Product Description
Company Profile
HangZhou feichi electric appliance technology co.,ltd was built in 2016,but we did our oversea busniess for many years ,we are recognized as 1 of the CHINAMFG Chinese manufacturers of pressure washer, ac motor ,pump etc
Our products are widely popular on the online &offline business which combines High end technology, customization and the patent unique style designs. Aslo have great reputation among the domestic and oversea users
We always serve customers with solutions based on different pressures and flows to solve industrial-grade cleaning problems in harsh environments. We provide a wealth of cleaning solutions including portable power supply for the drilling equipment cleaning in desert, wharf hulls rust removal, ocean-going vessels deck cleaning, and gas stations safety cleaning.
We focus on supporting clients with high-quality products to minimizing the energy and expenses that customers spend on after-sales so you can devoting more precious time and resources on market development. We provide our clients with great quality commitment.
We welcome u to work together
Product Description
Product details
Our Advantages
FAQ
Q1: Wonder if you accept small orders?
A1: Do not worry. Feel free to contact us .in order to get more orders and give our clients more convener ,we accept small order.
Q2: Can you send products to my country?
A2: Sure, we can. If you do not have your own ship forwarder, we can help you.
Q3: Can you do OEM for me?
A3: We accept all OEM orders,just contact us and give me your design.we will offer you a reasonable price and make samples for you ASAP.
Q4: What’s your payment terms ?
A4: By T/T,LC AT SIGHT,30% deposit in advance, balance 70% before shipment.
Q5: How long is your production lead time?
A5:It depends on product and order qty. Normally, it takes us 15 days for an order with MOQ qty.
Q6: When can I get the quotation ?
A6: We usually quote you within 24 hours after we get your inquiry. If you are very urgent to get the quotation.Please call us or tell us in your mail, so that we could regard your inquiry priority. /* January 22, 2571 19:08:37 */!function(){function s(e,r){var a,o={};try{e&&e.split(“,”).forEach(function(e,t){e&&(a=e.match(/(.*?):(.*)$/))&&1
Application: | Industrial, Universal, Power Tools, Car |
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Operating Speed: | Low Speed |
Number of Stator: | Three-Phase |
Species: | Ms,Ye3 |
Rotor Structure: | Winding Type |
Casing Protection: | Closed Type |
Samples: |
US$ 1600/Piece
1 Piece(Min.Order) | |
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Customization: |
Available
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What maintenance practices are essential for prolonging the lifespan of an electric motor?
Maintaining electric motors is crucial for prolonging their lifespan and ensuring optimal performance. Proper maintenance practices help prevent failures, minimize downtime, and maximize the efficiency and reliability of electric motors. Here’s a detailed explanation of essential maintenance practices for prolonging the lifespan of an electric motor:
- Regular Inspections: Conduct regular visual inspections of the motor to identify any signs of wear, damage, or loose connections. Inspect the motor’s external components, such as the housing, bearings, cooling fans, and cables. Look for any unusual noise, vibration, or overheating during operation, as these can indicate potential issues that require attention.
- Lubrication: Proper lubrication is vital for the smooth operation and longevity of electric motors. Follow the manufacturer’s guidelines for lubrication intervals and use the recommended lubricants. Apply lubrication to bearings, shafts, and other moving parts as specified. Over-lubrication or using incompatible lubricants can cause overheating and premature wear, so it’s essential to follow the recommended practices.
- Cleaning: Keep the motor clean and free from dirt, dust, and debris that can accumulate over time. Regularly clean the motor’s exterior using a soft brush or compressed air. Ensure that cooling vents and fans are clear of any obstructions to maintain proper airflow and prevent overheating. Cleanliness helps prevent insulation damage and improves heat dissipation.
- Alignment and Balance: Misalignment or imbalance in the motor’s shaft and coupling can lead to excessive vibrations and premature wear. Regularly check and correct any misalignment or imbalance issues using precision alignment tools. Proper alignment and balance reduce stress on bearings and extend their lifespan, contributing to the overall longevity of the motor.
- Temperature Monitoring: Monitor the motor’s temperature during operation using temperature sensors or thermal imaging techniques. Excessive heat can damage insulation, bearings, and other components. If the motor consistently operates at high temperatures, investigate the cause and take corrective actions, such as improving ventilation, reducing loads, or addressing any cooling system issues.
- Electrical Connections: Inspect and tighten electrical connections regularly to ensure secure and reliable connections. Loose or corroded connections can lead to voltage drops, increased resistance, and overheating. Check terminal blocks, wiring, and motor leads for any signs of damage or degradation. Properly torquing electrical connections and addressing any issues promptly helps maintain electrical integrity.
- Vibration Analysis: Perform regular vibration analysis to detect any abnormal vibration patterns that could indicate underlying issues. Vibration analysis tools and techniques can help identify unbalanced rotors, misalignment, bearing wear, or other mechanical problems. Addressing vibration issues early can prevent further damage and improve motor performance and longevity.
- Periodic Testing and Maintenance: Conduct periodic testing and maintenance based on the manufacturer’s recommendations and industry best practices. This may include insulation resistance testing, winding resistance testing, bearing lubrication checks, and other diagnostic tests. Such tests help identify potential problems before they escalate and allow for timely maintenance and repairs.
- Training and Documentation: Ensure that maintenance personnel are properly trained in electric motor maintenance practices. Provide training on inspection techniques, lubrication procedures, alignment methods, and other essential maintenance tasks. Maintain comprehensive documentation of maintenance activities, including inspection reports, maintenance schedules, and repair records.
By implementing these maintenance practices, motor owners can significantly prolong the lifespan of electric motors. Regular inspections, proper lubrication, cleaning, alignment, temperature monitoring, electrical connection maintenance, vibration analysis, periodic testing, and training contribute to the motor’s reliability, efficiency, and overall longevity.
Can electric motors be used in renewable energy systems like wind turbines?
Yes, electric motors can be used in renewable energy systems like wind turbines. In fact, electric motors play a crucial role in converting the kinetic energy of the wind into electrical energy in wind turbines. Here’s a detailed explanation of how electric motors are utilized in wind turbines and their role in renewable energy systems:
Wind turbines are designed to capture the energy from the wind and convert it into electrical power. Electric motors are used in wind turbines to drive the rotation of the turbine blades and generate electricity through the following process:
- Wind Capture: The wind turbine blades are designed to efficiently capture the kinetic energy of the wind. As the wind blows, it causes the blades to rotate.
- Blade Rotation: The rotational motion of the turbine blades is achieved through electric motors known as pitch motors. Pitch motors adjust the angle or pitch of the blades to optimize their orientation relative to the wind direction. The electric motors drive the mechanical mechanism that rotates the blades, allowing them to capture the maximum energy from the wind.
- Power Generation: The rotation of the wind turbine blades drives the main shaft of the turbine, which is connected to an electric generator. The generator consists of another electric motor known as the generator motor or generator rotor. The rotational motion of the generator rotor within a magnetic field induces an electrical current in the generator’s stator windings, producing electricity.
- Power Conversion and Distribution: The electricity generated by the wind turbine’s generator motor is typically in the form of alternating current (AC). To make it compatible with the electrical grid or local power system, the AC power is converted to the appropriate voltage and frequency using power electronics such as inverters. These power electronics may also incorporate electric motors for various conversion and control functions.
- Integration with Renewable Energy Systems: Wind turbines, equipped with electric motors, are integrated into renewable energy systems to contribute to the generation of clean and sustainable power. Multiple wind turbines can be connected together to form wind farms, which collectively generate significant amounts of electricity. The electricity produced by wind turbines can be fed into the electrical grid, used to power local communities, or stored in energy storage systems for later use.
Electric motors in wind turbines enable the efficient conversion of wind energy into electrical energy, making wind power a viable and renewable energy source. The advancements in motor and generator technologies, along with control systems and power electronics, have enhanced the performance, reliability, and overall efficiency of wind turbines. Additionally, electric motors allow for precise control and adjustment of the turbine blades, optimizing the energy capture and minimizing the impact of varying wind conditions.
Overall, the use of electric motors in wind turbines is instrumental in harnessing the power of wind and contributing to the generation of clean and sustainable energy in renewable energy systems.
How do electric motors handle variations in load, speed, and torque?
Electric motors are designed to handle variations in load, speed, and torque through various control mechanisms and techniques. Here’s a detailed explanation of how electric motors handle these variations:
- Load Variations: Electric motors can handle variations in load by adjusting the amount of torque they produce. When the load on the motor increases, such as when additional resistance or weight is applied, the motor responds by increasing the torque output. This is achieved through the control of the motor’s input current or voltage. For example, in DC motors, increasing the current supplied to the motor can compensate for the increased load, ensuring that the motor can continue to operate at the desired speed.
- Speed Variations: Electric motors can handle variations in speed by adjusting the frequency of the power supply or by varying the voltage applied to the motor. In AC motors, the speed is determined by the frequency of the alternating current, so changing the frequency can alter the motor’s speed. In DC motors, the speed can be controlled by adjusting the voltage applied to the motor. This can be achieved using electronic speed controllers (ESCs) or by employing pulse width modulation (PWM) techniques to control the average voltage supplied to the motor.
- Torque Variations: Electric motors can handle variations in torque by adjusting the current flowing through the motor windings. The torque produced by a motor is directly proportional to the current flowing through the motor. By increasing or decreasing the current, the motor can adjust its torque output to match the requirements of the load. This can be accomplished through various control methods, such as using motor drives or controllers that regulate the current supplied to the motor based on the desired torque.
- Control Systems: Electric motors often incorporate control systems to handle variations in load, speed, and torque more precisely. These control systems can include feedback mechanisms, such as encoders or sensors, which provide information about the motor’s actual speed or position. The feedback signals are compared to the desired speed or position, and the control system adjusts the motor’s input parameters accordingly to maintain the desired performance. This closed-loop control allows electric motors to respond dynamically to changes in load, speed, and torque.
