Committed to the research and development and production of fan motor series products.

Zhejiang Nicety Electric Machinery Co., LTD. (NEM), founded in 1993, currently NEM members are Hangzhou Sunlife Electric high-tech enterprise R & D center, Zhejiang Jiaxing Nicety production base and Longquan Nicety High-tech Enterprise company headquarters.
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The company has established a complete, effective quality management system, implemented the ISO/TS16949 international quality light system standard.
Products are mainly exported to North America, Europe, Middle East, Southeast Asia, South America and other countries and regions.
Unlike traditional fans that rely on brushes and commutators to operate, brushless fans use electronic circuits to control their rotation. This eliminates the need for physical brushes, resulting in a more efficient and reliable cooling solution. By utilizing magnets and sensors, brushless fans can dynamically adjust speed and airflow to optimize performance while minimizing energy consumption. Brushless fans are commonly used in a variety of applications that require cooling or air circulation, such as computers, electronics, and industrial equipment. Their energy efficiency, longevity, quiet operation, precise control, and compact design make them to traditional fans in a variety of applications. Whether in computers, industrial environments or automotive cooling systems, brushless fans deliver unparalleled performance and reliability. Employing this innovative cooling solution increases efficiency, reduces energy consumption and creates a more comfortable environment.
View MoreAn evaporative fan, also known as an evaporative air conditioner or wet cooler, is a device used to reduce ambient temperature. They cool the surrounding air by evaporating moisture, providing an energy-efficient and environmentally friendly air conditioning solution, especially suitable for dry and hot climate conditions. Evaporative fans use the evaporation principle of water to cool the air. During the evaporation process, a fan blows hot air through a water medium (usually wet filter paper or fluffy humidified fiber), so that the heat in the air is used to evaporate water, thereby cooling the air. This process lowers the temperature of the air while increasing its humidity. Evaporative fans typically consume less electrical energy than traditional refrigeration systems because they do not require compressed refrigerant. Additionally, evaporative fans do not emit harmful chemicals, making them environmentally friendly.
View MoreA blower is a fan that uses a special voltage supply to drive the blower's rotor to create airflow. It usually consists of an electromagnet stator and a permanent magnet rotor. The coils on the stator generate a magnetic field through electric current, while the permanent magnets on the rotor are acted upon by a fixed magnetic field. When current passes through the stator coil, the force generated by the magnetic field rotates the rotor, thereby driving the equipment to operate. The blower motor is precisely designed and machined to ensure its efficiency and reliability. It usually has low noise, high efficiency, long life and stable performance. Blower motors are widely used in various fields, such as electronic equipment cooling, automobile ventilation, industrial production, etc.
View MoreA brushed motor is a common type of DC motor with a relatively simple structure that uses brushes and brushes to transmit current to a rotating part to produce mechanical motion. A brushed motor consists of a rotating part called the rotor and a stationary part called the stator. The rotor usually includes permanent magnets, while the stator includes coils. Brushes and brushes are attached to the stator and they are in contact with the electronic slip rings of the rotating part so that current can enter the rotating part. The brushes are a conductive material, usually made of carbon or carbide, that are tightly attached to the stator along with the brushes (also called brush holders). The brushes pass current to the rotating part by contacting the collector ring (usually on the rotating part), thereby creating a magnetic field interaction and inducing rotational motion.
View MoreBrushed electronic fan, in which the motor adopts brushed DC motor technology. The motor of this kind of fan includes brushes and brushes that are in contact with the rotating part of the motor, called the rotor, to transfer current to the rotating part, which creates rotation. Brushed motors can easily change direction because the polarity of the current can be reversed, allowing the fan to rotate forward or reverse. The speed of the brushed motor can be precisely controlled by adjusting the current intensity, which allows the speed of the fan to be adjusted within a certain range.
