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Quarter Turn Actuators
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8102899
semi-rotary drive DFPD-1200-RP-90-RS60-F14-R3-C Size of actuator: 1200, Flange hole pattern: F14, Swivel angle: 90 deg, End-position adjustment range at 0°: -5 - 5 deg, End-position adjustment range at 90°: -5 - 5 deg
Festo
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8102849
semi-rotary drive DFPD-240-RP-90-RS45-F10-R3-C-VDE2 Size of actuator: 240, Flange hole pattern: F10, Swivel angle: 90 deg, End-position adjustment range at 0°: -5 - 5 deg, End-position adjustment range at 90°: -5 - 5 deg
Festo
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8102856
semi-rotary drive DFPD-N-300-RP-90-RS60-F10-R3-C Size of actuator: 300, Flange hole pattern: F10, Swivel angle: 90 deg, End-position adjustment range at 0°: -5 - 5 deg, End-position adjustment range at 90°: -5 - 5 deg
Festo
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549684
semi-rotary drive DAPS-0720-090-RS4-F14 Single-acting, air connection as per VDI/VDE 3845, Namur valves can be directly flange-mounted Size of actuator: 0720, Flange hole pattern: F14, Swivel angle: 90 deg, End-position adjustment range at 0°: -1 - 9 deg,
Festo
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533420
semi-rotary drive DAPS-0106-090-R-F0507 Double-acting, air connection as per VDI/VDE 3845, Namur valves can be directly flange-mounted Size of actuator: 0106, Flange hole pattern: (* F05, * F07), Swivel angle: 90 deg, End-position adjustment range at 0°:
Festo
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549675
semi-rotary drive DAPS-0360-090-RS3-F1012 Single-acting, air connection as per VDI/VDE 3845, Namur valves can be directly flange-mounted Size of actuator: 0360, Flange hole pattern: (* F10, * F12), Swivel angle: 90 deg, End-position adjustment range at 0°
Festo
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533424
semi-rotary drive DAPS-0480-090-R-F1012 Double-acting, air connection as per VDI/VDE 3845, Namur valves can be directly flange-mounted Size of actuator: 0480, Flange hole pattern: (* F10, * F12), Swivel angle: 90 deg, End-position adjustment range at 0°:
Festo
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533481
semi-rotary drive DAPS-0015-090-RS2-F04 Single-acting, air connection as per VDI/VDE 3845, Namur valves can be directly flange-mounted Size of actuator: 0015, Flange hole pattern: F04, Swivel angle: 90 deg, End-position adjustment range at 0°: -1 - 9 deg,
Festo
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549696
semi-rotary drive DAPS-2880-090-RS4-F16 single-acting, Namur valves not suited for direct flange-mounting. Size of actuator: 2880, Flange hole pattern: F16, Swivel angle: 90 deg, End-position adjustment range at 0°: -5 - 5 deg, End-position adjustment ran
Festo
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549681
semi-rotary drive DAPS-0720-090-RS1-F14 Single-acting, air connection as per VDI/VDE 3845, Namur valves can be directly flange-mounted Size of actuator: 0720, Flange hole pattern: F14, Swivel angle: 90 deg, End-position adjustment range at 0°: -1 - 9 deg,
Festo
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533436
semi-rotary drive DAPS-0053-090-RS2-F0507 Single-acting, air connection as per VDI/VDE 3845, Namur valves can be directly flange-mounted Size of actuator: 0053, Flange hole pattern: (* F05, * F07), Swivel angle: 90 deg, End-position adjustment range at 0°
Festo
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561696
semi-rotary drive DAPS-4000-090-RS4-F25 single-acting, Namur valves not suited for direct flange-mounting. Size of actuator: 4000, Flange hole pattern: F25, Swivel angle: 90 deg, End-position adjustment range at 0°: -5 - 5 deg, End-position adjustment ran
Festo
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553188
semi-rotary drive DAPS-2880-090-R-F16-T6 double-acting, air connection to VDI/VDE 3845 Namur valves, direct flange mounting, version with handwheel, low temperature version. Size of actuator: 2880, Flange hole pattern: F16, Swivel angle: 90 deg, End-posit
Festo
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552869
semi-rotary drive DAPS-0015-090-R-F03-CR double-acting, air connection to VDI/VDE 3845 Namur valves, direct flange mounting, stainless steel version. Size of actuator: 0015, Flange hole pattern: F03, Swivel angle: 90 deg, Shaft connection depth: 10,1 mm,
Festo
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552885
semi-rotary drive DAPS-0060-090-RS3-F0507-CR single-acting, air connection to VDI/VDE 3845 Namur valves, direct flange mounting, stainless steel version. Size of actuator: 0060, Flange hole pattern: (* F05, * F07), Swivel angle: 90 deg, Shaft connection d
Festo
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533478
semi-rotary drive DAPS-0960-090-R-F14 Double-acting, air connection as per VDI/VDE 3845, Namur valves can be directly flange-mounted Size of actuator: 0960, Flange hole pattern: F14, Swivel angle: 90 deg, End-position adjustment range at 0°: -1 - 9 deg, S
Festo
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533495
semi-rotary drive DAPS-0960-090-RS4-F1216 Single-acting, air connection as per VDI/VDE 3845, Namur valves can be directly flange-mounted Size of actuator: 0960, Flange hole pattern: (* F12, * F16), Swivel angle: 90 deg, End-position adjustment range at 0°
Festo
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533443
semi-rotary drive DAPS-0120-090-RS1-F0710 Single-acting, air connection as per VDI/VDE 3845, Namur valves can be directly flange-mounted Size of actuator: 0120, Flange hole pattern: (* F07, * F10), Swivel angle: 90 deg, End-position adjustment range at 0°
Festo
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533425
semi-rotary drive DAPS-0960-090-R-F1012 Double-acting, air connection as per VDI/VDE 3845, Namur valves can be directly flange-mounted Size of actuator: 0960, Flange hole pattern: (* F10, * F12), Swivel angle: 90 deg, End-position adjustment range at 0°:
Festo
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533458
semi-rotary drive DAPS-0480-090-RS4-F1012 Single-acting, air connection as per VDI/VDE 3845, Namur valves can be directly flange-mounted Size of actuator: 0480, Flange hole pattern: (* F10, * F12), Swivel angle: 90 deg, End-position adjustment range at 0°
Festo
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Quarter Turn Actuators
General Guide & Overview
These actuators are the driving force behind quarter turn valve actuators, which are used to control the flow of various fluids in industrial processes. Quarter turn actuators specifically work by rotating the valve stem a quarter of a full rotation, opening or closing the valve.