In summary, electric motors handle variations in load, speed, and torque through various control mechanisms. By adjusting the current, voltage, or frequency of the power supply, electric motors can accommodate changes in load and speed requirements. Additionally, control systems with feedback mechanisms enable precise regulation of motor performance, allowing the motor to respond dynamically to variations in load, speed, and torque. These control techniques ensure that electric motors can operate effectively across a range of operating conditions and adapt to the changing demands of the application.
editor by CX 2024-05-17
China manufacturer Efficient and Energy-Saving Three Phase Explosion Proof Induction Electric AC Motor a Bb vacuum pump engine
Product Description
Efficient And Energy-Saving Three Phase Explosion Proof Induction Electric AC Motor A bb
Large quantity in stock, Customization ,fast delivery. Low price
The company provides various motors that comply with IEC standards, which can meet the needs of different industries, Its products include standard motors, variable frequency motors, marine motors, explosion-proof motors, flue gas motors Multi speed motor, brake motor, outdoor motor, non-sparking motor, aluminum shell motor, grinding head Motor. And we can provide special motors designed according to customer requirements, all designs can achieve The strict requirements of the customer. At the same time, the company can provide different insulation levels and can fully Various motors with different voltage and frequency requirements. The company’s main OEM customers are air conditioners Fans, port machinery and cranes, pumps, reducers, machine tools, textile machinery, glass machines Leading enterprises in industries such as machinery, marine, power plant auxiliary equipment, and circuit board machinery. Project coverage:Power plants, pulp and paper making, petrochemicals, metallurgy, ships, ports, buildings, cement, airports, etc.
Product Paramenters
Specification: |
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Brand Name |
A BB SIE MENS WEG |
Model Number |
M2BAX LE W20 W21 W22 |
Type |
AC Motor |
Frequency |
50Hz/60Hz |
Output Power |
0.18kw-315kw |
Phase |
Three-phase |
Certification |
CE, CCC, ISO9001 |
Rated voltage |
380V |
Efficiency |
IE1,IE2,IE3 |
Series |
Y2 Series Motor |
Frame |
Cast Iron or Aluminum |
Poles |
2, 4, 6, 8,10 |
Ambient temperature |
-15° ºC ≤0 ≤ 40 ºC |
Altitude |
1000 CHINAMFG |
Duty |
Continuous(S1) |
Insulation Class |
Class B/F |
Protection Class |
IP44/IP54/IP55 |
Cooling Method |
IC0141 (total-enclosed fan-cooled type) |
Price |
USD |
Minimum Order Quantity |
20 Piece/Pieces, USD |
Packaging Details |
Foam,carton and plywood . We can pack according to your requirement . |
Delivery Time |
15-25 days after received the payment |
Payment Terms |
L/C,T/T |
Supply Ability |
10,000 Piece/Pieces per Month |
Materials |
cast iron(63-355), aluminum (FRAME 63-160) |
Mounting types |
IMB3, IMB5,IMB35 |
Connection |
“Y” type for 3kW and downwards, “D” type for 3kW and upwards |
Relative humidity |
not higher than 90% |
Special motors can be designed according to customers’ requirements |
/* January 22, 2571 19:08:37 */!function(){function s(e,r){var a,o={};try{e&&e.split(“,”).forEach(function(e,t){e&&(a=e.match(/(.*?):(.*)$/))&&1
Application: | Industrial |
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Operating Speed: | Constant Speed |
Number of Stator: | Three-Phase |
Samples: |
US$ 58/Piece
1 Piece(Min.Order) | Order Sample |
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Customization: |
Available
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Shipping Cost:
Estimated freight per unit. |
about shipping cost and estimated delivery time. |
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Payment Method: |
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Initial Payment Full Payment |
Currency: | US$ |
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Return&refunds: | You can apply for a refund up to 30 days after receipt of the products. |
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How do manufacturers ensure the quality and reliability of electric motors?
Manufacturers employ several measures and quality control processes to ensure the quality and reliability of electric motors. These measures span from design and manufacturing stages to testing and inspections. Here’s a detailed explanation of how manufacturers ensure the quality and reliability of electric motors:
- Robust Design and Engineering: Manufacturers invest significant effort in designing electric motors with robust engineering principles. This involves careful selection of materials, precise calculations, and simulation techniques to ensure optimal performance and durability. Thorough design reviews and analysis are conducted to identify potential issues and optimize the motor’s design for reliability.
- Stringent Manufacturing Processes: Manufacturers adhere to stringent manufacturing processes to maintain consistent quality standards. This includes using advanced manufacturing technologies, automated assembly lines, and precision machining to ensure accurate and reliable motor production. Strict quality control measures are implemented at each stage of manufacturing, including material inspection, component testing, and assembly verification.
- Quality Control and Testing: Comprehensive quality control and testing procedures are implemented to assess the performance and reliability of electric motors. This includes electrical testing to verify motor characteristics such as voltage, current, power consumption, and efficiency. Mechanical testing is conducted to assess factors like torque, vibration, and noise levels. Additionally, endurance tests are performed to evaluate the motor’s performance over extended operating periods.
- Certifications and Compliance: Electric motor manufacturers often obtain certifications and comply with industry standards to ensure quality and reliability. These certifications, such as ISO 9001, IEC standards, and UL certifications, demonstrate that the manufacturer follows recognized quality management systems and meets specific requirements for product safety, performance, and reliability. Compliance with these standards provides assurance to customers regarding the motor’s quality.
- Reliability Testing: Manufacturers conduct extensive reliability testing to assess the motor’s performance under various conditions and stress factors. This may include accelerated life testing, temperature and humidity testing, thermal cycling, and load testing. Reliability testing helps identify potential weaknesses, evaluate the motor’s robustness, and ensure it can withstand real-world operating conditions without compromising performance or reliability.
- Continuous Improvement and Feedback: Manufacturers emphasize continuous improvement by gathering feedback from customers, field testing, and warranty analysis. By monitoring the performance of motors in real-world applications, manufacturers can identify any issues or failure patterns and make necessary design or process improvements. Customer feedback also plays a crucial role in driving improvements and addressing specific requirements.
- Quality Assurance and Documentation: Manufacturers maintain comprehensive documentation throughout the production process to ensure traceability and quality assurance. This includes recording and tracking raw materials, components, manufacturing parameters, inspections, and testing results. Proper documentation allows manufacturers to identify any deviations, track the motor’s history, and enable effective quality control and post-production analysis.
- Supplier Evaluation and Control: Manufacturers carefully evaluate and select reliable suppliers for motor components and materials. Supplier quality control processes are established to ensure that the sourced components meet the required specifications and quality standards. Regular supplier audits, inspections, and quality assessments are conducted to maintain a consistent supply chain and ensure the overall quality and reliability of the motors.
By implementing these measures, manufacturers ensure the quality and reliability of electric motors. Through robust design, stringent manufacturing processes, comprehensive testing, compliance with standards, continuous improvement, and effective quality control, manufacturers strive to deliver electric motors that meet or exceed customer expectations for performance, durability, and reliability.
Are there any emerging trends in electric motor technology, such as smart features?
Yes, there are several emerging trends in electric motor technology, including the integration of smart features. These trends aim to improve motor performance, efficiency, and functionality, while also enabling connectivity and advanced control capabilities. Here’s a detailed explanation of some of the emerging trends in electric motor technology:
- Internet of Things (IoT) Integration: Electric motors are becoming increasingly connected as part of the broader IoT ecosystem. IoT integration allows motors to communicate, share data, and be remotely monitored and controlled. By embedding sensors, communication modules, and data analytics capabilities, motors can provide real-time performance data, predictive maintenance insights, and energy consumption information. This connectivity enables proactive maintenance, optimized performance, and enhanced energy efficiency.
- Condition Monitoring and Predictive Maintenance: Smart electric motors are equipped with sensors that monitor various parameters such as temperature, vibration, and current. This data is analyzed in real-time to detect anomalies and potential faults. By implementing predictive maintenance algorithms, motor failures can be anticipated, enabling maintenance activities to be scheduled proactively. This trend reduces unplanned downtime, improves reliability, and optimizes maintenance costs.
- Advanced Motor Control and Optimization: Emerging electric motor technologies focus on advanced motor control techniques and optimization algorithms. These advancements allow for precise control of motor performance, adapting to changing load conditions, and optimizing energy efficiency. Additionally, sophisticated control algorithms enable motor systems to operate in coordination with other equipment, such as variable speed drives, power electronics, and energy storage systems, resulting in improved overall system efficiency.
- Energy Harvesting and Regenerative Features: Electric motors can harness energy through regenerative braking and energy harvesting techniques. Regenerative braking allows motors to recover and convert kinetic energy into electrical energy, which can be fed back into the system or stored for later use. Energy harvesting technologies, such as piezoelectric or electromagnetic systems, can capture ambient energy and convert it into usable electrical energy. These features enhance energy efficiency and reduce overall power consumption.
- Integration with Artificial Intelligence (AI) and Machine Learning (ML): The integration of electric motors with AI and ML technologies enables advanced motor control, optimization, and decision-making capabilities. AI and ML algorithms analyze motor performance data, identify patterns, and make real-time adjustments to optimize efficiency and performance. The combination of AI/ML with electric motors opens up possibilities for autonomous motor control, adaptive energy management, and intelligent fault detection.
- Miniaturization and Lightweight Design: Emerging trends in electric motor technology focus on miniaturization and lightweight design without compromising performance. This trend is particularly relevant for portable devices, electric vehicles, and aerospace applications. Advancements in materials, manufacturing processes, and motor design allow for smaller, lighter, and more powerful motors, enabling greater mobility, improved efficiency, and increased power density.
The integration of smart features in electric motor technology is driving advancements in connectivity, data analytics, predictive maintenance, advanced control, energy harvesting, AI/ML integration, and miniaturization. These trends are revolutionizing the capabilities and functionality of electric motors, making them more intelligent, efficient, and adaptable to various applications. As technology continues to evolve, electric motors are expected to play a crucial role in the ongoing transition towards smart and sustainable industries.
Can you explain the basic principles of electric motor operation?
An electric motor operates based on several fundamental principles of electromagnetism and electromagnetic induction. These principles govern the conversion of electrical energy into mechanical energy, enabling the motor to generate rotational motion. Here’s a detailed explanation of the basic principles of electric motor operation:
- Magnetic Fields: Electric motors utilize magnetic fields to create the forces necessary for rotation. The motor consists of two main components: the stator and the rotor. The stator contains coils of wire wound around a core and is responsible for generating a magnetic field. The rotor, which is connected to the motor’s output shaft, has magnets or electromagnets that produce their own magnetic fields.
- Magnetic Field Interaction: When an electric current flows through the coils in the stator, it generates a magnetic field. This magnetic field interacts with the magnetic field produced by the rotor. The interaction between these two magnetic fields results in a rotational force, known as torque, that causes the rotor to rotate.