View More2025.03
With the continuous development of air conditioning technology, Evaporator Fans, as a core component of air conditioning systems, has evolved from a simple ventilation component to an important factor in determining the performance, efficiency and service life of air conditioning systems. As people's demand for air quality, energy saving effects and temperature control accuracy continues to increase, the importance of Evaporator Fans is becoming increasingly prominent, and they play an indispensable role in modern air conditioning systems. The main function of Evaporator Fans is to evenly distribute the cold air in the coolant evaporator into the air circulation path of the entire air conditioning system. The evaporator is a key component in the air conditioning system responsible for heat exchange. The coolant evaporates from the evaporator and absorbs heat and takes away hot air. The working principle of Evaporator Fans is to use a fan to guide the cold air emitted by the evaporator into the room or cooling area to maintain the uniform temperature distribution of the air, thereby ensuring that the air conditioning system can work effectively under a wide range of environmental conditions and avoid comfort differences caused by air circulation or uneven temperature control. In modern air conditioning systems, the performance of Evaporator Fans directly affects cooling effects and energy efficiency. For traditional air conditioners, the working efficiency of the evaporator is often affected by the fan. If the fan runs unstable or the wind speed is insufficient, the heat exchange efficiency of the evaporator will be greatly reduced, causing the air conditioner to take longer to reach the required temperature, thereby increasing energy consumption and reducing the overall efficiency of the system. Therefore, while ensuring the rapid cooling of air conditioners, Evaporator Fans can also improve energy utilization and reduce unnecessary energy waste. With the advancement of technology, Evaporator Fans' design and materials have been continuously optimized, improving the overall performance of the air conditioning system. For example, modern Evaporator Fans adopts more efficient and durable motor technology, as well as an optimized blade design, which effectively reduces the resistance in air flow, thereby increasing the fan's air flow and wind speed. At the same time, innovative motor technology can reduce power consumption while maintaining efficient operation, and effectively reduce noise levels, which is particularly important for noise-sensitive user groups. In addition, the intelligent development of Evaporator Fans is also an important trend in the air conditioning industry in recent years. Through integration with temperature and humidity sensors, intelligent control systems, etc., Evaporator Fans can automatically adjust wind speed according to changes in the environment to achieve more accurate temperature control adjustment. This technological innovation not only improves the user's comfort experience, but also helps the air conditioning system to respond intelligently according to changes in the indoor and outdoor environment, effectively improving the adaptability and energy saving of air conditioning equipment. For example, in hot summers, Evaporator Fans can increase wind power at the beginning of the air conditioner starting to reduce indoor temperatures more quickly; and as the temperature gradually stabilizes, the fan's wind speed will automatically decrease, reducing energy consumption and extending the service life of the equipment. In recent years, with the increasing strictness of global energy conservation and environmental protection policies, the energy-saving characteristics of Evaporator Fans have become an important direction for R&D. The air conditioning industry is facing increasingly high energy efficiency requirements, especially under strict carbon emission standards and energy consumption restrictions. How to maintain the effectiveness of the air conditioning system while minimizing energy consumption has become a key goal of manufacturers' research and development. By adopting high-efficiency motors, low-noise blades and optimized air duct design, modern Evaporator Fans can effectively reduce power consumption and reduce the overall operating cost of air conditioning systems. In addition, the use of more environmentally friendly materials and production processes has greatly reduced the environmental burden on the production and recycling process of Evaporator Fans, which will help promote the transformation of the air conditioning industry toward green and sustainable development. However, although Evaporator Fans plays an increasingly important role in improving air conditioning performance, consumers still need to pay attention to indicators in multiple dimensions when purchasing air conditioners. The fan's noise level, wind speed regulation range, energy efficiency level, and long-term operation stability are all important factors that determine the performance of the air conditioning system. In weather conditions, the stability and high temperature resistance of Evaporator Fans also play a crucial role in the reliability of the air conditioning system. Therefore, in the procurement and maintenance of air conditioners, understanding the technical characteristics and advantages of Evaporator Fans can help consumers make more scientific and reasonable choices. With the continuous innovation of technology, the future Evaporator Fans will be more intelligent and energy-saving, and the functions will be more diverse, and even personalized customization can be achieved. For example, through IoT technology, Evaporator Fans can exchange and linkage control data with other components of the air conditioning system in real time, and automatically optimize wind speed and wind direction according to changes in indoor and outdoor temperature and humidity, thereby further improving the comprehensive efficiency and user experience of the air conditioning system. At the same time, with the continuous development of artificial intelligence technology, future Evaporator Fans may also be able to automatically adjust working parameters through self-learning mechanisms to adapt to users' specific needs and environmental conditions. Overall, the role of Evaporator Fans in modern air conditioning systems cannot be ignored. They not only directly affect the cooling effect and energy efficiency of the air conditioner, but also determine the reliability, noise level and service life of the air conditioner system to a certain extent. With the continuous advancement of technology and the diversification of user needs, Evaporator Fans will play an increasingly important role in the air-conditioning industry and promote the development of air-conditioning technology toward more intelligent, efficient and environmentally friendly.
