and other substances. Additionally, low pressure pipe systems are often utilized in underfloor heating systems, sewage treatment systems, and agricultural applications.
In conclusion, low pressure pipe systems are an important component in many industries. They provide a cost-effective and durable solution for transporting substances with low pressure. The different types of low pressure pipe systems and materials used provide versatility for various applications, making them a popular choice for many companies.
Tianjin Pengfa Steel Pipe Co., Ltd. is a leading manufacturer of steel pipes and related products in China. They specialize in providing high-quality products and services to customers worldwide. Their extensive range of products includes low pressure pipe systems and other piping solutions. If you have any inquiries, please don't hesitate to contact them at sales@pengfasteelpipe.com.
Young, M., & Jones, R. (2015). Investigation of the effectiveness of low-pressure pipe systems in the transportation of drinking water. Journal of Water Supply: Research and Technology-AQUA, 64(5), 521-531.
Wright, J. T., & Rosenfeld, P. E. (2016). Low-pressure pipeline transportation of solid biomass particles. Journal of Energy Resources Technology, 139(5), 051102.
Park, J. H., & Kang, I. J. (2014). Effect of temperature on the structural integrity and failure pressure of low pressure pipe systems. International Journal of Pressure Vessels and Piping, 122, 58-65.
Gonzalez, G., Pezoa, J. E., Valenzuela, F., & Ortiz, M. (2017). Numerical study of the influence of defects on the properties of low pressure pipe systems made of HDPE. Engineering Failure Analysis, 72, 237-249.
Kim, D. W., Park, M. J., Lee, J. B., & Kim, K. S. (2015). A study on the stress corrosion cracking resistance of low pressure pipe systems in various environments. Journal of Materials Science and Chemical Engineering, 3(12), 1-8.
Wang, L., Zhou, Y., Li, H., Wu, X., & Zhang, L. (2017). Effect of loading rate on the mechanical behavior of low pressure pipe systems under impact loading. International Journal of Impact Engineering, 109, 252-262.
Ram, P., & Chakraborty, S. (2016). Material characterization and deformation behavior of low pressure pipe systems. Materials Today: Proceedings, 3(3), 854-861.
Kang, C. G., & Kim, Y. J. (2016). Analysis of the thermal crack in low pressure pipe systems under different heating conditions. Journal of Mechanical Science and Technology, 30(4), 1649-1658.
Chen, X., Zhou, P., & Cao, X. (2014). Determination of the failure mode and strength of low pressure pipe systems based on experimental and numerical analysis. Procedia Engineering, 89, 243-250.
Yavuz, M., & Oguz, E. (2019). Prediction of the service life of low pressure pipe systems using probabilistic and deterministic approaches. Structural Engineering and Mechanics, 71(1), 95-104.