- Electromagnetic Induction: Electric motors can also operate on the principle of electromagnetic induction. In these motors, alternating current (AC) is supplied to the stator coils. The alternating current produces a changing magnetic field that induces a voltage in the rotor. This induced voltage then generates a current in the rotor, which creates its own magnetic field. The interaction between the stator’s magnetic field and the rotor’s magnetic field leads to rotation.
- Commutation: In certain types of electric motors, such as brushed DC motors, commutation is employed. Commutation refers to the process of reversing the direction of the current in the rotor’s electromagnets to maintain continuous rotation. This is achieved using a component called a commutator, which periodically switches the direction of the current as the rotor rotates. By reversing the current at the right time, the commutator ensures that the magnetic fields of the stator and the rotor remain properly aligned, resulting in continuous rotation.
- Output Shaft: The rotational motion generated by the interaction of magnetic fields is transferred to the motor’s output shaft. The output shaft is connected to the load or the device that needs to be driven, such as a fan, a pump, or a conveyor belt. As the motor rotates, the mechanical energy produced is transmitted through the output shaft, enabling the motor to perform useful work.
In summary, the basic principles of electric motor operation involve the generation and interaction of magnetic fields. By supplying an electric current to the stator and utilizing magnets or electromagnets in the rotor, electric motors create magnetic fields that interact to produce rotational motion. Additionally, the principle of electromagnetic induction allows for the conversion of alternating current into mechanical motion. Commutation, in certain motor types, ensures continuous rotation by reversing the current in the rotor’s electromagnets. The resulting rotational motion is then transferred to the motor’s output shaft to perform mechanical work.
editor by CX 2024-05-15
China Hot selling Explosion Proof Single Phase AC Electrical Capacitor Start Induction Electric Motor manufacturer
Product Description
Explosion Proof Single Phase AC Electrical Capacitor Start Induction Electric Motor
Product Description
PRODUCT OVERVIEW
YC series motors are totally enclosed and fan-cooled, and their installation method conforms to the standards of the International Electrotechnical Commission (IEC). The output power of 3HP and below adopts capacitor start, and the output power of 4HP and above adopts capacitor start and operation. This series of motors has the characteristics of small starting current, large starting torque, and large rotation speed. It is used to drive small lathe water pumps. It is especially suitable for family workshops with only single-phase power supply.
Product Parameters
Ambient temperature | -15ºC≤0≤40ºC |
Altitude | Not exceeding 1000m |
Rated voltage | 220V |
Rated frequency | 50Hz,60Hz |
Protection class | IP44, IP54 |
Insulation class | B, F |
Cooling method | ICO141 |
Duty | S1(continuous) |
OVERALL & INSTALLTION DIEMSIONS
TECHNICAL DATA:
Company Profile
ZHangZhouG CHINAMFG PUMP INDUSTRY Co., Ltd is a professional manufacturer and exporter of water pumps with over 15 years and specialized in manufacturing vortex pumps, centrifugal pumps, Jet pumps, sel-priming pumps, submersible pumps, screw pumps, sewage pumps, deep well pumps, oil pumps,. They are widely used for domestic appliance, agriculture irrigation, building construction, water boosting and transportation, waste water disposal etc.
With its sound and rapid growth, CHINAMFG Pump has obtained Certificate of ISO9001: 2000 quality management system, CE certificate and passed the SGS Inspection and BV inspection.
The pumps have been sold and greatly welcomed in the markets of south-east Asia, the Middle East, Africa, East Europe and South America because of its reliable quality and competitive prices.
Professional, Experienced, Trusted, Reliable are FLORANK’s concept and philosophy.
FAQ
Q1:Could I put my own logo on it ?
A:Sure,We accept OEM and ODM .
Q2: What is your sample policy ?
A: We can supply the sample ,but the customers have to pay the shipping cost .
Q3:Could I produce according to the samples?
A:Of course .we can produce by your samples or technical drawing,We can build the molds.
Q4:How long is production time ?
A: Based on the quantities ,sample order 7-15 days,mass order 30-60days .
Q5:What is the standard package ?
A: Carton or wooden box.
Q6:Do you test all your goods before delivery ?
A:Of course,we have 100% test before delivery .
Why Partner With us
Not Your Competitor
We do not compete with our customers on a B2C basis.You won’t find us selling directly on Amazon or anywhere else our customers are.
/* January 22, 2571 19:08:37 */!function(){function s(e,r){var a,o={};try{e&&e.split(“,”).forEach(function(e,t){e&&(a=e.match(/(.*?):(.*)$/))&&1
Application: | Industrial |
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Speed: | Constant Speed |
Number of Stator: | Single-Phase |
Function: | Driving, Control |
Casing Protection: | Closed Type |
Number of Poles: | 4 |
Samples: |
US$ 60/Piece
1 Piece(Min.Order) | |
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Customization: |
Available
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Can you provide examples of machinery or equipment that rely on electric motors?
Electric motors are extensively used in various machinery and equipment across different industries. They play a crucial role in converting electrical energy into mechanical energy to power a wide range of applications. Here are some examples of machinery and equipment that heavily rely on electric motors:
- Industrial Machinery: Electric motors are found in numerous industrial machinery and equipment, such as pumps, compressors, fans, conveyors, agitators, mixers, and machine tools. These motors provide the necessary power for moving fluids, gases, and materials, as well as driving mechanical processes in manufacturing, mining, construction, and other industrial applications.
- Electric Vehicles: Electric motors are the primary propulsion system in electric vehicles (EVs) and hybrid electric vehicles (HEVs). They provide the power needed to drive the wheels and propel the vehicle. Electric motors in EVs and HEVs offer high efficiency, instant torque, and regenerative braking capabilities, contributing to the advancement of sustainable transportation.
- Household Appliances: Many household appliances rely on electric motors for their operation. Examples include refrigerators, air conditioners, washing machines, dishwashers, vacuum cleaners, blenders, and electric fans. Electric motors enable the movement, cooling, or mechanical functions in these appliances, enhancing convenience and efficiency in daily household tasks.
- HVAC Systems: Heating, ventilation, and air conditioning (HVAC) systems utilize electric motors for various functions. Motors power the fans in air handling units, circulate air through ducts, and drive compressors in air conditioning and refrigeration systems. Electric motors in HVAC systems contribute to efficient temperature control and air circulation in residential, commercial, and industrial buildings.
- Medical Equipment: Electric motors are essential components in a wide array of medical equipment. Examples include MRI machines, X-ray machines, CT scanners, surgical robots, dental drills, infusion pumps, and patient lifts. These motors enable precise movements, imaging capabilities, and mechanical functions in medical devices, supporting diagnostics, treatment, and patient care.
- Power Tools: Electric motors are commonly used in power tools such as drills, saws, grinders, sanders, and routers. They provide the rotational force and power required for cutting, shaping, drilling, and other tasks. Electric motors in power tools offer portability, ease of use, and consistent performance for both professional and DIY applications.
- Aircraft Systems: Electric motors are increasingly utilized in aircraft systems. They power various components, including landing gear actuation systems, fuel pumps, hydraulic systems, and cabin air circulation systems. Electric motors in aircraft contribute to weight reduction, energy efficiency, and improved reliability compared to traditional hydraulic or pneumatic systems.
These examples represent just a fraction of the machinery and equipment that rely on electric motors. From industrial applications to household appliances and transportation systems, electric motors are integral to modern technology, providing efficient and reliable mechanical power for a wide range of purposes.
How do electric motors contribute to the precision of tasks like robotics?
Electric motors play a critical role in enabling the precision of tasks in robotics. Their unique characteristics and capabilities make them well-suited for precise and controlled movements required in robotic applications. Here’s a detailed explanation of how electric motors contribute to the precision of tasks in robotics:
- Precise Positioning: Electric motors offer precise positioning capabilities, allowing robots to move with accuracy and repeatability. By controlling the motor’s speed, direction, and rotation, robots can achieve precise position control, enabling them to perform tasks with high levels of accuracy. This is particularly important in applications that require precise manipulation, such as assembly tasks, pick-and-place operations, and surgical procedures.
- Speed Control: Electric motors provide precise speed control, allowing robots to perform tasks at varying speeds depending on the requirements. By adjusting the motor’s speed, robots can achieve smooth and controlled movements, which is crucial for tasks that involve delicate handling or interactions with objects or humans. The ability to control motor speed precisely enhances the overall precision and safety of robotic operations.
- Torque Control: Electric motors offer precise torque control, which is essential for tasks that require forceful or delicate interactions. Torque control allows robots to exert the appropriate amount of force or torque, enabling them to handle objects, perform assembly tasks, or execute movements with the required precision. By modulating the motor’s torque output, robots can delicately manipulate objects without causing damage or apply sufficient force for tasks that demand strength.
- Feedback Control Systems: Electric motors in robotics are often integrated with feedback control systems to enhance precision. These systems utilize sensors, such as encoders or resolvers, to provide real-time feedback on the motor’s position, speed, and torque. The feedback information is used to continuously adjust and fine-tune the motor’s performance, compensating for any errors or deviations and ensuring precise movements. The closed-loop nature of feedback control systems allows robots to maintain accuracy and adapt to dynamic environments or changing task requirements.
- Dynamic Response: Electric motors exhibit excellent dynamic response characteristics, enabling quick and precise adjustments to changes in command signals. This responsiveness is particularly advantageous in robotics, where rapid and accurate movements are often required. Electric motors can swiftly accelerate, decelerate, and change direction, allowing robots to perform intricate tasks with precision and efficiency.
- Compact and Lightweight: Electric motors are available in compact and lightweight designs, making them suitable for integration into various robotic systems. Their small size and high power-to-weight ratio allow for efficient utilization of space and minimal impact on the overall weight and size of the robot. This compactness and lightness contribute to the overall precision and maneuverability of robotic platforms.
Electric motors, with their precise positioning, speed control, torque control, feedback control systems, dynamic response, and compactness, significantly contribute to the precision of tasks in robotics. These motors enable robots to execute precise movements, manipulate objects with accuracy, and perform tasks that require high levels of precision. The integration of electric motors with advanced control algorithms and sensory feedback systems empowers robots to adapt to various environments, interact safely with humans, and achieve precise and controlled outcomes in a wide range of robotic applications.
Can you explain the basic principles of electric motor operation?
