Gillian Chew

Geothermal Steam Turbine Governor

Geothermal /

Geothermal Steam Turbine Governor Geothermal Power Plants see some of the most harsh and abrasive services found in any industry segment. Regardless of plant design type, toxic chemicals are withdrawn from the earth as part of the process that compromise process equipment rapidly. Hydraulic systems associated with Steam Turbine Controls are highly susceptible to oil breakdown in this environment. REXA’s self-contained, positive pressure, sealed system provides the highest level of system integrity and reliability. REXA’s technology is designed for critical applications such as steam turbine control, offering resolution to 0.05%, high frequency response, and full speed trip capabilities under 500mS.  Literature Download the Steam Turbine Governor Control Application Spotlight! Download

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Wellhead Shut Off & Control

Geothermal /

Wellhead Shut Off and Control Background With the demand for renewable energy continuing to increase, Geothermal power has become a focal point in generation company portfolios. Geothermal energy is extracted without burning any fossil fuels, ensuring a reduction in greenhouse gas emissions. Geo-fields are currently producing about one-sixth of the carbon dioxide of a clean natural gas-fueled plant. Moreover, geothermal energy is always available unlike solar and wind power.  Whether it is a dry steam, flash, or binary cycle plant design, everything begins at the wellhead. Often separated from the plant by significant distances, production wells include emergency shutoff valves (ESV) and flow control valves which play a key role in the process. Therefore, they must function dependably to ensure no interruption of the flow of steam or brine to the plant.  Reliable shutoff and flow control valve operation at production wells can cause a major headache thanks to scaling and potential harsh environmental conditions. As geothermal fluids travel through the earth’s crust towards the wellhead, they absorb many dissolved minerals and gases. Reservoir temperature and saturation levels dictate the amount of scaling at the well caused by these minerals. Consequently, build-up on valve internals begins immediately and can reach catastrophic levels soon after.  Literature Click to download our full Application Spotlight to learn how REXA Actuators provide the best solution for Production Wellhead Shut Off and Control!  Download

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Geothermal Separator Level Control

Geothermal /

Geothermal Separator Level Control Background In areas of the world where steam or two-phase flow are the dominant sources of geothermal energy, it is vital to remove the fluid portion of the mixture from the well. Otherwise, salts and dissolved solids will cause scaling and corrosion of the turbine and related equipment. To combat damage to the turbine, plants install separators –  the most important components at a geothermal plant. Separators ensure only clean, dry steam enters the turbine.  There are two common separator designs – the vertical cyclone and the horizontal separator. Both designs essentially work the same in that a high-velocity two-phase flow enters the separator in a spiral pattern. Next, the centrifugal force moves the fluid to the outer surface, therefore allowing steam to direct toward the outlet tube. The separator fluid then collects in the base of the separator or freestanding tank, with the level controlled by an external control valve. Finally, the salts and solids are discarded and sent to a reinjection well, or vent silencer. Both vertical cyclone and horizontal separator have a 99% or better separation efficiency rate.  Problem Maintaining specific fluid velocities and internal pressure drops are imperative for separators to function as designed. The fluid level has a large impact on separation efficiency and the potential for moisture to carry over into the steam. During production well operation, separator tanks quickly fill with brine and contaminants that must be continuously removed to maintain a proper level. Consequently, this leads to excessive cycling of the separator level control valves –  normally operated by electro-mechanical actuation. Frequent cycling in high ambient temperatures can push these electric actuators to their limit.  Solution So how can REXA solve this problem? Our Electraulic Actuation™ offers a responsive and dependable solution for geothermal separator level control valve applications. We specifically engineer our actuators for critical applications within the harshest environments requiring continuous modulating duty cycle, as well as accurate and repeatable positioning. We specifically engineer our actuators for critical applications within the harshest environments requiring continuous modulating duty cycle, as well as accurate and repeatable positioning.  Literature Read more about our solution in the full Geothermal Separator Level Control Application Spotlight! Download