2025.03
With the continuous improvement of industrial equipment performance and increasing density, the importance of cooling systems in maintaining equipment stability and improving efficiency is becoming increasingly prominent. Against this background, DC Brushless Centrifugal Fans has gradually become the core solution in the industrial cooling field with its high efficiency, low energy consumption and strong stability, and has received widespread attention and recognition from various industries. DC Brushless Centrifugal Fans stand out with its high rev and low power design. Compared with traditional cooling technology, this type of fan achieves higher energy conversion efficiency through intelligent control of brushless motors, reducing energy losses caused by friction, thus having significant advantages in energy management. Under the current global trend of energy conservation and emission reduction, this feature undoubtedly provides industrial enterprises with more choices. In recent years, DC Brushless Centrifugal Fans has been increasing in application cases in many fields such as data centers, industrial automation, and automobile manufacturing. As one of the high-energy-consuming industries, data centers have particularly demanding cooling equipment. DC Brushless Centrifugal Fans meets the cooling needs of server equipment with its high air volume and precise control. At the same time, dynamic optimization is achieved through intelligent adjustment, which greatly reduces operating costs. In the field of industrial automation, robotic arms, production equipment, etc. have extremely high requirements for continuous heat dissipation. Brushless centrifugal fans provide stable airflow support to enable the equipment to maintain performance in high-load operating environments. At the same time, the industry's requirements for product reliability and lifespan have also prompted enterprises to continue to make efforts in technological innovation. DC Brushless Centrifugal Fans uses a brushless motor design to completely solve the problem of traditional fans shortening their life due to brush wear, greatly improving the stability of equipment operation. This feature not only provides guarantees for the long-term failure-free operation of industrial equipment, but also effectively reduces maintenance costs and brings higher return on investment to enterprises. According to the latest report released by market analysis agencies, the global DC Brushless Centrifugal Fans market is expanding rapidly at a compound growth rate of more than 8% per year. Especially in the Asia-Pacific region, with the deepening of manufacturing upgrading and intelligent transformation, the demand for efficient cooling equipment will continue to increase in the next few years. This not only brings market opportunities to related manufacturing companies, but also provides impetus for further improvement of industry standards. In addition, policy-level support is also promoting development in this area. For example, many countries and regions are implementing stricter energy efficiency regulations, which put forward higher requirements on the energy consumption of industrial equipment. Against this background, the energy-saving characteristics of DC Brushless Centrifugal Fans have become an important means for enterprises to meet compliance requirements, and at the same time strengthen their market competitiveness. Looking ahead, with the continuous improvement of intelligent control technology and the improvement of material processes, DC Brushless Centrifugal Fans will show stronger potential in the field of industrial cooling. When choosing cooling solutions, enterprises should fully consider the comprehensive performance, adaptability and long-term economic benefits of the products, so as to provide strong support for the efficient operation and sustainable development of industrial equipment. The widespread application of DC Brushless Centrifugal Fans not only reflects the industry's urgent need for efficient cooling technology, but also shows the inevitable trend of industrial cooling solutions in the future development of intelligent and energy-saving directions.
2025.03
As the automotive industry undergoes a paradigm shift toward electrification, the demand for efficient, reliable, and sustainable components has reached an all-time high. Among these critical components, automotive DC centrifugal fans are emerging as indispensable solutions for optimizing electric vehicle (EV) performance. These fans are not merely auxiliary devices but pivotal contributors to the functionality and longevity of electric vehicles, addressing challenges unique to EV technology. The primary role of automotive DC centrifugal fans is to ensure effective thermal management, a factor of paramount importance in EV systems. Unlike internal combustion engine vehicles, EVs rely on high-capacity lithium-ion batteries and intricate electronic control systems. These components are highly sensitive to temperature fluctuations, with performance and safety risks significantly elevated under thermal conditions. DC centrifugal fans deliver precise and efficient airflow, maintaining operating temperatures for batteries, inverters, and motors. This precision minimizes the risk of overheating and ensures consistent performance even in demanding environments. Another key advantage of DC centrifugal fans is their exceptional energy efficiency. Electric vehicles are designed to maximize energy utilization, as every watt counts toward extending driving range and enhancing overall efficiency. Traditional fan systems often consume more power and deliver inconsistent airflow. In contrast, DC centrifugal fans leverage advanced motor technology to provide energy savings without compromising performance, aligning perfectly with the sustainability goals of the EV industry. Noise reduction is another significant consideration in modern electric vehicles. Unlike conventional cars, EVs operate with near-silent powertrains, making any additional noise from auxiliary components more noticeable. Automotive DC centrifugal fans are engineered to deliver quiet operation, employing aerodynamic designs and advanced materials to minimize sound output. This contributes to the overall driving experience, ensuring the cabin remains tranquil and free from intrusive noises. The durability and adaptability of DC centrifugal fans further cement their importance. EVs often operate under varied environmental conditions, from heat to freezing cold. These fans are built to withstand these challenges, utilizing robust materials and advanced sealing techniques to resist dust, moisture, and vibrations. Moreover, their compact designs allow them to integrate seamlessly into the confined spaces of EV architectures, offering manufacturers greater flexibility in vehicle design. As the EV market continues to expand, the development of next-generation DC centrifugal fans remains a priority for automotive suppliers. Innovations in motor efficiency, smart control systems, and material science are driving the evolution of these fans, ensuring they meet the growing demands of an industry focused on sustainability and performance. The adoption of advanced manufacturing processes further ensures scalability and cost-effectiveness, enabling these critical components to remain accessible as EV adoption accelerates globally. In conclusion, automotive DC centrifugal fans are far more than supplementary components in electric vehicles; they are integral to the performance, efficiency, and reliability of modern EVs. By addressing the unique thermal and energy challenges associated with electric drivetrains, these fans are helping manufacturers and consumers alike realize the full potential of electric mobility. Their ongoing innovation and integration into the EV ecosystem highlight their indispensable role in the future of transportation.
