FluidTech News

 How Do Internal Forces Change in a Diaphragm Pump Under High Back Pressure? Diaphragm pumps are widely used in chemical dosing, fluid transfer, and high-precision metering applications due to their leak-free structure and strong adaptability to corrosive media. However, in real-world operation, a common situation is often overlooked: 👉 The pump operates under high back pressure conditions Many users focus only on whether the pump can “handle the pressure,” but ignore a deeper issue: 👉 The internal force distribution has already changed What Is High Back Pressure Operation? High back pressure occurs when: Discharge resistance increases Downstream system pressure rises Valves are partially closed or pipelines become restrictive 👉 As a result: The pump must overcome higher opposing pressure to discharge fluid How Internal Forces Change Inside the Pump 1. Increased Stress on the Diaphragm The diaphragm is the core component, responsible for: Creating suction (negative pressure) Gen...

 What Causes Abnormal Temperature Rise in Magnetic Drive Pumps? Internal Mechanism Analysis Magnetic drive pumps are widely used in chemical, pharmaceutical, and environmental industries due to their sealless design, making them ideal for handling hazardous, flammable, or corrosive fluids. However, during operation, a common issue is observed: 👉 The pump operates normally, but temperature rises abnormally In most cases, this is not caused by a single factor, but by multiple internal mechanisms acting together. Why Magnetic Drive Pumps Are Prone to Heat Accumulation Unlike conventional pumps, magnetic drive pumps feature: Magnetic coupling (no mechanical seal) Fully enclosed containment shell 👉 This leads to: Limited heat dissipation Heat accumulation inside the pump Once heat is generated, it becomes difficult to release. Key Internal Mechanisms Behind Temperature Rise 1. Eddy Current Loss (Primary Heat Source) During operation: The outer magnet creates a rotating magnetic field ...

 How Is Interstage Pressure Distribution Formed in CDLF Vertical Stainless Steel Multistage Pumps? In applications such as high-rise water supply, industrial boosting, and water treatment systems, CDLF vertical stainless steel multistage pumps are widely used due to their compact structure, high efficiency, and strong head capacity. However, in real-world operation, many users focus only on the total head, while overlooking a more fundamental question: 👉 How is the interstage pressure distribution actually formed? Understanding this process is key to mastering the working principle of multistage pumps. Structural Basis: Why Pressure Is Built Stage by Stage CDLF pumps are vertical multistage centrifugal pumps, characterized by: Multiple impellers arranged in series Guide vanes (diffusers) between stages Fluid gaining energy progressively 👉 This means: Pressure is not generated at once, but built up progressively across multiple stages Step-by-Step Formation of Interstage Pressure ...

 How Clearance Changes Affect Rotary Lobe Pump Performance in High-Viscosity Fluids In industries such as food processing, chemicals, and pharmaceuticals, rotary lobe pumps are widely used for handling high-viscosity fluids due to their low shear and stable flow characteristics. However, during long-term operation, many users encounter a common issue: 👉 The pump keeps running, but flow rate decreases and pressure becomes unstable. In most cases, the root cause is not insufficient power, but rather: 👉 Changes in internal clearances Why Is Clearance So Critical in Rotary Lobe Pumps? Rotary lobe pumps are positive displacement pumps. Their performance depends heavily on controlled internal clearances, including: Lobe-to-lobe clearance Lobe-to-casing clearance Lobe-to-end cover clearance 👉 These clearances must strike a balance: Large enough to avoid contact Small enough to minimize internal leakage How High-Viscosity Fluids Influence Clearance Compared with low-viscosity fluids, hi...

 How Does Volumetric Efficiency Decline in Progressive Cavity Pumps? A Step-by-Step Analysis In industrial fluid handling systems, progressive cavity pump (also known as screw pumps) are widely used for transferring viscous, abrasive, and sensitive fluids due to their stable flow and high adaptability. However, during long-term operation, many users notice a common issue: 👉 The pump runs normally, but the flow rate gradually decreases. This is not a sudden failure — it is typically the result of a gradual decline in volumetric efficiency. What Is Volumetric Efficiency? Volumetric efficiency refers to: 👉 Actual flow rate ÷ Theoretical flow rate When internal leakage or slippage increases, the pump delivers less fluid than expected, leading to efficiency loss. The Step-by-Step Formation of Efficiency Decline Understanding how this decline develops is key to preventing costly failures. 1. Initial Stage: Micro Wear Begins At the early stage of operation: Slight wear occurs between ro...

 Abnormal Temperature Rise in Magnetic Pumps: Internal Mechanisms You Should Understand In practical applications, magnetic drive pumps sometimes show a common issue: they continue running normally, but the temperature keeps rising, and in severe cases, may even lead to shutdown. Many users initially attribute this to ambient conditions or insufficient cooling. However, real-world experience shows that: 👉 Abnormal temperature rise in magnetic pumps is often caused by internal mechanisms rather than external factors. Why Are Magnetic Pumps Prone to Heat Accumulation? Magnetic pumps use a magnetic coupling design: No mechanical seal Torque transmitted via inner and outer magnetic rotors A containment shell isolates the fluid from the motor This design ensures leak-free operation, but it also means: 👉 Heat generated inside the pump is harder to dissipate Key Internal Mechanisms Behind Temperature Rise 1. Eddy Current Losses During operation: The outer magnetic rotor rotates at high ...