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Injection Well Control

Geothermal /

Injection Well Control What are Injection Wells? Within the last few decades, injection wells have become a necessity for maximum geothermal power generation and reservoir management. Fluid injection is one of the most important parts of this process, eliminating any environmental impact of surface disposal and providing pressure support to the well. To ensure reservoir replenishment and the highest production well output, injection sites need to meet specific requirements to be selected. These include exploration, testing, conceptual modeling and proper well design.  Why is Accurate Control so Essential? Reliable flow control keeps fluid velocities high enough to prevent the settling of suspended solids. It also allows multiple units to feed a reduced number of injection wells. Controlling fluid flow to an injection well while maintaining system backpressure, however, is a difficult task in itself. Potential major issues, such as gradual plugging of the well or pipeline due to silica scaling, increase injection pressure. Cooling of the fluid at production wells or declining enthalpy happens if there is “short-circuiting” of the injected fluid through a fault or fracture zone during high pressure conditions.  The wrong type of actuation technology could spell disaster for a geothermal plant.  The REXA Solution With more than 20 years of experience in the Geothermal power market, REXA Electraulic™ Actuators ensure efficient injection well control. The self-contained, closed-loop hydraulic circuit provides stiff and stable control independent of load variation. Unscheduled downtime due to overheated actuators tripped offline from high ambient temperatures and scaled-up valves becomes a thing of the past!  Literature Check out our full Application Spotlight to read more about our solution for Injection Well Control!  Download

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FCC Flue Gas Slide Valve

Downstream /

Fluid Catalytic Cracking (FCC) Background on Fluid Catalytic Cracking (FCC) Fluid catalytic cracking (FCC) is an essential process in refineries, used to convert heavy feedstock oil into valuable gasoline, jet fuel, and diesel, amongst other products. During the FCC reaction coke builds up on the catalyst, limiting the catalyst’s ability to carry out the reaction. The spent catalyst transfers over to the regenerator to burn off the residual coke. As the spent catalyst is regenerated, flue gas (combustion gas) is created by burning off residual coke. The flue gas must then pass through a flue gas slide valve which diverts the flue gas to a power recovery train or through a series of separators and electro-static precipitators before it is released into the atmosphere.  Its’ Importance The flue gas slide valve provides accurate pressure control of the regenerator, and in turn, control the differential pressure between the reactor and the regenerator. Tight control is critical in maintaining the FCC pressure balance in the cracking process, allowing smooth flow of the catalyst and feedstock oil between the reactor and the regenerator.  Why REXA? With REXA Electraulic™ Actuation, the end-user gets all the advantages of a hydraulic actuator, such as fast response to signal command and precise modulation of the Flue Gas Slide valve, which are essential for tight control, an efficient process and safe operation.  Literature Download the full FCC Flue Gas Application Spotlight!  Download

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Furnace & Heat Stack Dampers

Downstream /

Furnace and Heater Stack Dampers Background Furnaces help refineries and petrochemical plants break down and convert hydrocarbon fluids into fuels or chemicals such as gasoline, diesel, ethylene and propylene. As furnaces sometimes account for more than 50% of total plant energy consumption, small improvements in efficiency equate to large financial returns. Refineries and petrochemical plants tend to overlook draft control when making process improvements.  Optimizing the draft in a process heater is easy as there are many types of processes and instruments to choose from. The challenge is safely elevating process fluid temperature to a target level while maximizing thermal efficiency, throughput and reducing O2, CO and NOx emissions. Fast-acting, repeatable and accurate damper positioning enables fine-tuning of modern damper control systems.  Problem Despite the high-level automatic control of instruments running complex loops in refineries and petrochemical plants, many dampers are controlled manually via cable and winch. This type of damper arrangement complicates accurate positioning, leading to poor furnace draft control. More importantly, manual operation of dampers creates a potential safety hazard to personnel – especially during emergency situations.  In an inexpensive attempt to automate a damper, a lot of plants select pneumatically-operated drives. Prone to hysteresis, static friction (stiction), overshoot and instability, pneumatic actuators face increased difficulty making small and controlled position changes. This inability to achieve stiff control limits the combustion process efficiency. Solution Upgrading or automating existing dampers with REXA Electraulic™ damper drives provides immediate benefits – enhancing furnace draft control.  Literature Download the full Furnace and Heater Stack Dampers Application Spotlight! Download

