Skip to main content

DRY GAS SEALS: How to Implement Proactive Monitoring

BY MICHAEL FORSTHOFFER.

In the last 10+ years there has been a significant increase in the technology and instrumentation used on dry gas seal systems to monitor the condition of the seals. Most notable has been the call to monitor secondary seal condition – there have been significant failures of the secondary seal without any issue with the primary seal. The majority of these failures have been due to oil migration across the separation seals. As the oil is not drained out, it accumulates around the secondary seal, fills the grooves, and causes the secondary seal faces to contact.

There are various approaches to monitoring secondary seal condition. Probably the most beneficial is utilizing a back pressure control valve in the primary vent (Figure).

Figure: Using a back pressure control valve in the primary vent as part of the monitoring of secondary seal condition in a dry gas seal.

This sets the primary vent at a pressure below the primary seal gas supply pressure, but high enough for the user to be able to set a low-pressure alarm and trip (if required), indicating the secondary seal has failed.

This pressure should probably be set somewhere between 15-25 psig, as this will provide a good dierential pressure across the secondary seal and improve its lifespan by slightly increasing the gap between the faces (less wear).

By using a positioner (wireless positioners are available) on the back pressure control valve, a user will be able to be proactive in determining if the secondary or primary seal is going to fail. For example, if the valve is normally set at 60% open and it starts to open more, this could indicate excessive primary seal leakage (assuming if intermediate nitrogen is being supplied, the flow has not increased). Likewise, if the back pressure control valve begins to close more, this could indicate excessive secondary seal leakage.

By trending the position of this valve, one can predict at what point the valve will no longer be able to control the pressure. If the valve position stays relatively steady throughout a run on a compressor, it is not recommended to change the dry gas seals. However, if it has changed by more than 20% over a run time, it would be recommended to do so.

Labels

Labels:

Comments

Post a Comment

Popular posts from this blog

Why Pump Shafts Often Break at the Keyway Area

By NTS Pump shaft failure can lead to significant downtime and repair costs in industrial plants. One of the most common locations for pump shaft failure is at the keyway area. In this article, we will explore the reasons why pump shafts often break at the keyway and what can be done to prevent such failures. The keyway is a high-stress point (weakest point)  on the shaft, where a key is inserted to transmit torque between the shaft and the pump impeller or coupling. During operation, the keyway experiences cyclic loading that creates a bending moment in the shaft, which is concentrated in the keyway area. Over time, this cyclic loading can cause fatigue failure in the shaft material, leading to a fracture at the keyway. In addition to cyclic loading, other factors can contribute to shaft failure at the keyway. Improper keyway design or installation can lead to stress concentrations or inadequate clearance between the key and keyway . Misalignment or overloading can also cause ex...
Post a Comment
[Read more...]

John Crane's Type 28 Dry Gas Seals: How Does It Work?

How Does It Work? Highest Pressure Non-Contacting, Dry-Running Gas Seal Type 28 compressor dry-running gas seals have been the industry standard since the early 1980s for gas-handling turbomachinery. Supported by John Crane's patented design features, these seals are non-contacting in operation. During dynamic operation, the mating ring/seat and primary ring/face maintain a sealing gap of approximately 0.0002 in./5 microns, thereby eliminating wear. These seals eliminate seal oil contamination and reduce maintenance costs and downtime. John Crane's highly engineered Type 28 series gas seals incorporate patented spiral-groove technology, which provides the most efficient method for lifting and maintaining separation of seal faces during dynamic operation. Grooves on one side of the seal face direct gas inward toward a non-grooved portion of the face. The gas flowing across the face generates a pressure that maintains a minute gap between the faces, optimizing flui...
Post a Comment
[Read more...]

FACTORS IMPACTING COMPRESSOR SURGE

BY AMIN ALMASI. Surge can be a major challenge for turbo compressors. Operation in the surge area will result in instability, exposing the machine to destructive stresses and forces, high vibration, and even serious damage. Surge during shutdown (trip) has been reported for many turbo-compressors. This is particularly possible if the machine operates at high head and low flow, immediately before the trip, when the operating point can move toward the surge line and even pass it during coast-down (when the turbo-compressor reduces flowrate). When a turbo-compressor experiences a serious alarm, an emergency shutdown is usually initiated. But an immediate shutdown could result in a surge. In this case, the surge happens shortly after the shutdown (trip) and at a high energy level. This could be a surge at a high head (operating point could pass the surge line at high head). In many cases, there are advantages to not removing the driving power from the turbocompressor (tripping) immediately...
Post a Comment
[Read more...]