Industry News

Self-priming pumps and centrifugal pumps are two common options, but many users still feel confused: what are the specific differences between them? Can they be used interchangeably? Which one is more suitable for low-liquid-level pumping scenarios? As an innovative brand focusing on high-efficiency pumping technology, Teffiko provides reliable selection support for industrial and municipal projects worldwide every year. This article will comprehensively analyze the essential differences between self-priming pumps and centrifugal pumps from the perspectives of working principles, structural differences, applicable working conditions, and practical operation and maintenance pain points, and provide scientific selection suggestions.

In petrochemical, water supply systems, heating, ventilation, and industrial processes, pipeline centrifugal pumps are key equipment ensuring the stable transportation of fluids. However, many on-site engineers often encounter a typical problem: "The pump is obviously running, so why is the water output significantly reduced, or even failing to pump water at all?" This not only affects production efficiency but may also trigger chain failures such as cavitation and motor overload. Combining fluid mechanics analysis by senior researchers and practical experience from frontline operation and maintenance, this article will deeply dissect the five core dimensions leading to the performance degradation of pipeline centrifugal pumps.

In the field of industrial fluid transportation, multistage pipeline centrifugal pumps are widely used due to their advantages such as high head and small floor space. However, in actual operation, many engineers find that the pump performance (flow rate or pressure) fails to meet expectations. At this time, speed testing is often the primary step in troubleshooting. Let's explore the correct methods and common misunderstandings of speed testing for multistage pipeline centrifugal pumps with Teffiko to accurately identify the root cause of performance deviations.

Sludge screw pumps are widely used for their ability to transport high-viscosity media containing solid particles. However, during long-term operation, the equipment is inevitably prone to various faults or performance degradation. If not handled in a timely manner, it will not only affect system efficiency but also cause shutdown losses and even safety accidents. Based on Teffiko's years of R&D and practical experience in chemical screw pumps, this article deeply analyzes the seven most common problems of sludge screw pumps and provides a professional guide from root cause investigation to complete resolution.

In industrial fluid transportation systems, vertical centrifugal pumps are widely used in fields such as building water supply, heating, ventilation and air conditioning (HVAC), chemical processes, and municipal drainage due to their compact structure, convenient installation, and simple maintenance. However, many users encounter a common yet tricky problem during actual operation: the low rotational speed of vertical centrifugal pumps. This not only affects the pump's head and flow rate but also may lead to reduced system efficiency, increased energy consumption, and even equipment failures.

As a professional brand in the fluid transfer industry, Teffiko has always focused on the efficient operation of industrial pumps. In the field of industrial fluid transfer, multistage centrifugal pumps are favored for their ability to provide high head and high efficiency, and their working principle follows the general laws of centrifugal pumps. However, many on-site operators often have questions: Why is it imperative to bleed air before starting a multistage pump? What are the risks of skipping this step? I will deeply analyze this seemingly simple yet crucial operational specification from four dimensions: physical mechanism, equipment structure, operational safety, and actual working conditions.