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Temperature Controllers
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description
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PC21-F35B-0100
Watlow Power Series controller, 3-phase/2-leg control, (4 SCRs), with heater diagnostics, 250A, fan cooled, 200V to 480V voltage output, load current feedback (0-10V or 0-20mA)
customer-359
Quick Quote
PC81-F35A-0000
Watlow Power Series controller, 2 single-phase zones, with heater diagnostics, 250A, fan cooled, 24V to 120V voltage output
customer-359
Quick Quote
PC21-F35B-0000
Watlow Power Series controller, 3-phase/2-leg control, (4 SCRs), with heater diagnostics, 250A, fan cooled, 200V to 480V voltage output
customer-359
Quick Quote
PC81-F35A-0100
Watlow Power Series controller, 2 single-phase zones, with heater diagnostics, 250A, fan cooled, 24V to 120V voltage output, load current feedback (0-10V or 0-20mA)
customer-359
Quick Quote
PC81-F20C-1000
Watlow Power Series controller, 2 single-phase zones, with heater diagnostics, 120A, fan cooled, 200V to 600V voltage output, EIA/TIA-232/485 communications
customer-359
Quick Quote
PC81-F20C-0100
Watlow Power Series controller, 2 single-phase zones, with heater diagnostics, 120A, fan cooled, 200V to 600V voltage output, load current feedback (0-10V or 0-20mA)
customer-359
Quick Quote
PC30-N25B-0000
Watlow Power Series controller, 3-phase/3-leg control, (6 SCRs), 85A, 200V to 480V voltage output
customer-359
Quick Quote
PC30-N30A-0000
Watlow Power Series controller, 3-phase/3-leg control, (6 SCRs), 105A, 24V to 120V voltage output
customer-359
Quick Quote
PC10-N20C-1000
Watlow Power Series controller, 1 phase, 100A, 200V to 600V voltage output, EIA/TIA-232/485 communications
customer-359
Quick Quote
PC10-F25C-1000
Watlow Power Series controller, 1 phase, 200A, fan cooled, 200V to 600V voltage output, EIA/TIA-232/485 communications
customer-359
Quick Quote
PC10-F20C-1000
Watlow Power Series controller, 1 phase, 125A, fan cooled, 200V to 600V voltage output, EIA/TIA-232/485 communications
customer-359
Quick Quote
PC10-F20A-1000
Watlow Power Series controller, 1 phase, 125A, fan cooled, 24V to 120V voltage output, EIA/TIA-232/485 communications
customer-359
Quick Quote
PC11-N20A-0000
Watlow Power Series controller, 1 phase, with heater diagnostics, 100A, 24V to 120V voltage output
customer-359
Quick Quote
PC10-N25C-1000
Watlow Power Series controller, 1 phase, 140A, 200V to 600V voltage output, EIA/TIA-232/485 communications
customer-359
Quick Quote
PC11-N20B-0100
Watlow Power Series controller, 1 phase, with heater diagnostics, 100A, 200V to 480V voltage output, load current feedback (0-10V or 0-20mA)
customer-359
Quick Quote
PC11-F20C-1000
Watlow Power Series controller, 1 phase, with heater diagnostics, 125A, fan cooled, 200V to 600V voltage output, EIA/TIA-232/485 communications
customer-359
Quick Quote
PC11-F25A-0100
Watlow Power Series controller, 1 phase, with heater diagnostics, 200A, fan cooled, 24V to 120V voltage output, load current feedback (0-10V or 0-20mA)
customer-359
Quick Quote
PC10-F30B-1000
Watlow Power Series controller, 1 phase, 250A, fan cooled, 200V to 480V voltage output, EIA/TIA-232/485 communications
customer-359
Quick Quote
PC11-N30B-0100
Watlow Power Series controller, 1 phase, with heater diagnostics, 165A, 200V to 480V voltage output, load current feedback (0-10V or 0-20mA)
customer-359
Quick Quote
PC11-F30C-0100
Watlow Power Series controller, 1 phase, with heater diagnostics, 250A, fan cooled, 200V to 600V voltage output, load current feedback (0-10V or 0-20mA)
customer-359
Quick Quote
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Temperature Controllers
General Guide & Overview
Temperature controllers play a vital role in maintaining a stable temperature in various applications. Whether it's a plastic extrusion machine, a packaging line, or a food processing facility, temperature controllers ensure that the desired temperature is consistently met. In this article, we will explore the different types of temperature controllers and their importance in industrial settings.
There are two basic types of temperature controllers: open loop control and closed loop control. Open loop control applies continuous heating or cooling without considering the actual temperature output. This type of control is commonly used in simple applications where precise temperature regulation may not be critical.
