When hydraulic systems start underperforming, it can be frustrating and time-consuming. What's the problem? Where do you even begin? The usual culprit is hydraulic varnish buildup. This sticky substance seriously reduces your equipment's efficiency and lifespan. Let's explore some effective strategies for mitigating varnish in hydraulic systems.
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The Problem with Varnish in Hydraulic Oil | Deep Dive into Varnish Formation | Strategies to Reduce Varnish Formation | Testing & Analysis | Powerful Varnish Mitigation Systems | Frequently Asked Question
Key Takeaways✔️ Hydraulic varnish buildup can disrupt lubrication, increase operating temperatures, and cause seal damage and leaks in hydraulic systems. ✔️ To reduce varnish formation, offline filtration, dewatering, and degassing should be used. Electrostatic discharge should also be prevented. Oil temperature should be monitored, and hydraulic systems should be periodically chemically cleaned and flushed. ✔️ Advanced technologies, such as resin-based filtration, cooling, and standalone varnish mitigation units, ensure effective varnish control and enhance system performance and longevity. |
Varnish is a sticky, dark residue that forms in hydraulic systems, much like a dark stain applied to wood. Composed of organic and polar compounds, varnish particles are less than one micron in size and are soluble in oil. These deposits typically form on cold metallic surfaces, leading to various operational issues. The main issue is that varnish disrupts the lubricating properties of hydraulic oil and hinders its flow, causing valves to stick and pumps to wear out faster. This buildup also increases operating temperatures, leading to potential seal damage and leaks.
Several things lead to varnish buildup including:
Extreme Heat Oxidation: High operating temperatures accelerate oxidation, leading to varnish precursors.
Electrostatic Discharge (ESD): Sparking within lubrication systems can damage filter elements and system components. Learn more in our blog post, Electrostatic Discharge (ESD) in Hydraulic Systems.
Cavitation and Micro-dieseling: These phenomena cause localized high temperatures and pressures, promoting varnish formation.
Elevated Turbine Bearing Temperature: Higher bearing temperatures increase the likelihood of varnish deposits.
Changes in Base Oils: Transitioning from group one to group two and three oils has increased varnish problems due to differing bonding sites for varnish precursors.
Varnish can have severe consequences on hydraulic systems, including elevated friction and temperature, which may lead to potential bearing wear and damage. Also, varnish buildup can damage sensor and filter elements, diminishing overall system performance. Additionally, varnish buildup reduces heat transfer efficiency, resulting in higher operational temperatures and accelerated oil degradation. That's why addressing varnish formation is critical to maintaining the efficiency and longevity of hydraulic systems.
Understanding the formation of varnish is key to preventing and mitigating its effects.
Varnish forms through several mechanisms, including extreme heat oxidation, electrostatic discharge, cavitation, and micro-dieseling. Each process introduces varnish precursors into the hydraulic oil, which is then deposited on metallic surfaces. Learn more in our blog post, 6 Types of Hydraulic Fluid Contamination You Need to Know.
Varnish buildup can significantly reduce the efficiency and reliability of hydraulic systems. It increases friction, causes bearing wear, and reduces heat transfer effectiveness, leading to higher operational temperatures and accelerated oil degradation.
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Effective varnish mitigation involves a combination of techniques. Let's review:
Using offline filtration systems can help remove varnish precursors before they form deposits. These systems operate independently of the main hydraulic circuit, ensuring continuous filtration.
Removing water and gasses from hydraulic oil can prevent the conditions that lead to varnish formation. Dewatering units and vacuum degassers are effective tools for this purpose.
Implementing measures to prevent ESD, such as using conductive materials and grounding, can reduce the risk of varnish formation due to sparking.
Maintaining optimal oil temperatures is crucial for minimizing oxidation and varnish formation. Cooling systems can help achieve this.
Periodic chemical cleaning and flushing of hydraulic systems can remove existing varnish deposits and prevent further accumulation.
📝 Several tests can detect varnish presence and concentration in hydraulic oil:
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Several advanced technologies and equipment are available for varnish mitigation. Review below or learn more in our blog post, Three HYDAC Solutions for Hydraulic Varnish Removal.
These systems use specialized resin materials to capture varnish precursors, effectively preventing their formation.
Combining cooling systems with fine filtration units enhances varnish mitigation by removing precursors and maintaining optimal oil temperatures.
Standalone units are specifically designed to address varnish issues, employing a combination of filtration, dewatering, and cooling techniques.
Hydraulic varnish is a significant challenge for system operators, industrial maintenance specialists, and fluid chemists. You can maintain peak system performance and longevity by understanding its causes, impacts, and mitigation strategies. Learn more in our on-demand webinar, Varnish Mitigation 101, or reach out for expert support in hydraulic varnish mitigation.
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