2025.02
The core role of motor control technologyMotor control technology is the basis for Automotive DC Centrifugal fans to achieve stepless speed regulation and precise control. It involves a series of complex algorithms and electronic circuits for precise adjustment of motor operating parameters such as speed and torque. The core of this technology is to ensure that the fan can run at the optimal speed according to actual needs, maintain high efficiency and low noise. 1. Pulse Width Modulation (PWM) TechnologyPulse Width Modulation technology is a method of adjusting the average voltage of the motor by changing the pulse width. In DC centrifugal fans, PWM technology is widely used to achieve stepless speed regulation. By accurately controlling the width of the pulse, the speed of the motor can be smoothly adjusted to meet different cooling needs. The advantages of PWM technology are its wide speed regulation range, high accuracy, fast response speed, and effective reduction of energy consumption and noise. 2. Brushless DC Motor ControlBrushless DC motors are widely used in automotive DC centrifugal fans due to their high efficiency, long life and low maintenance cost. The key to controlling a brushless DC motor is to precisely adjust its input voltage and current to achieve the desired speed and torque. This is usually achieved through advanced motor control algorithms, such as vector control or direct torque control. These algorithms can monitor the motor's operating status in real time and dynamically adjust based on feedback signals to ensure that the fan operates in the optimal state. 3. Intelligent control algorithmIn order to further improve the speed regulation accuracy and system stability, intelligent control algorithms are widely used in the control system of automotive DC centrifugal fans. These algorithms can dynamically adjust the motor's control parameters based on real-time data to adapt to different operating conditions and load changes. Through predictive control algorithms, the fan's speed change trend can be predicted in advance and adjusted in advance to avoid overspeed or underspeed. Key technologies for achieving stepless speed regulationStepless speed regulation means that the fan can smoothly adjust its speed within a certain range to adapt to different cooling needs. In automotive DC centrifugal fans, the key technologies for achieving stepless speed regulation include: 1. Variable frequency speed regulation technologyVariable frequency speed regulation technology adjusts the speed of the motor by changing the power supply frequency of the motor. In automotive applications, this usually involves converting the battery's DC power into AC power and adjusting its frequency through a frequency converter. As the frequency changes, the motor's speed will also be adjusted accordingly, thus achieving stepless speed regulation. The advantages of variable frequency speed regulation technology are its wide speed regulation range, high precision, and effective reduction in energy consumption and noise. 2. Microcontroller (MCU) controlModern automotive DC centrifugal fans generally use microcontrollers as control centers. MCUs are able to receive real-time data from sensors, such as temperature, humidity, and wind speed, and process and make decisions based on preset algorithms. By accurately controlling the input voltage and current of the motor, MCUs are able to achieve stepless speed regulation and precise control of the fan. MCUs also have fault detection and protection functions, which can monitor the operating status of the fan in real time and take timely measures in the event of a fault to ensure the safe and stable operation of the system. Methods for accurately controlling the fan speedIn order to achieve precise control of automotive DC centrifugal fans, a series of measures need to be taken to ensure that the fan speed can stably and accurately reach the preset value. 1. Closed-loop control systemThe closed-loop control system is the key to achieving precise control. It monitors the fan's speed and torque and other parameters in real time, compares them with the preset values, and then adjusts them according to the error signal. This system can automatically compensate for the impact of external interference and internal changes on the fan speed, thereby ensuring the stable operation of the fan. 2. Sensor technologySensors are an important tool for achieving precise control. In Automotive DC Centrifugal fans, commonly used sensors include speed sensors, temperature sensors, and humidity sensors. These sensors can monitor the fan's operating status and environmental parameters in real time and feed the data back to the control system. The control system makes decisions and adjustments based on these data to achieve precise control of the fan. 3. Software algorithm optimizationIn order to achieve higher control accuracy and stability, the control software needs to be continuously optimized. This includes improving the control algorithm, increasing data processing speed and accuracy, and enhancing the system's anti-interference ability. Through continuous optimization and improvement, the control performance and stability of automotive DC centrifugal fans can be further improved.