Closed loop control, on the other hand, is more advanced and widely used in industrial processes. It constantly measures the actual temperature output and adjusts the heating or cooling devices to maintain a constant desired temperature. Closed loop control ensures that the temperature remains within the desired range, resulting in consistent quality and optimal performance.
Temperature controllers find applications in various industries, including plastic extrusion, packaging, heat-treating, healthcare, and food processing. In plastic extrusion, temperature controllers help maintain the correct temperature for melting and shaping plastic materials. In packaging and food processing, they ensure that products are stored or processed at the required temperatures to maintain freshness and safety.
Understanding the different types of temperature controllers and their functions is essential for industries that rely on precise temperature control. In the following sections, we will delve deeper into the intricacies of temperature controllers and explore their common applications in detail.
Introduction to Temperature Controllers
A temperature controller is a crucial device used to maintain a desired temperature at a specified value. It is commonly found in various applications, including thermostats in homes, hot water heaters, ovens, and refrigerators. By continuously comparing the actual temperature to a user-determined setpoint, temperature controllers ensure that heating or cooling devices are adjusted to maintain the desired temperature.
Temperature controllers play a vital role in controlling temperature in a wide range of applications, providing precision and stability. Whether it's regulating the temperature in an oven to ensure perfect baking or maintaining the optimal temperature in a refrigerator to preserve food, temperature controllers are instrumental in keeping processes and environments at the desired temperature.
Common Controller Applications
Temperature controllers play a crucial role in managing manufacturing processes across various industries. They are widely utilized in industrial heating and cooling processes including plastic extrusion, packaging, food processing, and even blood banks.
In the field of plastic extrusion, temperature controllers ensure precise control over the temperature of the extruder barrel, optimizing the quality and consistency of the extruded plastic products. In packaging machines, temperature controllers regulate the temperature of sealing elements, guaranteeing secure and reliable packaging. With food processing, temperature controllers maintain the ideal temperatures for cooking, baking, drying, and preserving food products.
Additionally, temperature controllers are essential in the operation of thermoforming machines, which are used to create various plastic products such as trays, containers, and packaging materials. These controllers ensure consistent and accurate temperature control during the heating, shaping, and cooling stages of the process.
Benefits in Food Storage and Blood Banks
In the food storage industry, temperature controllers help maintain optimal temperatures in cold storage facilities, keeping perishable items fresh and extending their shelf life. By providing precise temperature regulation, temperature controllers prevent potential spoilage and preserve the quality of stored food products.
Similarly, temperature control is critical in blood banks to ensure the proper storing conditions for blood and plasma products. Temperature controllers help maintain the required temperature range, preserving the integrity and safety of these life-saving biological materials.
Parts and Functions of a Temperature Controller
Temperature controllers play a crucial role in managing and maintaining precise temperature levels in various applications. These controllers consist of several essential parts that work together to achieve accurate temperature control.
The inputs of a temperature controller are responsible for measuring the temperature. They rely on sensors such as thermocouples, resistive thermal devices (RTDs), or other linear inputs to gather temperature data. These inputs provide the necessary information for the controller to make adjustments accordingly.
On the other hand, the outputs of a temperature controller are responsible for controlling the temperature-regulating devices. These outputs act as the interface between the controller and the equipment used to adjust the temperature. For example, in heating applications, the output may control heating elements, while in cooling applications, it may control refrigeration components.
Temperature controllers also feature important parameters, including the setpoint and the alarm value. The setpoint refers to the desired target temperature that the controller aims to achieve and maintain. Meanwhile, the alarm value serves as a threshold that triggers an alarm or alert when the process reaches specific conditions, ensuring optimal control and safety.
Additionally, temperature controllers employ various control actions, such as ON/OFF control, proportional control, integral control, derivative control, or a combination of these actions known as PID control. These control actions enable the temperature controller to dynamically adjust the heating or cooling devices based on the temperature measurements and the desired setpoint, ensuring precise and efficient temperature control.
FAQ
What is a temperature controller?
A temperature controller is a device used to maintain a desired temperature at a specified value by continuously comparing the actual temperature to a user-determined setpoint and adjusting heating or cooling devices accordingly.
What are the types of temperature controllers?
There are two basic types of temperature controllers: open loop and closed loop control. Open loop control simply applies continuous heating or cooling, while closed loop control constantly measures and adjusts the output temperature to maintain a constant desired temperature.
Where are temperature controllers commonly used?
Temperature controllers are extensively used in various industries such as plastic extrusion, packaging, food processing, healthcare, and manufacturing processes to regulate temperature in machines, storage, and production environments.
What are the key parts of a temperature controller?
Temperature controllers consist of inputs and outputs. Inputs measure the temperature using sensors, while outputs control temperature-regulating devices. Temperature controllers also have parameters such as setpoint and alarm value, and can employ different control actions such as ON/OFF, proportional, integral, derivative, or PID control.