How to Select an Electric Globe Control Valve - Weldon

Electric globe control valves are vital components in process automation and industrial flow systems. They function as precision flow regulators, using an electric actuator to control the valve's stem position, which in turn adjusts the distance between the disc and the seat. This mechanism enables precise opening and closing of the valve, effectively managing the flow rate, pressure, and direction of fluids or gases through a pipeline.

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Commonly used in chemical processing, water treatment, HVAC systems, and power generation, electric globe control valves offer automated control with reliable shut-off capabilities. While they are well-suited for managing the flow of water, steam, and compressed air, they are not ideal for media with high viscosity, solids, or crystallization tendencies, due to the potential for clogging or obstruction.

Understanding how these electric globe control valves work and selecting the right model for your application is critical for ensuring efficient and long-lasting system performance. This article provides a comprehensive guide to help you choose the ideal electric globe control valve based on operating parameters, materials, actuator features, and application needs.

How Does an Electric Globe Control Valve Work?

An electric globe control valve consists of three key components: the valve body, the internal trim (including the disc and seat), and an electric actuator. The actuator replaces manual handwheels with an electric motor, enabling remote or automatic operation.

Here’s how it works:

When powered, the electric actuator converts electrical energy into mechanical motion.

The actuator drives the valve stem either upward or downward, moving the valve disc away from or toward the seat.

This movement changes the size of the flow passage, thus regulating the flow rate of the medium through the valve.

The extent of the stem travel determines whether the valve is fully open, fully closed, or in a throttled position.

The valve’s position is typically indicated by the height of the stem exposed above the bonnet. This visual cue allows operators to gauge the valve's status during manual inspection, though most modern electric actuators provide digital position feedback for automated systems.

Key Specifications to Consider

Choosing the correct electric globe control valve requires careful consideration of several technical specifications. Matching these parameters with your system requirements ensures optimal performance and minimizes maintenance costs.

1. Valve Size

Select a valve size that matches the nominal diameter of your pipeline. An incorrectly sized valve can lead to flow restrictions, pressure drops, or excessive wear. Valve sizing should consider:

Desired flow rate

System pressure

Piping dimensions

Application-specific requirements (e.g., turndown ratio)

2. Pressure Rating

Each valve is designed to handle specific pressure levels. Make sure the valve’s maximum pressure rating meets or exceeds the highest operating pressure in your system. This includes static and dynamic pressure considerations, especially in fluctuating environments.

3. Temperature Range

Choose a valve that can withstand both the maximum and minimum temperatures expected in your application. Temperature extremes can affect material strength and seal integrity, so proper thermal resistance is essential.

4. Flow Coefficient (Cv)

The flow coefficient (Cv) defines the flow rate of water through a valve at a pressure drop of 1 psi. A higher Cv value indicates a larger flow capacity. Calculate the required Cv using system conditions to ensure adequate throughput with minimal pressure loss.

Material Selection of Electric Globe Control Valve

Material compatibility is fundamental to the valve’s durability and reliability. Corrosion, erosion, or chemical degradation can lead to leaks, failures, or safety risks.

1. Body Materials

The valve body must be made from materials suited to the medium and the process conditions. Common options include:

Stainless Steel: Excellent corrosion resistance; suitable for aggressive media or corrosive environments.

Carbon Steel: Ideal for high-pressure applications involving non-corrosive media; cost-effective and durable.

Brass/Bronze: Good corrosion resistance in potable water and air applications, though not recommended for high-temperature or high-pressure systems.

2. Internal Trim Materials

The disc and seat materials must withstand wear and chemical exposure. Hard-faced alloys or stainless steel are common for high-durability applications. For high-temperature or erosive media, materials like Stellite or Monel may be used.

3. Sealing and Gasket Materials

Seals and gaskets ensure leak-proof operation. Choose sealing materials based on temperature and chemical compatibility. Common options include:

PTFE: Excellent chemical resistance; suitable for a wide temperature range.

EPDM: Ideal for water and steam applications.

Viton: Resistant to aggressive chemicals and high temperatures.

Electric Actuator Specifications

The electric actuator is the control mechanism that automates valve operation. Its performance directly impacts the accuracy and responsiveness of flow control.

1. Torque Requirements

Ensure the actuator provides sufficient torque to operate the valve under all anticipated operating conditions, including:

High differential pressures

Sticky or viscous media

Temperature-induced resistance

Oversized actuators may result in higher costs, while undersized ones risk failure and operational delays.

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2. Control Options

Electric actuators come with different control functionalities:

On/Off Control: Simple open/close functionality. Ideal for isolation or shut-off applications.

Modulating Control: Allows fine adjustment of valve position, providing precise flow control. Often used in process control systems.

Smart Actuators: Feature integrated positioners, diagnostics, and communication interfaces (e.g., Modbus, HART, Profibus) for intelligent process management.

3. Power Supply

Select an actuator with a power supply compatible with your system’s electrical infrastructure. Common supply types include:

AC Power: 220V/380V for industrial applications

DC Power: 24V or 48V for mobile or low-voltage systems

Also, consider the actuator's power consumption and whether it requires fail-safe features such as battery backup or spring-return mechanisms.