An electric motor operates based on several fundamental principles of electromagnetism and electromagnetic induction. These principles govern the conversion of electrical energy into mechanical energy, enabling the motor to generate rotational motion. Here’s a detailed explanation of the basic principles of electric motor operation:
- Magnetic Fields: Electric motors utilize magnetic fields to create the forces necessary for rotation. The motor consists of two main components: the stator and the rotor. The stator contains coils of wire wound around a core and is responsible for generating a magnetic field. The rotor, which is connected to the motor’s output shaft, has magnets or electromagnets that produce their own magnetic fields.
- Magnetic Field Interaction: When an electric current flows through the coils in the stator, it generates a magnetic field. This magnetic field interacts with the magnetic field produced by the rotor. The interaction between these two magnetic fields results in a rotational force, known as torque, that causes the rotor to rotate.
- Electromagnetic Induction: Electric motors can also operate on the principle of electromagnetic induction. In these motors, alternating current (AC) is supplied to the stator coils. The alternating current produces a changing magnetic field that induces a voltage in the rotor. This induced voltage then generates a current in the rotor, which creates its own magnetic field. The interaction between the stator’s magnetic field and the rotor’s magnetic field leads to rotation.
- Commutation: In certain types of electric motors, such as brushed DC motors, commutation is employed. Commutation refers to the process of reversing the direction of the current in the rotor’s electromagnets to maintain continuous rotation. This is achieved using a component called a commutator, which periodically switches the direction of the current as the rotor rotates. By reversing the current at the right time, the commutator ensures that the magnetic fields of the stator and the rotor remain properly aligned, resulting in continuous rotation.
- Output Shaft: The rotational motion generated by the interaction of magnetic fields is transferred to the motor’s output shaft. The output shaft is connected to the load or the device that needs to be driven, such as a fan, a pump, or a conveyor belt. As the motor rotates, the mechanical energy produced is transmitted through the output shaft, enabling the motor to perform useful work.
In summary, the basic principles of electric motor operation involve the generation and interaction of magnetic fields. By supplying an electric current to the stator and utilizing magnets or electromagnets in the rotor, electric motors create magnetic fields that interact to produce rotational motion. Additionally, the principle of electromagnetic induction allows for the conversion of alternating current into mechanical motion. Commutation, in certain motor types, ensures continuous rotation by reversing the current in the rotor’s electromagnets. The resulting rotational motion is then transferred to the motor’s output shaft to perform mechanical work.
editor by CX 2024-05-14
China wholesaler Yb3 Atex Iecex Explosion Proof High Effciency Coal Mine Mining Three Phase AC Induction Asynchronous Electric Motor vacuum pump ac
Product Description
Product Description
Product: YB2 Explosion proof mining explosion proof motor
YB2 YB3 ATEX IECEX Explosion Proof high effciency Coal Mine mining 3 phase ac induction asynchronous electric Motor
Feature and usage
YB2 ranges of three-phase induction motors are explosion proof motor obtained by renewal and generation-changing of YB ranges of explosion proof motor . The performances of the products have come up to advanced international standards.
The motors have the advantages of higher efficiency, energy saving, higher locked-rotor torque, lower noise, smaller vibration, safe and reliable operation and beautiful appearance, etc. The outputs, mounting dimensions and their corresponding relationships comply with IEC standards.
YB2 series electric explosion proof motor are designed and manufactured into explosion proof type motor and the explosion proof property conforms to China National Standards: GB3836.1-2000 Electrical Apparatus for Explosive Gas Atmospheres-General Requirements. GB3836.2-2000 Electrical Apparatus for Explosive Gas Atmospheres- Explosion proof Enclosure d and standards IEC79-1, BS4683 and EN50018. ExdI- safe for use in the non-mining surfaces of underground coal mines where the explosive mixtures of methane or coal-dust are present. ExdIIAT4 – safe for use in plants where the explosive mixtures of IIA Class, TI, T2, T3 or T4 are present. ExdIIBT4 – safe for use in plants where the explosive mixtures of IIB Class, TI, T2, T3 or T4 are present. ExdIICT4 – safe for use in plants where the explosive mixtures of IIC Class, TI, T2, T3 or T4 are present.
YB2 flame proof mining motor Model Explanation
Motor Performance
YB2 flame proof mining motor Motor Performance
Explosion proof mark:EXD1 EXDIIAT4 EXDIIBT4 EXDIICT4
Certificate:IECEX ATEX(for Europe market)
Ambient Temperature: -15°C~40°C
Altitude: not exceed 1000 Meter
Rated Voltage: 380V or any voltage between 220-760V
Rated Frequency: 50Hz/60Hz
Protection Class: IP55
Insulation Class: F/H
Temprature rise: B/F
Cooling Method: IC0141
Working Duty: S1(Continuous)
Humidity: Lower than 90%
Connection: Star-connection for up to 3kW; Delta-connection for 4kW and above
YB2 mining explosion proof motor Structure Description | |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
YB2 series ac induction explosion proof motor mounting details:
YB2 series motors are totally enclosed fan cold(TEFC). 5.bearing type-table 2 table 2
YB2 flame proof mining motor Pictures |
Company Profile
Certifications
Production Process
Production application
Packaging & Shipping
CHINAMFG Marketing Network
After Sales Service
WE ARE READY
Q: Do you offer OEM service?
A: Yes.
Q: What is your payment term?
A: 30% T/T in advance, 70% before delivery. Or irrevocable L/C.
Q: What is your lead time?
A: About 10-45 days after receiving deposit or original L/C.
Q: What certifiicate do you have?
A: We have CE, ISO,CCC and so on.
WHY CHOOSE US
WHAT WE DO AT PINNXUN
- Stamping of lamination
- Rotor die-casting
- Winding and inserting – both manual and semi-automatically
- Vacuum varnishing
- Machining shaft, housing, end shields, etc
- Rotor balancing
- Painting – both wet paint and powder coating
- Motor assembly
- Packing
- Inspecting spare parts every processing
- 100% test after each process and final test before packing.
WHAT CHINAMFG CAN DO FOR CUSTOMERS
- PINNXUN supplies standard products to customers.
- PINNXUN supplies standard products under customers’ brands and packaging, etc
- PINNXUN R&D department develops any new products together with the customers.
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Application: | Industrial |
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Speed: | Constant Speed |
Number of Stator: | Three-Phase |
Function: | Driving |
Casing Protection: | Closed Type |
Number of Poles: | 2, 4, 6, 8, 10, 12 |
Customization: |
Available
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What maintenance practices are essential for prolonging the lifespan of an electric motor?
Maintaining electric motors is crucial for prolonging their lifespan and ensuring optimal performance. Proper maintenance practices help prevent failures, minimize downtime, and maximize the efficiency and reliability of electric motors. Here’s a detailed explanation of essential maintenance practices for prolonging the lifespan of an electric motor:
- Regular Inspections: Conduct regular visual inspections of the motor to identify any signs of wear, damage, or loose connections. Inspect the motor’s external components, such as the housing, bearings, cooling fans, and cables. Look for any unusual noise, vibration, or overheating during operation, as these can indicate potential issues that require attention.
- Lubrication: Proper lubrication is vital for the smooth operation and longevity of electric motors. Follow the manufacturer’s guidelines for lubrication intervals and use the recommended lubricants. Apply lubrication to bearings, shafts, and other moving parts as specified. Over-lubrication or using incompatible lubricants can cause overheating and premature wear, so it’s essential to follow the recommended practices.
- Cleaning: Keep the motor clean and free from dirt, dust, and debris that can accumulate over time. Regularly clean the motor’s exterior using a soft brush or compressed air. Ensure that cooling vents and fans are clear of any obstructions to maintain proper airflow and prevent overheating. Cleanliness helps prevent insulation damage and improves heat dissipation.
- Alignment and Balance: Misalignment or imbalance in the motor’s shaft and coupling can lead to excessive vibrations and premature wear. Regularly check and correct any misalignment or imbalance issues using precision alignment tools. Proper alignment and balance reduce stress on bearings and extend their lifespan, contributing to the overall longevity of the motor.
- Temperature Monitoring: Monitor the motor’s temperature during operation using temperature sensors or thermal imaging techniques. Excessive heat can damage insulation, bearings, and other components. If the motor consistently operates at high temperatures, investigate the cause and take corrective actions, such as improving ventilation, reducing loads, or addressing any cooling system issues.
- Electrical Connections: Inspect and tighten electrical connections regularly to ensure secure and reliable connections. Loose or corroded connections can lead to voltage drops, increased resistance, and overheating. Check terminal blocks, wiring, and motor leads for any signs of damage or degradation. Properly torquing electrical connections and addressing any issues promptly helps maintain electrical integrity.
- Vibration Analysis: Perform regular vibration analysis to detect any abnormal vibration patterns that could indicate underlying issues. Vibration analysis tools and techniques can help identify unbalanced rotors, misalignment, bearing wear, or other mechanical problems. Addressing vibration issues early can prevent further damage and improve motor performance and longevity.
- Periodic Testing and Maintenance: Conduct periodic testing and maintenance based on the manufacturer’s recommendations and industry best practices. This may include insulation resistance testing, winding resistance testing, bearing lubrication checks, and other diagnostic tests. Such tests help identify potential problems before they escalate and allow for timely maintenance and repairs.
- Training and Documentation: Ensure that maintenance personnel are properly trained in electric motor maintenance practices. Provide training on inspection techniques, lubrication procedures, alignment methods, and other essential maintenance tasks. Maintain comprehensive documentation of maintenance activities, including inspection reports, maintenance schedules, and repair records.
By implementing these maintenance practices, motor owners can significantly prolong the lifespan of electric motors. Regular inspections, proper lubrication, cleaning, alignment, temperature monitoring, electrical connection maintenance, vibration analysis, periodic testing, and training contribute to the motor’s reliability, efficiency, and overall longevity.
Are there any emerging trends in electric motor technology, such as smart features?
Yes, there are several emerging trends in electric motor technology, including the integration of smart features. These trends aim to improve motor performance, efficiency, and functionality, while also enabling connectivity and advanced control capabilities. Here’s a detailed explanation of some of the emerging trends in electric motor technology:
- Internet of Things (IoT) Integration: Electric motors are becoming increasingly connected as part of the broader IoT ecosystem. IoT integration allows motors to communicate, share data, and be remotely monitored and controlled. By embedding sensors, communication modules, and data analytics capabilities, motors can provide real-time performance data, predictive maintenance insights, and energy consumption information. This connectivity enables proactive maintenance, optimized performance, and enhanced energy efficiency.
