Abstract
This paper examines the immature rupture of glass fiber reinforced plastic composite (GFRP) mitered elbow pipes. The GFRP composite mitered elbow pipe’s lifespan was twenty-five years; however, the pipes in question experienced immature failures, resulting in the reduction of their lifetimes to seven, nine, and ten years, respectively. The GFRP cooling water mitered elbow pipe’s service conditions operate at a pressure of up to 7 bar and temperatures between 15–36 °C. The root cause of failure was determined using visual inspection, analytical, microstructural, mechanical characterizations, and chemical analysis. The initial visualization inspection revealed an improper joint between the composite overwrapped and the straight pipe sections. Mechanical properties along the axial, hoop and 45° from the axial direction were obtained. The results from the analytical analysis indicated that the elbow might withstand the operating pressure depending on the quality factor, which was confirmed to be low due to the elbow joint’s improper fabrication process. As evidence of this, the numerical analyses’ results indicated that the safety factor in withstanding the operating pressure of 5 bar is dropped down in the radial region where the thickness is reduced to simulate the failure zone. This study’s findings recommend that thickness of less than 15 mm be reinforced using overwrapped composites. It is recommended for future installations that the fabrication process be appropriately monitored and controlled and avoids using 45°/−45° fiber orientation and multiple layers of chopped strand mat glass fiber.
Highlights
Glass fiber reinforced plastic composite (GFRP) pipeline is a lightweight, corrosionresistant, and cost-competitive alternative for concrete, steel, and other plastic pipes, especially in large-diameter, moderate-pressure applications with good energy absorption and excellent bending behavior [1,2,3]
The results revealed that using the Continuum Damage Mechanics (CDM) method in finite element simulations might lead to an internal pressure estimation error of as low as 7.4%
Three-dimensional finite element stress and fracture analyses of a bonded socket joint reinforced with laminated Fiber-Reinforced Plastic (FRP) composite were conducted to study the influence of the internal pressure conditions on the stresses induced in a composite pipe
Summary
Glass fiber reinforced plastic composite (GFRP) pipeline is a lightweight, corrosionresistant, and cost-competitive alternative for concrete, steel, and other plastic pipes, especially in large-diameter, moderate-pressure applications with good energy absorption and excellent bending behavior [1,2,3]. If the fiber orientation is at ±45◦, the generated strain due to service load is not principally in the axial and hoop direction In this case, a maximum strain failure theory does allow cracks in the matrix before cracks occur in the fiber [13]. A maximum strain failure theory does allow cracks in the matrix before cracks occur in the fiber [13] They used the axial and circumferential properties of the GFRP pipes using a set of tensile and compressive axial and circumferential tests. Three-dimensional finite element stress and fracture analyses of a bonded socket joint reinforced with laminated FRP composite were conducted to study the influence of the internal pressure conditions on the stresses induced in a composite pipe. The aging of a Glass-fiber Reinforced Epoxy (GRE) composite pipe used for seawater transportation was experimentally simulated and studied. It has been observed that the failures in mitered composite elbows have not been covered enough in the literature, and this paper analyses the immature failure in an industrial composite mitered elbow and suggests improvements to the design
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