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C-Lin’s Electric Drive and Control Series offers a comprehensive solution for industrial automation, integrating intelligent control, energy efficiency, and reliable protection.
This series includes PLCs with fast logic processing and expandable I/O modules, 4G-enabled gateways for remote monitoring, and industrial-grade remote I/O modules with RS485/CAN communication. Our inverters ensure stable, energy-saving speed control across industries, while intelligent soft starters offer smooth motor startup and comprehensive protection.
Motor protectors respond quickly to electrical faults, ensuring operational safety.
AC and DC motor speed regulators provide stepless, precise control for a wide range of motor-driven systems.
With a focus on proprietary technology, Xinling Electrical has obtained over 450 patents and 120 software copyrights.
In 2023 , 88 new patents were added, including 23 invention patents, significantly enhancing the unique innovation of its technologies and boosting the competitive edge of its products.
Electrical drives are systems that control the operation of electric motors, including starting, speed regulation, and stopping, by converting electrical energy into mechanical motion. Electrical control involves managing these drives to ensure efficient and safe motor performance.
A motor protector monitors parameters like current, voltage, temperature, speed, and torque to prevent damage. It disconnects the motor from the power supply during faults or abnormal conditions, safeguarding the motor and its circuit.
A soft starter reduces the voltage supplied to the motor during startup, providing a smooth acceleration by gradually increasing voltage. In contrast, a Variable Frequency Drive (VFD) not only controls voltage but also adjusts the frequency, enabling precise speed control throughout the motor’s operation.
A soft starter works by controlling the voltage supplied to the motor, gradually ramping it up from a low level to the full operating voltage. This approach allows the motor to start smoothly, reducing mechanical stress and electrical inrush currents.
To size an inverter, first determine the total wattage of all devices you intend to power. Add up the wattage of each device, then select an inverter that can handle this total load, considering a margin for safety and potential future additions.
The lifespan of an inverter varies by type and usage. Depending on the type, an inverter can last up to 25 years. However, factors like electro-mechanical wear and temperature fluctuations can affect longevity, with some inverters failing after only a few years.
A time relay is a device that controls the timing of electrical events, opening or closing contacts after a predetermined time delay.
The primary difference between a standard relay and a timer relay is that a standard relay operates immediately upon receiving an electrical signal, whereas a timer relay introduces a delay before activating or deactivating its contacts.
A counting relay is designed to count the number of events or pulses in a circuit, activating its output after a specified count has been reached.
A meter counter works by tallying the number of electrical pulses it receives, often used to measure quantities like flow rate or production counts.
A liquid level relay monitors the liquid level in a container, activating or deactivating a pump or alarm when the liquid reaches a certain threshold.
A level relay for conductive liquids detects the level of conductive liquids, using the conductivity to complete a circuit and trigger actions like activating a pump or alarm.
To test a solid-state relay (SSR), begin with a visual inspection to check for any physical damage or loose connections. Next, verify that the input side of the SSR receives the correct control voltage. Use a multimeter to measure the output side, ensuring it responds appropriately when the control input is applied. Finally, connect the SSR to its intended load and confirm it operates as expected under normal conditions.
A solid-state relay operates by using semiconductor components to switch electrical circuits on or off without moving parts, providing faster and more reliable operation compared to electromechanical relays.
The main difference between a standard relay and a solid-state relay lies in their construction and operation: standard relays use electromagnetic coils and moving parts to open or close contacts, while solid-state relays rely on semiconductor components to perform the switching function, offering advantages like faster response times and longer lifespan.