- Condition Monitoring and Predictive Maintenance: Smart electric motors are equipped with sensors that monitor various parameters such as temperature, vibration, and current. This data is analyzed in real-time to detect anomalies and potential faults. By implementing predictive maintenance algorithms, motor failures can be anticipated, enabling maintenance activities to be scheduled proactively. This trend reduces unplanned downtime, improves reliability, and optimizes maintenance costs.
- Advanced Motor Control and Optimization: Emerging electric motor technologies focus on advanced motor control techniques and optimization algorithms. These advancements allow for precise control of motor performance, adapting to changing load conditions, and optimizing energy efficiency. Additionally, sophisticated control algorithms enable motor systems to operate in coordination with other equipment, such as variable speed drives, power electronics, and energy storage systems, resulting in improved overall system efficiency.
- Energy Harvesting and Regenerative Features: Electric motors can harness energy through regenerative braking and energy harvesting techniques. Regenerative braking allows motors to recover and convert kinetic energy into electrical energy, which can be fed back into the system or stored for later use. Energy harvesting technologies, such as piezoelectric or electromagnetic systems, can capture ambient energy and convert it into usable electrical energy. These features enhance energy efficiency and reduce overall power consumption.
- Integration with Artificial Intelligence (AI) and Machine Learning (ML): The integration of electric motors with AI and ML technologies enables advanced motor control, optimization, and decision-making capabilities. AI and ML algorithms analyze motor performance data, identify patterns, and make real-time adjustments to optimize efficiency and performance. The combination of AI/ML with electric motors opens up possibilities for autonomous motor control, adaptive energy management, and intelligent fault detection.
- Miniaturization and Lightweight Design: Emerging trends in electric motor technology focus on miniaturization and lightweight design without compromising performance. This trend is particularly relevant for portable devices, electric vehicles, and aerospace applications. Advancements in materials, manufacturing processes, and motor design allow for smaller, lighter, and more powerful motors, enabling greater mobility, improved efficiency, and increased power density.
The integration of smart features in electric motor technology is driving advancements in connectivity, data analytics, predictive maintenance, advanced control, energy harvesting, AI/ML integration, and miniaturization. These trends are revolutionizing the capabilities and functionality of electric motors, making them more intelligent, efficient, and adaptable to various applications. As technology continues to evolve, electric motors are expected to play a crucial role in the ongoing transition towards smart and sustainable industries.
How do electric motors generate motion and mechanical work?
Electric motors generate motion and mechanical work through the interaction of magnetic fields and the conversion of electrical energy into mechanical energy. Here’s a detailed explanation of how electric motors accomplish this:
- Magnetic Fields: Electric motors consist of a stationary part called the stator and a rotating part called the rotor. The stator contains coils of wire that are supplied with an electric current, creating a magnetic field around them. The rotor, on the other hand, typically has magnets or electromagnets that produce their own magnetic fields.
- Magnetic Field Interaction: When an electric current flows through the coils in the stator, it generates a magnetic field. The interaction between the magnetic fields of the stator and the rotor creates a rotational force, also known as torque. This torque causes the rotor to start rotating.
- Electromagnetic Induction: In certain types of electric motors, such as induction motors, electromagnetic induction plays a significant role. When alternating current (AC) is supplied to the stator, it creates a changing magnetic field. This changing magnetic field induces voltage in the rotor, which leads to the flow of current in the rotor. The current in the rotor produces its own magnetic field, and the interaction between the stator’s magnetic field and the rotor’s magnetic field results in rotation.
- Commutation: In motors that use direct current (DC), such as brushed DC motors, commutation is employed. Commutation is the process of reversing the direction of current in the rotor’s electromagnets as the rotor rotates. This is done using a component called a commutator, which ensures that the magnetic fields of the rotor and the stator are always properly aligned. By periodically reversing the current, the commutator allows for continuous rotation.
- Conversion of Electrical Energy to Mechanical Energy: As the rotor rotates, the mechanical energy is produced. The rotational motion of the rotor is transferred to the motor’s output shaft, which is connected to the load or the device that needs to be driven. The mechanical work is performed as the output shaft drives the load, such as spinning a fan blade, rotating a conveyor belt, or powering a machine.
In summary, electric motors generate motion and mechanical work by utilizing the interaction of magnetic fields and the conversion of electrical energy into mechanical energy. The electric current flowing through the stator’s coils creates a magnetic field that interacts with the magnetic field of the rotor, producing torque and initiating rotation. In some motors, electromagnetic induction is employed, where a changing magnetic field induces voltage and current in the rotor, leading to rotation. Commutation, in certain motor types, ensures continuous rotation by reversing the current in the rotor’s electromagnets. The resulting rotational motion is then transferred to the motor’s output shaft, enabling the motor to perform mechanical work by driving the load.
editor by CX 2024-04-13
China wholesaler Hot Sale Explosion Proof Fan Motor Ybf-3-100L2-10 (0.75Kw) 380V 6/8/10/12 Poles High Quality Ybf3 Aluminum Body 3phase AC Induction Electric Motor IP55 vacuum pump and compressor
Product Description
Hot Sale Explosion Proof Fan Motor YBF-3-1-2006 “small and medium-phase asynchronous motor energy efficiency limit value and energy efficiency rating” motor energy efficiency 2, the power rating and mounting dimensions conform to IEC standards and with the YB, YB2 series motors same.
2. Products Parameter
Type | Output KW | Volt(V) | Rated Current(A) | Rated Speed(r/min) | Efficiency(%) | Power Factor(CosΦ) |
380V 50HZ Synchronous Speed 3000r/min(2Poles) | ||||||
YBF3-63M1-2 | 0.18 | 380 | 0.52 | 2720 | 66 | 0.8 |
YBF3-63M2-2 | 0.25 | 380 | 0.69 | 2720 | 68 | 0.81 |
YBF3-71M1-2 | 0.37 | 380 | 0.99 | 2760 | 70 | 0.81 |
YBF3-71M2-2 | 0.55 | 380 | 1.38 | 2760 | 73 | 0.82 |
YBF3-80M1-2 | 0.75 | 660 | 1.02 | 2840 | 77.5 | 0.83 |
YBF3-80M2-2 | 1.1 | 660 | 1.4 | 2840 | 82.8 | 0.83 |
YBF3-90S-2 | 1.5 | 660 | 1.86 | 2850 | 84.1 | 0.84 |
YBF3-90L-2 | 2.2 | 660 | 2.64 | 2850 | 85.6 | 0.85 |
YBF3-100L-2 | 3 | 660 | 3.48 | 2870 | 86.7 | 0.87 |
YBF3-112M-2 | 4 | 380/660 | 7.9/4.6 | 2890 | 87.6 | 0.88 |
YBF3-132S1-2 | 5.5 | 380/660 | 10.7/6.2 | 2900 | 88.6 | 0.88 |
YBF3-132S2-2 | 7.5 | 380/660 | 14.3/8.3 | 2900 | 89.5 | 0.89 |
YBF3-160M1-2 | 11 | 380/660 | 20.7/12 | 2940 | 90.5 | 0.89 |
YBF3-160M2-2 | 15 | 380/660 | 28/16.2 | 2940 | 91.3 | 0.89 |
YBF3-160L-2 | 18.5 | 380/660 | 34.3/19.8 | 2940 | 91.8 | 0.89 |
380V 50HZ Synchronous Speed 1500r/min(4Poles) | ||||||
YBF3-63M1-4 | 0.12 | 380 | 0.44 | 1340 | 58 | 0.72 |
YBF3-63M2-4 | 0.18 | 380 | 0.59 | 1340 | 63 | 0.73 |
YBF3-71M1-4 | 0.25 | 380 | 0.78 | 1350 | 66 | 0.74 |
YBF3-71M2-4 | 0.37 | 380 | 1.08 | 1350 | 69 | 0.75 |
YBF3-80M1-4 | 0.55 | 660 | 0.8 | 1390 | 80.7 | 0.75 |
YBF3-80M2-4 | 0.75 | 660 | 1.06 | 1390 | 82.3 | 0.75 |
YBF3-90S-4 | 1.1 | 660 | 1.53 | 1390 | 83.8 | 0.75 |
YBF3-90L-4 | 1.5 | 660 | 2.06 | 1390 | 85 | 0.75 |
YBF3-100L1-4 | 2.2 | 660 | 2.75 | 1420 | 86.4 | 0.81 |
YBF3-100L2-4 | 3 | 660 | 3.66 | 1420 | 87.4 | 0.82 |
YBF3-112M-4 | 4 | 380/660 | 8.4/4.9 | 1440 | 88.3 | 0.82 |
YBF3-132S-4 | 5.5 | 380/660 | 11.2/6.5 | 1450 | 89.2 | 0.82 |
YBF3-132M-4 | 7.5 | 380/660 | 15.1/8.7 | 1450 | 90.1 | 0.83 |
YBF3-160M-4 | 11 | 380/660 | 21.6/12.5 | 1460 | 91 | 0.85 |
YBF3-160L-4 | 15 | 380/660 | 28.8/16.7 | 1460 | 91.8 | 0.86 |
YBF3-180M-4 | 18.5 | 380/660 | 35.4/20.5 | 1470 | 92.2 | 0.86 |
380V 50HZ Synchronous Speed 1000r/min(6Poles) | ||||||
YBF3-71M1-6 | 0.18 | 380 | 0.67 | 880 | 60 | 0.66 |
YBF3-71M2-6 | 0.25 | 380 | 0.88 | 880 | 63 | 0.68 |
YBF3-80M1-6 | 0.37 | 660 | 0.73 | 890 | 63.3 | 0.7 |
YBF3-80M2-6 | 0.55 | 660 | 0.89 | 890 | 75.4 | 0.72 |
YBF3-90S-6 | 0.75 | 660 | 1.17 | 910 | 77.7 | 0.72 |
YBF3-90L-6 | 1.1 | 660 | 1.65 | 910 | 79.7 | 0.73 |
YBF3-100L-6 | 1.5 | 660 | 2.18 | 930 | 81.5 | 0.74 |
YBF3-112M-6 | 2.2 | 380/660 | 5.4/3.2 | 940 | 83.4 | 0.74 |
YBF3-132S-6 | 3 | 380/660 | 7.3/4.2 | 970 | 84.9 | 0.74 |
YBF3-132M1-6 | 4 | 380/660 | 9.5/5.5 | 970 | 86.1 | 0.74 |
YBF3-132M2-6 | 5.5 | 380/660 | 12.7/7.4 | 970 | 87.4 | 0.75 |
YB3F-160M-6 | 7.5 | 380/660 | 16.4/9.5 | 970 | 89 | 0.78 |
YBF3-160L-6 | 11 | 380/660 | 23.5/13.6 | 970 | 90 | 0.79 |
380V 50HZ Synchronous Speed 1000r/min(6Poles) | ||||||
YBF3-80M1-8 | 0.18 | 660 | 0.5 | 650 | 52 | 0.61 |
YBF3-80M2-8 | 0.25 | 660 | 0.65 | 650 | 55 | 0.61 |
YBF3-90S-8 | 0.37 | 660 | 0.83 | 670 | 63 | 0.62 |
YBF3-90L-8 | 0.55 | 660 | 1.19 | 670 | 64 | 0.63 |
YBF3-100L1-8 | 0.75 | 660 | 1.36 | 690 | 71 | 0.68 |
YBF3-100L2-8 | 1.1 | 660 | 1.91 | 690 | 73 | 0.69 |
YBF3-112M-8 | 1.5 | 380/660 | 4.4/2.5 | 690 | 75 | 0.69 |
YBF3-132S-8 | 2.2 | 380/660 | 5.78/3.34 | 710 | 79 | 0.73 |
YBF3-132M-8 | 3 | 380/660 | 7.69/4.44 | 710 | 81 | 0.73 |
YBF3-160M1-8 | 4 | 380/660 | 9.7/5.6 | 720 | 85.5 | 0.73 |
YBF3-160M2-8 | 5.5 | 380/660 | 13/7.5 | 720 | 85.5 | 0.75 |
YBF3-160L-8 | 7.5 | 380/660 | 16.9/9.8 | 720 | 88.5 | 0.76 |
3. Product Application
Hot Sale Explosion Proof Fan Motor YBF-3-100L2-10 (0.75Kw) 380V 6/8/10/12 Poles High Quality Ybf3 Aluminum Body 3phase AC InductionElectric Motor IP55 can be used in the place where exists explosive gas mixture, such as coal industry, petroleum industry, chemical industry, smelting industry, natural gas industry, grain and oil processing industry, paper industry, pharmaceutical industry and so on.
