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Why Metering Pump Inaccuracy Often Isn’t a Pump Problem

 Why Metering Pump Inaccuracy Often Isn’t a Pump Problem Metering pumps are critical for delivering precise doses of chemicals, additives, or treatments in water treatment, chemical processing, pharmaceuticals, and many industrial systems. When a metering pump starts delivering off-target volumes, the instinctive response is often: “The pump must be bad.” But in most real-world cases, the cause is not the pump itself — it’s the system conditions surrounding the pump. Let’s break down the real reasons behind metering pump inaccuracies and how to diagnose them effectively. Product overview and specifications: 🔗 https://www.scpv.cn/jiliangbeng/ 1. Suction Issues: Air Entrainment and Leakage One of the most common causes of metering inaccuracies is air entering the suction side. Even tiny leaks at: Tube fittings Suction line connections Foot valves Pump inlet gaskets can allow air bubbles to enter the pump chamber. Since air is compressible, it drastically changes the actual delivered...
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Magnetic Pump Overheating: Three Real Engineering Cases and What They Reveal

 Magnetic Pump Overheating: Three Real Engineering Cases and What They Reveal Magnetic drive pumps are widely used in chemical processing, pharmaceuticals, new energy, and environmental systems due to their leak-free design and high safety level. However, one issue occasionally reported by plant engineers is: Unexpected temperature rise during operation. In most situations, the root cause is not material failure or manufacturing defects — it is system condition mismatch. Below are three real engineering scenarios that explain the most common causes of magnetic pump overheating: Insufficient internal circulation Improper back pressure Gas locking (air/vapor entrainment) For product reference and structural overview, see: 👉 https://www.scpv.cn/cilibeng/ Case 1: Blocked Suction Filter → Insufficient Internal Cooling Background A chemical plant was transferring an organic solvent using a magnetic drive centrifugal pump. After several months of stable operation, the pump casing tempera...
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Why Diaphragm Pumps Can Self-Prime and Withstand Dry Running Explained Clearly for Engineers and Technical Readers

 Why Diaphragm Pumps Can Self-Prime and Withstand Dry Running Explained Clearly for Engineers and Technical Readers Diaphragm pumps are widely used in chemical, wastewater, food, and industrial processing systems — often praised for two remarkable characteristics: ✔ Ability to self-prime ✔ Resistance to dry running damage Many users know these as facts, but few understand why they happen from a mechanical and fluid perspective. In this article, we break down the real reasons behind these capabilities. For deeper technical reference, see: 🔗 https://www.scpv.cn/news/690.html 1. Self-Priming: The Core Reason Is Volume Change Unlike centrifugal pumps that rely on fluid dynamics and rotational inertia, diaphragm pumps operate on the positive displacement principle. Here’s how it works: An elastic diaphragm moves backward → Pump chamber volume increases → Pressure drops inside the chamber → Liquid is drawn in through the inlet check valve The diaphragm moves forward → Chamber volume dec...
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Key Parameters Often Overlooked When Selecting a Screw Pump: Viscosity, Temperature, Differential Pressure & Shear Sensitivity

 Key Parameters Often Overlooked When Selecting a Screw Pump: Viscosity, Temperature, Differential Pressure & Shear Sensitivity Screw pumps are widely regarded as reliable, low-pulsation positive displacement pumps, making them a go-to choice for viscous fluids and demanding industrial services. However, many premature failures or performance problems occur not because of the pump itself, but because four critical selection parameters are overlooked during the design phase: 👉 viscosity, temperature, differential pressure, and allowable shear limits. For more technical insights and real-world considerations, see: 🔗 https://www.scpv.cn/news/387.html 1. Viscosity: Not Just a Number on Paper Viscosity is often treated as a secondary concern, yet it is one of the most important factors influencing screw pump performance. A fluid’s viscosity directly affects: Actual flow rate (high viscosity reduces effective pumping volume) Required torque (higher viscosity demands higher torque f...
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What to Do When a Magnetic Pump Fails: Common Fault Causes and Step-by-Step Repair Guide

 What to Do When a Magnetic Pump Fails: Common Fault Causes and Step-by-Step Repair Guide Magnetic pumps are widely used in chemical processing, wastewater treatment, plating, pharmaceuticals, and other industries because of their leak-free design and high safety performance. However, a failed magnetic pump can disrupt production and lead to costly downtime if handled improperly. To help you troubleshoot and repair effectively, this article analyzes the common causes of magnetic pump failure and the recommended repair steps. For reference and case examples, see: 👉 https://www.scpv.cn/news/877.html 1. Understand What “Magnetic Pump Failure” Really Means A magnetic pump doesn’t have a traditional mechanical seal — but it still has critical components that can fail, including: Isolation sleeve Magnetic couplers Sliding bearings Impeller and rotor assembly Failure may present as performance degradation rather than complete breakdown. Early signs often include: ✔ Reduced flow rate ✔ Ab...
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What Happens When a CDLF Multistage Pump Operates Away from Its Design Point?

 What Happens When a CDLF Multistage Pump Operates Away from Its Design Point? CDLF vertical multistage pumps are widely used in water supply systems, boiler feed applications, industrial circulation, and pressure boosting. They are known for high head, compact structure, and stable performance. However, in real-world operation, many pumps do not run at their original design point for long periods of time. At first, everything seems normal. But long-term operation away from the design condition can gradually affect efficiency, stability, and service life. For technical specifications and models, visit: 👉 https://www.scpv.cn/pumps/CDL.html 1. What Does “Operating Away from Design Point” Mean? Every multistage pump has a Best Efficiency Point (BEP) defined by: Rated flow Rated head Optimal hydraulic balance When the actual operating flow is consistently lower or higher than this range, the pump is considered to be running off-design. This does not immediately cause failure — but it ...
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How Gear Oil Pumps Achieve Stable Delivery: Explained Through Meshing Volume Changes

 How Gear Oil Pumps Achieve Stable Delivery: Explained Through Meshing Volume Changes In industrial lubrication, hydraulic systems, and fluid circulation applications, gear oil pumps are widely chosen for their reliable delivery and long-term stability. But have you ever wondered what makes them so consistently effective? The key lies in something fundamental to their design: 👉 the predictable change of meshing volume between the gears. To explore available gear oil pump models and specifications, visit: https://www.scpv.cn/pumps/KCB.html 1. Gear Pumps Deliver Fluid Based on Meshing Volume Unlike centrifugal pumps that rely on kinetic energy to move fluid, a gear oil pump works on a positive displacement principle. Pressurized flow is generated by the repetitive change in internal volume as two gears rotate and mesh. Here’s how it works in each revolution: Suction: As the teeth of the driving and driven gears separate, the space between them expands, creating a low-pressure area t...
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