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Compressor Anti-Surge

Downstream, Metals Processing /

Compressor Anti-Surge Background Axial and centrifugal compressors are critical pieces of equipment found at the heart of many industrial processes throughout many industries. Implementing the correct high performance compressor control strategy impacts process control and plant profitability. Responsive and stable process control is imperative to improve yield and ensure maximized compressor availability. One of the main applications to ensure maximized availability and throughput is Anti-Surge Control.  What is Compressor Surge? A compressor surge event is a temporary flow reversal through a compressor. This typically causes a rapid downstream decrease in demand, therefore resulting in a rapid increase in compressor discharge pressure. Eliminating these events is essential since they damage the compressor and cause unwanted process downtime at production facilities.  How can the Compressor Anti-Surge Valve help? The Compressor Anti-Surge Valve (ASV) is a critical component in compressor operation, because if optimally controlled, the ASV can eliminate surge through the compressor. Furthermore, this allows for safe operation while enabling the compressor map area to be increased, maximizing compressor efficiency. The ASV requires high-performance capabilities including minimal dead-time, high-frequency response, rapid stroke speed, and minimal overshoot. REXA Actuators can easily exceed the requirements for 500msec full stroke trip, moving the operating point away from the surge line and back into control. Our actuators provide resolution and repeatability to 0.05% and eliminate overshoot, regardless of the step size. Literature Download the full Compressor Anti-Surge Application Spotlight! Download

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Pump Station Pressure Control Systems Explained

Midstream /

Pump Station Pressure Control Pressure control of incoming and discharge flows at the pump stations directly correlates to overall pipeline safety and security. A critical part of the control systems is pressure control in the pipeline. Pressure control serves two essential purposes. The first is to control the discharge pressure of the pump station to achieve the proper flow rate and to attenuate pressure fluctuations in the transmission to downstream pump stations. The pressure control systems, which include valves and actuators, must ensure the pipeline is operating below the system design pressure. The second purpose of the pressure control system is to ensure that the incoming pressure to the pump station is kept above the NPSH (Net Positive Suction Head) required by the pumps in order to prevent cavitation within the pumps and the possibility of damage that could result from the cavitation. Pressure control is interactive from one pump station to another, which means that pressure fluctuations at one station will affect all of the other pump stations along the pipeline. The control system must be able to provide fast response to pressure disturbances during starts, stops, and flow rate changes. It must also provide fast response to set point adjustments at one station in order to achieve the desired flow rate and pressure at another Literature Download the Pump Station Pressure Control Application Spotlight! Download

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Terminal Inlet Pressure Control

Midstream /

Terminal Inlet Pressure Control Background Pressure control is critical when transferring crude oil and petroleum products from the main line to the terminal. Therefore, reducing the variation in delivery pressure will result in uniform flow rates that provide protection from over-pressure conditions in terminal systems. Installing a terminal inlet pressure control valve in the delivery line reduces pressure variation. The inlet pressure control valve is also known as a “holding pressure” or “delivery pressure” control valve. Achieving Poor valve performance could potentially cause unwanted pressure excursions – leading to unscheduled pipeline shutdowns and unit downtime. Problem High pressure differentials are concerning due to the potential cavitation in the flow through the terminal inlet pressure control valve. Cavitation will occur when the flow stream pressure falls below the fluid’s vapor pressure, therefore forming bubbles which will implode once the fluid pressure recovers. These bubble implosions cause severe damage to the valve and, consequently, to the downstream pipeline itself. Solution REXA Electraulic™ Actuators are the solution for fast response to signal command and precise modulation of the terminal inlet pressure control valve. This ensures proper flow control and stable pressure for safe operation. Literature Download the Terminal Inlet Pressure Control Application Spotlight! Download

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Pump Recycle Control

Midstream /

Pump Recycle Control What is Pump Recycle Control? Pump Recycle Control, also known as pump re-circulation flow control, is one of the most common applications found within the Liquid Pipeline industry. Pump Recycle Control keeps pumps operating at a point on their curve. This preventative measure prevents over-pressure of downstream piping and components. The loop directly controls pressure and (by the nature of the system hydraulics) flow rate.  When selecting control valves for this application, it’s important to understand cavitation and consider designs that will limit it. Globe valve designs are generally preferred for pump recycle control due to their higher cavitation coefficient. Response times should be moderately fast.  Explore the significance of Pump Recycle Control, a crucial application in the Liquid Pipeline industry. Learn how it maintains optimal pump operation, prevents over-pressure, and the importance of selecting appropriate control valves to mitigate cavitation effectively. Literature Download to read the full Pump Recycle Control Spotlight! Download

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