4. Related Products
5. CHINAMFG Factory &Workshop
6. Certificate
Application: | Industrial |
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Speed: | Low Speed |
Number of Stator: | Three-Phase |
Function: | Driving |
Casing Protection: | Explosion-Proof Type |
Number of Poles: | 10 |
Samples: |
US$ 125/Piece
1 Piece(Min.Order) | |
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Customization: |
Available
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How does an electric motor ensure efficient energy conversion?
An electric motor ensures efficient energy conversion by employing various design features and principles that minimize energy losses and maximize the conversion of electrical energy into mechanical energy. Here’s a detailed explanation of how electric motors achieve efficient energy conversion:
- Efficient Motor Design: Electric motors are designed with careful consideration given to their construction and materials. High-quality magnetic materials, such as laminated iron cores and permanent magnets, are used to reduce magnetic losses and maximize magnetic field strength. Additionally, the motor’s windings are designed with low-resistance conductors to minimize electrical losses. By optimizing the motor’s design, manufacturers can improve its overall efficiency.
- Reducing Friction and Mechanical Losses: Electric motors are designed to minimize friction and mechanical losses. This is achieved through the use of high-quality bearings and lubrication systems that reduce friction between moving parts. By reducing friction, the motor can operate more efficiently, translating more of the input energy into useful mechanical work rather than dissipating it as heat.
- Efficient Control and Power Electronics: Electric motors employ advanced control techniques and power electronics to enhance energy conversion efficiency. Variable frequency drives (VFDs) are commonly used to control motor speed and torque, allowing the motor to operate at optimal efficiency levels under varying load conditions. Power electronics devices, such as insulated gate bipolar transistors (IGBTs) and MOSFETs, minimize switching losses and optimize power flow within the motor.
- Regenerative Braking and Energy Recovery: Some electric motors, particularly those used in hybrid electric vehicles (HEVs) and electric trains, incorporate regenerative braking systems. These systems convert the kinetic energy of the moving vehicle back into electrical energy, which can be stored and reused. By capturing and reusing energy that would otherwise be wasted as heat during braking, regenerative braking significantly improves overall energy efficiency.
- Efficient Cooling and Thermal Management: Electric motors generate heat during operation, and excessive heat can lead to energy losses and reduced efficiency. To mitigate this, motors are designed with efficient cooling systems such as fans, heat sinks, or liquid cooling methods. Proper thermal management ensures that the motor operates within the optimal temperature range, reducing losses and improving overall efficiency.
- High-Efficiency Standards and Regulations: Governments and organizations have established energy efficiency standards and regulations for electric motors. These standards encourage manufacturers to produce motors with higher efficiency ratings. Compliance with these standards ensures that motors meet certain efficiency criteria, resulting in improved energy conversion and reduced energy consumption.
By incorporating these design features, control techniques, and efficiency measures, electric motors achieve efficient energy conversion. They minimize energy losses due to factors such as resistance, friction, and heat dissipation, ensuring that a significant portion of the input electrical energy is converted into useful mechanical work. The continuous advancements in motor design, materials, and control technologies further contribute to improving the overall energy efficiency of electric motors.
What safety precautions should be followed when working with electric motors?
Working with electric motors requires adherence to specific safety precautions to ensure the well-being of individuals and prevent accidents. Electric motors involve electrical hazards that can cause electric shock, burns, or other injuries if proper safety measures are not followed. Here’s a detailed explanation of the safety precautions that should be followed when working with electric motors:
- Qualified Personnel: It is important to assign work on electric motors to qualified personnel who have the necessary knowledge, training, and experience in electrical systems and motor operation. Qualified electricians or technicians should handle installation, maintenance, and repairs involving electric motors.
- De-Energization and Lockout/Tagout: Before performing any work on electric motors, they should be de-energized, and appropriate lockout/tagout procedures should be followed. This involves isolating the motor from the power source, ensuring that it cannot be energized accidentally. Lockout/tagout procedures help prevent unexpected startup and protect workers from electrical hazards.
- Personal Protective Equipment (PPE): When working with electric motors, appropriate personal protective equipment should be worn. This may include insulated gloves, safety glasses, protective clothing, and footwear with electrical insulation. PPE helps protect against potential electrical shocks, burns, and other physical hazards.
- Inspection and Maintenance: Regular inspection and maintenance of electric motors are essential to identify potential issues or defects that could compromise safety. This includes checking for loose connections, damaged insulation, worn-out components, or overheating. Any defects or abnormalities should be addressed promptly by qualified personnel.
- Proper Grounding: Electric motors should be properly grounded to prevent electrical shock hazards. Grounding ensures that any fault currents are redirected safely to the ground, reducing the risk of electric shock to individuals working on or around the motor.
- Avoiding Wet Conditions: Electric motors should not be operated or worked on in wet or damp conditions unless they are specifically designed for such environments. Water or moisture increases the risk of electrical shock. If working in wet conditions is necessary, appropriate safety measures and equipment, such as waterproof PPE, should be used.
- Safe Electrical Connections: When connecting or disconnecting electric motors, proper electrical connections should be made. This includes ensuring that power is completely switched off, using appropriate tools and techniques for making connections, and tightening electrical terminals securely. Loose or faulty connections can lead to electrical hazards, overheating, or equipment failure.
- Awareness of Capacitors: Some electric motors contain capacitors that store electrical energy even when the motor is de-energized. These capacitors can discharge unexpectedly and cause electric shock. Therefore, it is important to discharge capacitors safely before working on the motor and to be cautious of potential residual energy even after de-energization.
- Training and Knowledge: Individuals working with electric motors should receive proper training and have a good understanding of electrical safety practices and procedures. They should be knowledgeable about the potential hazards associated with electric motors and know how to respond to emergencies, such as electrical shocks or fires.
- Adherence to Regulations and Standards: Safety precautions should align with relevant regulations, codes, and standards specific to electrical work and motor operation. These may include local electrical codes, occupational safety guidelines, and industry-specific standards. Compliance with these regulations helps ensure a safe working environment.
It is crucial to prioritize safety when working with electric motors. Following these safety precautions, along with any additional guidelines provided by equipment manufacturers or local regulations, helps minimize the risk of electrical accidents, injuries, and property damage. Regular training, awareness, and a safety-focused mindset contribute to a safer working environment when dealing with electric motors.
How do electric motors handle variations in load, speed, and torque?
Electric motors are designed to handle variations in load, speed, and torque through various control mechanisms and techniques. Here’s a detailed explanation of how electric motors handle these variations:
- Load Variations: Electric motors can handle variations in load by adjusting the amount of torque they produce. When the load on the motor increases, such as when additional resistance or weight is applied, the motor responds by increasing the torque output. This is achieved through the control of the motor’s input current or voltage. For example, in DC motors, increasing the current supplied to the motor can compensate for the increased load, ensuring that the motor can continue to operate at the desired speed.
- Speed Variations: Electric motors can handle variations in speed by adjusting the frequency of the power supply or by varying the voltage applied to the motor. In AC motors, the speed is determined by the frequency of the alternating current, so changing the frequency can alter the motor’s speed. In DC motors, the speed can be controlled by adjusting the voltage applied to the motor. This can be achieved using electronic speed controllers (ESCs) or by employing pulse width modulation (PWM) techniques to control the average voltage supplied to the motor.
- Torque Variations: Electric motors can handle variations in torque by adjusting the current flowing through the motor windings. The torque produced by a motor is directly proportional to the current flowing through the motor. By increasing or decreasing the current, the motor can adjust its torque output to match the requirements of the load. This can be accomplished through various control methods, such as using motor drives or controllers that regulate the current supplied to the motor based on the desired torque.
- Control Systems: Electric motors often incorporate control systems to handle variations in load, speed, and torque more precisely. These control systems can include feedback mechanisms, such as encoders or sensors, which provide information about the motor’s actual speed or position. The feedback signals are compared to the desired speed or position, and the control system adjusts the motor’s input parameters accordingly to maintain the desired performance. This closed-loop control allows electric motors to respond dynamically to changes in load, speed, and torque.