Application Considerations of Electric Globe Control Valve

Each industrial application has unique performance requirements. Consider the following before finalizing your valve selection:

1. Flow Medium

Determine the type of fluid or gas the valve will control. This includes:

Chemical composition

Presence of particulates or abrasives

Viscosity and phase (liquid/gas)

Electric globe valves are best suited for clean, non-viscous media. They are not recommended for slurries, sticky fluids, or substances prone to crystallization.

2. Service Conditions

Evaluate the environmental conditions surrounding the valve, such as:

Ambient temperature and humidity

Risk of water or dust ingress (requiring IP-rated enclosures)

Hazardous area classification (may necessitate explosion-proof actuators)

3. Duty Cycle

Determine how often the valve will operate:

Intermittent Duty: Occasional adjustments; lower actuator wear.

Continuous Duty: Frequent throttling; requires robust actuator design and heat dissipation features.

Installation and Maintenance of Electric Globe Control Valve

Proper installation is crucial for maximizing the valve’s service life and ensuring safety. Consider these best practices:

Mount the actuator in a position that avoids direct exposure to heat, moisture, or corrosive fumes.

Ensure the valve is installed in the correct flow direction, typically marked by an arrow on the body.

Use appropriate flanges and fasteners to match pressure and temperature specifications.

Conduct pre-installation flushing of the pipeline to remove debris that may damage the valve seat.

After installation, verify valve operation and actuator responsiveness through manual testing or system commissioning procedures.

Routine maintenance includes inspection of seals, stem lubrication, actuator calibration, and checking electrical connections.

Selecting the right electric globe control valve is a critical decision in ensuring reliable, efficient, and safe process control. By evaluating parameters such as valve size, pressure and temperature ratings, material compatibility, actuator specifications, and the specific demands of your application, you can ensure long-term performance and operational efficiency.

Electric globe valves offer excellent throttling capabilities and automation potential, making them ideal for modern industrial systems. Whether you’re working in chemical processing, HVAC, water treatment, or energy production, understanding these selection criteria will help you achieve optimal control outcomes with minimal downtime or maintenance.

As automation becomes increasingly integral to fluid control systems, investing in the right electric globe control valve ensures your operations remain precise, responsive, and resilient in the face of evolving demands.

Control valves play an important role in various process industries. They are designed to control the flow of fluids in a system. They are designed to start and stop as well as throttle the fluid flow to ensure efficient process operation. Owing to their increasing use in process industries, today, it is easy to find these valves in different specifications. This large selection may be confusing to users who are purchasing it for the first time. There are several factors to be considered when making a selection. This post aims to ease the control valve selection by providing a few easy-to-follow tips.

What Are the Different Types of Control Valves?

Control valves are differentiated based on their designs and other characteristics. The following are a few important types of control valves in use today:

• Linear globe valves: These valves are made of cylindrical or disk plug element, and have a spherical body and a stationary ring seat. Linear globe valves allow easy access to internal elements, and they are used to regulate the flow of a variety of fluids.
• Linear angle valves: The control valves are designed for severe applications, which may have large noise, flashing, and flow rates.
• Rotary valves: In this type of valve, the liquid flow is regulated through the rotation of passages present in a transverse plug. These valves are ideal for applications, where fluids being transferred may contain solids. In many applications, rotary valves serve as a replacement for globe and angle valves. These valves are designed for severe applications, and they are suited for applications where cleanliness is not mandatory. 
• Linear three-way control valves: These control valves feature two outlets and one inlet or vice-versa. Linear three-way control valves are used for applications, where liquids may be involved. They enable easy mixing of liquids from two different pipes into a single pipe. These valves can be found in water chillers, fan coils, air handling units, and so on.

5 Factors to Consider When Selecting Control Valve for Your Process

The purpose of this section is to provide you points that will ease the control valve selection process for your next project.

• Fluid to be Transferred: What type of fluid will be transferred at your processing plant? The control valves are designed for controlling the flow of media such as natural gas, compressed air, steam, liquefied petroleum, gasoline, hydraulic fluid, slurry, and water. So, it needs to be ensured that the valve works perfectly for all these fluids.
• Material Grades: As said earlier, today, it is easy to find the industrial valves in various stainless steel material grades such as ASTM, ASTM A217 grade, A216 grade WCC, ASTM A351 CF8M, and so on.
• Flow Control Characteristics: Address the maximum and minimum or acceptable temperature range of the fluid to be transferred. Also, address the minimum and maximum inlet and outlet pressures that a valve is expected to handle. This will help you understand the flow control characteristics of the valve. Ensure that the valve chosen offers consistent control across various temperatures. Also, they meet equal or linear percentage or several other characteristics. Understand that these flow characteristics will vary across different processes, and the valve must be able to assure stability across all conditions.
• Compatibility with Remote Systems: Owing to the criticality of the process environment, many processes require remote control and monitoring. It is important to ensure that the valve chosen complies with the remote process management systems.
• Rugged Construction: Most industrial processes are conducted in ambient, harsh environments; so, if the chosen valve is unable to meet these diverse requirements, then it may fail to serve the purpose. You need to check if the valve can withstand the extremes and minimums as well as upset conditions, and can operate virtually.

In addition to the above-discussed tips, you can discuss your requirements with the manufacturer. Whenever you are considering these valves for your project, ensure that they are sourced from a reliable supplier like The Transmitter Shop. The company provides a new surplus, reconditioned, and factory new control valves.

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