Understanding the terminology associated with quarter turn actuators is essential. Terms such as quarter-turn, position, CW (clockwise) rotation, CCW (counterclockwise) rotation, stroke, cycle, and safety factor will be discussed in detail to ensure a full understanding of their functionalities and implications.
When it comes to selecting the right quarter turn actuator, we will specifically focus on Bettis actuators. Sizing Bettis actuators involves obtaining the maximum torque requirement and identifying the type of actuator required. We will guide you through the specific sizing information for Bettis rack and pinion, double-acting actuators, and spring-return actuators.
Types of Electric Actuators for Valves
Electric actuators are essential devices that utilize power to drive valves, enabling automated and remote control over valve operations. These actuators come in various types based on their modes of operation, including manual, pneumatic, hydraulic, and electric.
This section delves into the working principle, components, and types of electric actuators specifically used for valves. It explores the process of converting electrical energy into mechanical energy through an electric motor and the subsequent transmission of rotational motion to the valve stem via gears. Limit switches are incorporated to precisely control the valve's position.
Within the realm of electric actuators, three prominent types deserve attention: multi-turn electric actuators, linear output electric actuators, and 1/4 turn electric actuators. Each type presents distinct advantages and is uniquely suitable for various valve applications.
Selection and Application of Electric Actuators
In order to ensure the smooth operation and optimal performance of valves, it is crucial to select the appropriate electric actuators that suit the specific valve applications. The selection process involves considering various factors to ensure a perfect match between the electric actuator and the valve's working conditions.
One of the key considerations is the required output torque or displacement thrust. The electric actuator must be capable of generating sufficient power to operate the valve effectively. Additionally, factors such as the type of actuator (control or on/off type), the frequency of valve use, and the power requirements must also be taken into account during the selection process.
It is equally important to choose a reliable brand for electric actuators to ensure their durability and longevity. Reliability is crucial in industrial processes as it minimizes downtime and maintenance costs. By selecting high-quality electric actuators, users can enhance the safety and environmental protection measures within their operations.
The role of electric actuators goes beyond mere valve control. They play a significant role in optimizing the efficiency of power plants and other automated systems. The correct selection of electric actuators ensures the reliability, safety, and efficiency of these systems, leading to improved overall performance and reduced downtime.
The selection process involves considering factors such as the required output torque, valve use frequency, and power requirements. It is crucial to match the right actuator to the valve's working conditions to ensure optimal performance and efficiency.
With the different types of electric actuators available, including multi-turn electric actuators, linear output electric actuators, and 1/4 turn electric actuators, users have options that suit a wide range of valve applications. By selecting the appropriate actuator type, users can achieve reliable and precise control of valve operations.
Whether utilized in industrial processes or power plants, quarter turn actuators play a critical role in ensuring the smooth and efficient operation of valves. The proper selection and application of these actuators contribute to enhancing safety, improving environmental protection, and maximizing productivity in various automated systems.
FAQ
What are quarter turn actuators?
Quarter turn actuators are devices used to control the opening and closing of valves with a quarter turn of 90 degrees. They provide automated or remote operation, allowing for efficient control of fluid flow in various applications.
What are the advantages of using quarter turn actuators?
The advantages of using quarter turn actuators include quick and precise operation, compact design, high torque output, and compatibility with a wide range of valve types. They also offer improved efficiency, reduced manual labor, and enhanced safety in valve automation.
How do electric actuators work for valves?
Electric actuators for valves work by converting electrical energy into mechanical energy to drive the valve's operation. They use an electric motor to generate rotational motion, which is then transmitted to the valve stem through gears. Limit switches are used to control the valve's position and provide feedback on its status.
What are the types of electric actuators used for valves?
The types of electric actuators used for valves include multi-turn electric actuators, linear output electric actuators, and 1/4 turn electric actuators. These types have specific advantages and are suitable for different valve applications, depending on the required level of control and torque.
How do I select the right electric actuator for my valve application?
When selecting an electric actuator for a valve application, factors to consider include the type of actuator (control or on/off type), the required output torque or displacement thrust, the frequency of valve use, and the power requirements. It is also important to choose a reliable brand and consider the specific working conditions of the valve.
What role do electric actuators play in enhancing safety and environmental protection?
Electric actuators play a crucial role in enhancing safety and environmental protection in industrial processes. They enable accurate and reliable valve control, reducing the risk of human error and minimizing potential leaks or hazardous situations. Electric actuators also contribute to energy efficiency, process optimization, and compliance with environmental regulations.
Why is the proper selection and application of quarter turn actuators important?
The proper selection and application of quarter turn actuators are important to ensure the reliability, safety, and efficiency of power plants and other automated systems. By choosing the right actuator for the specific valve and considering factors such as torque requirements, power supply, and environmental conditions, optimal performance and longevity of the system can be achieved.