In summary, electric motors handle variations in load, speed, and torque through various control mechanisms. By adjusting the current, voltage, or frequency of the power supply, electric motors can accommodate changes in load and speed requirements. Additionally, control systems with feedback mechanisms enable precise regulation of motor performance, allowing the motor to respond dynamically to variations in load, speed, and torque. These control techniques ensure that electric motors can operate effectively across a range of operating conditions and adapt to the changing demands of the application.
editor by CX 2023-11-18
China wholesaler Explosion Proof Flameproof Asynchronous Synchronous AC DC Electrical Induction Electric Motor vacuum pump oil
Product Description
Asynchronous Synchronous AC DC Yrkk Induction Electric Motor
ZheJiang ELECTRIC
Produce Synchronous AC/ DC Yrkk ZZJ Z4 Z Induction Electric Motor
Power from 10-1000kw 5000kw-50000kw 50mw – 100mw .
Deeply appreciate your enquiry, We are biggest of chinese company 30 years experiences,1000 workers with 10 billion USD turnover in ZheJiang china .Welcome your visiting !! |
Series Z4 d-c machines are newly developed products of our works. The products are found wide use for prime mover in various, sucb as mill auxilinry in merallurgical induetry, metal cutting machine-tool, paper making, print, textile, printing and dyeing, cement-making, plastic extruding machine, etc. |
Outline and mounting dimensions of the motors comply with IEC72 Standard, except for the axial distance between the mounting holes (dimension B).
Performance and technical requirements of the motors can be checked in accordance with IEC34-1 Standard of the International Electro technical Commission, or DIN57530 Norm of the Deutsche Industries-Norm.
The motors are class F insulated, with reliable insulating construction and impregnating process, cnsuring stable dielectric performance and excellent heat dissipation. The motors possess the features of small size, good performance, light weight, large output, high efficiency and reliability, being able to match the current international advanced level. The motors can be lastingly operated form fully controlled three-phase bridge without a smoothing reactor. Motors for 160V may be operated on single-phase bridge thyristor. In that case, a smoothing reactor, whose inductance is specified in the relevant technical date, should be inserted in the armature circult to suppres ripple current. |
Application: | Industrial |
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Speed: | Low Speed |
Number of Stator: | Three-Phase |
Function: | Driving, Control |
Casing Protection: | Closed Type |
Number of Poles: | 6 |
Customization: |
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What maintenance practices are essential for prolonging the lifespan of an electric motor?
Maintaining electric motors is crucial for prolonging their lifespan and ensuring optimal performance. Proper maintenance practices help prevent failures, minimize downtime, and maximize the efficiency and reliability of electric motors. Here’s a detailed explanation of essential maintenance practices for prolonging the lifespan of an electric motor:
- Regular Inspections: Conduct regular visual inspections of the motor to identify any signs of wear, damage, or loose connections. Inspect the motor’s external components, such as the housing, bearings, cooling fans, and cables. Look for any unusual noise, vibration, or overheating during operation, as these can indicate potential issues that require attention.
- Lubrication: Proper lubrication is vital for the smooth operation and longevity of electric motors. Follow the manufacturer’s guidelines for lubrication intervals and use the recommended lubricants. Apply lubrication to bearings, shafts, and other moving parts as specified. Over-lubrication or using incompatible lubricants can cause overheating and premature wear, so it’s essential to follow the recommended practices.
- Cleaning: Keep the motor clean and free from dirt, dust, and debris that can accumulate over time. Regularly clean the motor’s exterior using a soft brush or compressed air. Ensure that cooling vents and fans are clear of any obstructions to maintain proper airflow and prevent overheating. Cleanliness helps prevent insulation damage and improves heat dissipation.
- Alignment and Balance: Misalignment or imbalance in the motor’s shaft and coupling can lead to excessive vibrations and premature wear. Regularly check and correct any misalignment or imbalance issues using precision alignment tools. Proper alignment and balance reduce stress on bearings and extend their lifespan, contributing to the overall longevity of the motor.
- Temperature Monitoring: Monitor the motor’s temperature during operation using temperature sensors or thermal imaging techniques. Excessive heat can damage insulation, bearings, and other components. If the motor consistently operates at high temperatures, investigate the cause and take corrective actions, such as improving ventilation, reducing loads, or addressing any cooling system issues.
- Electrical Connections: Inspect and tighten electrical connections regularly to ensure secure and reliable connections. Loose or corroded connections can lead to voltage drops, increased resistance, and overheating. Check terminal blocks, wiring, and motor leads for any signs of damage or degradation. Properly torquing electrical connections and addressing any issues promptly helps maintain electrical integrity.
- Vibration Analysis: Perform regular vibration analysis to detect any abnormal vibration patterns that could indicate underlying issues. Vibration analysis tools and techniques can help identify unbalanced rotors, misalignment, bearing wear, or other mechanical problems. Addressing vibration issues early can prevent further damage and improve motor performance and longevity.
- Periodic Testing and Maintenance: Conduct periodic testing and maintenance based on the manufacturer’s recommendations and industry best practices. This may include insulation resistance testing, winding resistance testing, bearing lubrication checks, and other diagnostic tests. Such tests help identify potential problems before they escalate and allow for timely maintenance and repairs.
- Training and Documentation: Ensure that maintenance personnel are properly trained in electric motor maintenance practices. Provide training on inspection techniques, lubrication procedures, alignment methods, and other essential maintenance tasks. Maintain comprehensive documentation of maintenance activities, including inspection reports, maintenance schedules, and repair records.
By implementing these maintenance practices, motor owners can significantly prolong the lifespan of electric motors. Regular inspections, proper lubrication, cleaning, alignment, temperature monitoring, electrical connection maintenance, vibration analysis, periodic testing, and training contribute to the motor’s reliability, efficiency, and overall longevity.
What safety precautions should be followed when working with electric motors?
Working with electric motors requires adherence to specific safety precautions to ensure the well-being of individuals and prevent accidents. Electric motors involve electrical hazards that can cause electric shock, burns, or other injuries if proper safety measures are not followed. Here’s a detailed explanation of the safety precautions that should be followed when working with electric motors:
- Qualified Personnel: It is important to assign work on electric motors to qualified personnel who have the necessary knowledge, training, and experience in electrical systems and motor operation. Qualified electricians or technicians should handle installation, maintenance, and repairs involving electric motors.
- De-Energization and Lockout/Tagout: Before performing any work on electric motors, they should be de-energized, and appropriate lockout/tagout procedures should be followed. This involves isolating the motor from the power source, ensuring that it cannot be energized accidentally. Lockout/tagout procedures help prevent unexpected startup and protect workers from electrical hazards.
- Personal Protective Equipment (PPE): When working with electric motors, appropriate personal protective equipment should be worn. This may include insulated gloves, safety glasses, protective clothing, and footwear with electrical insulation. PPE helps protect against potential electrical shocks, burns, and other physical hazards.
- Inspection and Maintenance: Regular inspection and maintenance of electric motors are essential to identify potential issues or defects that could compromise safety. This includes checking for loose connections, damaged insulation, worn-out components, or overheating. Any defects or abnormalities should be addressed promptly by qualified personnel.
- Proper Grounding: Electric motors should be properly grounded to prevent electrical shock hazards. Grounding ensures that any fault currents are redirected safely to the ground, reducing the risk of electric shock to individuals working on or around the motor.
- Avoiding Wet Conditions: Electric motors should not be operated or worked on in wet or damp conditions unless they are specifically designed for such environments. Water or moisture increases the risk of electrical shock. If working in wet conditions is necessary, appropriate safety measures and equipment, such as waterproof PPE, should be used.
- Safe Electrical Connections: When connecting or disconnecting electric motors, proper electrical connections should be made. This includes ensuring that power is completely switched off, using appropriate tools and techniques for making connections, and tightening electrical terminals securely. Loose or faulty connections can lead to electrical hazards, overheating, or equipment failure.
- Awareness of Capacitors: Some electric motors contain capacitors that store electrical energy even when the motor is de-energized. These capacitors can discharge unexpectedly and cause electric shock. Therefore, it is important to discharge capacitors safely before working on the motor and to be cautious of potential residual energy even after de-energization.
- Training and Knowledge: Individuals working with electric motors should receive proper training and have a good understanding of electrical safety practices and procedures. They should be knowledgeable about the potential hazards associated with electric motors and know how to respond to emergencies, such as electrical shocks or fires.
- Adherence to Regulations and Standards: Safety precautions should align with relevant regulations, codes, and standards specific to electrical work and motor operation. These may include local electrical codes, occupational safety guidelines, and industry-specific standards. Compliance with these regulations helps ensure a safe working environment.
It is crucial to prioritize safety when working with electric motors. Following these safety precautions, along with any additional guidelines provided by equipment manufacturers or local regulations, helps minimize the risk of electrical accidents, injuries, and property damage. Regular training, awareness, and a safety-focused mindset contribute to a safer working environment when dealing with electric motors.
How do electric motors handle variations in load, speed, and torque?
Electric motors are designed to handle variations in load, speed, and torque through various control mechanisms and techniques. Here’s a detailed explanation of how electric motors handle these variations:
- Load Variations: Electric motors can handle variations in load by adjusting the amount of torque they produce. When the load on the motor increases, such as when additional resistance or weight is applied, the motor responds by increasing the torque output. This is achieved through the control of the motor’s input current or voltage. For example, in DC motors, increasing the current supplied to the motor can compensate for the increased load, ensuring that the motor can continue to operate at the desired speed.
- Speed Variations: Electric motors can handle variations in speed by adjusting the frequency of the power supply or by varying the voltage applied to the motor. In AC motors, the speed is determined by the frequency of the alternating current, so changing the frequency can alter the motor’s speed. In DC motors, the speed can be controlled by adjusting the voltage applied to the motor. This can be achieved using electronic speed controllers (ESCs) or by employing pulse width modulation (PWM) techniques to control the average voltage supplied to the motor.
- Torque Variations: Electric motors can handle variations in torque by adjusting the current flowing through the motor windings. The torque produced by a motor is directly proportional to the current flowing through the motor. By increasing or decreasing the current, the motor can adjust its torque output to match the requirements of the load. This can be accomplished through various control methods, such as using motor drives or controllers that regulate the current supplied to the motor based on the desired torque.
- Control Systems: Electric motors often incorporate control systems to handle variations in load, speed, and torque more precisely. These control systems can include feedback mechanisms, such as encoders or sensors, which provide information about the motor’s actual speed or position. The feedback signals are compared to the desired speed or position, and the control system adjusts the motor’s input parameters accordingly to maintain the desired performance. This closed-loop control allows electric motors to respond dynamically to changes in load, speed, and torque.
In summary, electric motors handle variations in load, speed, and torque through various control mechanisms. By adjusting the current, voltage, or frequency of the power supply, electric motors can accommodate changes in load and speed requirements. Additionally, control systems with feedback mechanisms enable precise regulation of motor performance, allowing the motor to respond dynamically to variations in load, speed, and torque. These control techniques ensure that electric motors can operate effectively across a range of operating conditions and adapt to the changing demands of the application.
editor by CX 2023-10-20
China Standard Hot Sale Explosion Proof Fan Motor Ybf-3-100L2-10 (0.75Kw) 380V 6/8/10/12 Poles High Quality Ybf3 Aluminum Body 3phase AC Inductionelectric Motor IP55 wholesaler
Item Description
Very hot Sale Explosion Evidence Admirer Motor YBF-3-100L2-ten (.75Kw) 380V 6/8/ten/12 Poles Substantial High quality Ybf3 Aluminum Human body 3phase AC InductionElectric Motor IP55
The YBF3 motors are our organization based YB, YB2 collection motors on new technologies at domestic and overseas with the present electromagnetic structures, processes, components and other aspects of the advancement of successful new goods, with vitality-effective , temperature margin, long life, excellent performance, minimal noise,
1. Solution Introduction
Very hot Sale Explosion Proof Enthusiast Motor YBF-3-100L2-10 (.75Kw) 380V 6/8/10/twelve Poles Large Top quality Ybf3 Aluminum Entire body 3phase AC InductionElectric Motor IP55 The collection motor efficiency indicators in line GB186~13 0571 88828 13858117778-2006 “small and medium-section asynchronous motor vitality efficiency limit worth and strength effectiveness rating” motor energy performance 2, the energy score and mounting dimensions conform to IEC standards and with the YB, YB2 series motors exact same.
two. Products Parameter
Variety | Output KW | Volt(V) | Rated Current(A) | Rated Velocity(r/min) | Efficiency(%) | Power Issue(CosΦ) |
380V 50HZ Synchronous Speed 3000r/min(2Poles) | ||||||
YBF3-63M1-2 | .eighteen | 380 | .52 | 2720 | 66 | .eight |
YBF3-63M2-2 | .twenty five | 380 | .69 | 2720 | sixty eight | .81 |
YBF3-71M1-2 | .37 | 380 | .ninety nine | 2760 | 70 | .81 |
YBF3-71M2-2 | .fifty five | 380 | one.38 | 2760 | 73 | .82 |
YBF3-80M1-2 | .seventy five | 660 | one.02 | 2840 | seventy seven.five | .83 |
YBF3-80M2-2 | one.1 | 660 | 1.four | 2840 | 82.eight | .83 |
YBF3-90S-two | one.5 | 660 | 1.86 | 2850 | eighty four.one | .84 |
YBF3-90L-two | two.two | 660 | two.sixty four | 2850 | eighty five.six | .85 |
YBF3-100L-2 | 3 | 660 | three.48 | 2870 | 86.seven | .87 |
YBF3-112M-two | 4 | 380/660 | 7.9/4.6 | 2890 | 87.6 | .88 |
YBF3-132S1-two | 5.five | 380/660 | ten.7/6.two | 2900 | 88.six | .88 |
YBF3-132S2-2 | 7.five | 380/660 | fourteen.3/8.three | 2900 | 89.five | .89 |
YBF3-160M1-two | 11 | 380/660 | twenty.7/twelve | 2940 | 90.five | .89 |
YBF3-160M2-2 | 15 | 380/660 | 28/sixteen.2 | 2940 | ninety one.3 | .89 |
YBF3-160L-2 | eighteen.five | 380/660 | 34.3/19.8 | 2940 | ninety one.8 | .89 |
380V 50HZ Synchronous Speed 1500r/min(4Poles) | ||||||
YBF3-63M1-4 | .twelve | 380 | .44 | 1340 | fifty eight | .seventy two |
YBF3-63M2-4 | .18 | 380 | .fifty nine | 1340 | 63 | .73 |
YBF3-71M1-four | .25 | 380 | .seventy eight | 1350 | sixty six | .seventy four |
YBF3-71M2-four | .37 | 380 | 1.08 | 1350 | sixty nine | .seventy five |
YBF3-80M1-four | .fifty five | 660 | .8 | 1390 | 80.7 | .seventy five |
YBF3-80M2-four | .75 | 660 | 1.06 | 1390 | eighty two.3 | .75 |
YBF3-90S-four | 1.1 | 660 | 1.53 | 1390 | eighty three.8 | .seventy five |
YBF3-90L-4 | 1.five | 660 | 2.06 | 1390 | eighty five | .75 |
YBF3-100L1-4 | two.two | 660 | 2.75 | 1420 | 86.4 | .81 |
YBF3-100L2-4 | 3 | 660 | three.sixty six | 1420 | 87.4 | .82 |
YBF3-112M-4 | four | 380/660 | eight.4/4.9 | 1440 | 88.three | .eighty two |
YBF3-132S-4 | 5.5 | 380/660 | eleven.2/6.5 | 1450 | 89.2 | .82 |
YBF3-132M-four | 7.five | 380/660 | fifteen.1/8.seven | 1450 | 90.1 | .83 |
YBF3-160M-four | 11 | 380/660 | 21.6/twelve.five | 1460 | 91 | .eighty five |
YBF3-160L-four | 15 | 380/660 | 28.8/16.seven | 1460 | ninety one.8 | .86 |
YBF3-180M-4 | eighteen.five | 380/660 | 35.4/20.five | 1470 | 92.two | .86 |
380V 50HZ Synchronous Speed 1000r/min(6Poles) | ||||||
YBF3-71M1-6 | .18 | 380 | .sixty seven | 880 | 60 | .sixty six |
YBF3-71M2-6 | .25 | 380 | .88 | 880 | sixty three | .sixty eight |
YBF3-80M1-6 | .37 | 660 | .73 | 890 | 63.3 | .seven |
YBF3-80M2-six | .55 | 660 | .89 | 890 | 75.four | .72 |
YBF3-90S-six | .seventy five | 660 | 1.17 | 910 | seventy seven.7 | .72 |
YBF3-90L-six | 1.one | 660 | 1.65 | 910 | seventy nine.7 | .73 |
YBF3-100L-6 | 1.5 | 660 | two.18 | 930 | 81.five | .seventy four |
YBF3-112M-6 | 2.2 | 380/660 | five.4/3.2 | 940 | 83.four | .74 |
YBF3-132S-6 | three | 380/660 | seven.3/4.two | 970 | 84.9 | .seventy four |
YBF3-132M1-six | 4 | 380/660 | nine.5/5.five | 970 | 86.one | .74 |
YBF3-132M2-six | 5.five | 380/660 | 12.7/7.4 | 970 | 87.four | .seventy five |
YB3F-160M-six | seven.five | 380/660 | 16.4/9.five | 970 | 89 | .78 |
YBF3-160L-6 | eleven | 380/660 | 23.5/13.six | 970 | 90 | .79 |
380V 50HZ Synchronous Pace 1000r/min(6Poles) | ||||||
YBF3-80M1-8 | .18 | 660 | .five | 650 | fifty two | .sixty one |
YBF3-80M2-eight | .25 | 660 | .65 | 650 | 55 | .61 |
YBF3-90S-8 | .37 | 660 | .83 | 670 | sixty three | .sixty two |
YBF3-90L-eight | .fifty five | 660 | 1.19 | 670 | sixty four | .63 |
YBF3-100L1-eight | .seventy five | 660 | 1.36 | 690 | 71 | .68 |
YBF3-100L2-eight | one.1 | 660 | 1.ninety one | 690 | seventy three | .sixty nine |
YBF3-112M-8 | 1.5 | 380/660 | 4.4/2.5 | 690 | 75 | .69 |
YBF3-132S-8 | two.two | 380/660 | 5.seventy eight/3.34 | 710 | seventy nine | .73 |
YBF3-132M-8 | 3 | 380/660 | 7.69/4.forty four | 710 | eighty one | .73 |
YBF3-160M1-eight | four | 380/660 | nine.7/5.6 | 720 | eighty five.5 | .73 |
YBF3-160M2-8 | 5.5 | 380/660 | 13/7.five | 720 | 85.5 | .seventy five |
YBF3-160L-8 | 7.5 | 380/660 | sixteen.9/9.eight | 720 | 88.five | .seventy six |
three. Solution Application
Hot Sale Explosion Evidence Fan Motor YBF-3-100L2-10 (.75Kw) 380V 6/8/10/12 Poles Large Good quality Ybf3 Aluminum Physique 3phase AC InductionElectric Motor IP55 can be utilised in the place in which exists explosive gasoline mixture, this kind of as coal business, petroleum market, chemical sector, smelting industry, all-natural gasoline sector, CZPT and oil processing industry, paper business, CZPT sector and so on.
4. Related Merchandise
5. CZPT Manufacturing facility &Workshop
six. Certification
An AC motor is a kind of motor that utilizes the phenomenon of electromagnetic induction. AC electricity drives the motor. It is a recent that periodically reverses route and modifications its magnitude of the recent in excess of time. This existing is the opposite of a direct present or “DC” which flows in only one course. AC motors can give a reasonably successful way to produce mechanical power from a easy electrical enter signal.
DC motors use strength from batteries or other generating resources that supply a continual voltage. A DC motor consists of many areas, the most famous of which consist of bearings, shafts, and gearboxes or gears. DC motors provide better pace variation and management and make far more torque than AC motors. The two kinds of DC motors contain Brushed motors: Brushed motors are 1 of the oldest varieties and are internally commutated motors driven by DC present. A brushed motor consists of a rotor, brushes, and a shaft. The charge and polarity of the brushes handle the direction and speed of the motor. Brushless Motors: In latest years, brushless motors have turn out to be popular for many purposes, mostly due to the fact of their effectiveness. Brushless motors are built in the identical way as brushed motors, minus the brushes of training course. Brushless motors also incorporate committed circuitry to manage speed and path. In brushless motors, magnets are mounted all around the rotor, an performance-boosting configuration.