Product Description
Product Description
NEMA Single Phase Air Compressor Motor Feature:
HP:2-5HP
RPM:3600RPM
Frame:56-215T
Protection:IP23
Class B Temp Rise
Removable Universal Base
Overload Protection With Manual Reset
Capacitor Start / Capacitor Run
| Model | HP | RPM | AMPS | VOLTS | FRAME | HZ | IP | INS |
| CM01256 | 1 | 3600 | 13.2/6.6 | 115/230 | 56 | 60 | 23 | F |
| 120156-ODP | 1 | 3600 | 11.2/5.6 | 115/230 | ||||
| CM15256 | 1.5 | 3600 | 17.4/8.7 | 115/230 | ||||
| CM57156 | 2SPL | 3600 | 15/7.5 | 115/230 | ||||
| CM03256 | 3SPL | 3600 | 18/9 | 115/230 | ||||
| 12 0571 -ODP | 3.7SPL | 3600 | 16-15 | 208-230 | ||||
| CM05256 | 5SPL | 3600 | 16-15 | 208-230 | ||||
| 1203T-ODP | 3 | 3600 | 16-15 | 208-230 | 143/5T | |||
| 1205T-ODP | 5 | 3600 | 22-21 | 208-230 | 143/5T | |||
| CM032145T | 3 | 3600 | 25.0/12.5A | 115/230 | 145T | 60 | 23 | F |
| CM032182T | 3600 | 13.8-13.0A | 208-230 | 182/4T | ||||
| CM034184T | 1800 | 16.8-16.0A | 208-230 | 182/4T | ||||
| CM5714T | 5 | 3600 | 24.0-23.0A | 208-230 | 182/4T | |||
| CM054184T | 1800 | 22.7-20.6A | 208-230 | 182/4T | ||||
| CM722184T | 7.5 | 3600 | 33.0-30.0A | 208-230 | 182/4T | |||
| CM724215T | 1800 | 33.0-31.4A | 208-230 | 213/5T | ||||
| CM157115T | 10 | 3600 | 48.0-46.0A | 208-230 | 213/5T | |||
| CM15715T | 1800 | 41.0-40.0A | 208-230 | 213/5T | ||||
| CMW032184T | 3 | 3600 | 13.8-13.0A | 208-230 | 182/4T | |||
| CMW034184T | 1800 | 16.8-15.0A | 208-230 | 182/4T | ||||
| CMW5714T | 5 | 3600 | 24.0-23.0A | 208-230 | 182/4T | |||
| CMW054184T | 1800 | 28.5-27.0A | 208-230 | 182/4T | ||||
| CMW722184T | 7.5 | 3600 | 33.4-29.6A | 208-230 | 182/4T | |||
| CMF032145T | 3 | 3600 | 13.8-13.0A | 208-230 | 145T | 60 | 23 | F |
| CMF032182T | 3600 | 13.8-13.0A | 208-230 | 182/4T | ||||
| CMF034184T | 1800 | 16.8-16.0A | 208-230 | 182/4T | ||||
| CMF5714T | 5 | 3600 | 24.0-23.0A | 208-230 | 182/4T | |||
| CMF054184T | 1800 | 22.7-20.6A | 208-230 | 182/4T | ||||
| CMF722184T | 7.5 | 3600 | 33.0-30.0A | 208-230 | 182/4T | |||
| CMF724215T | 1800 | 33.0-31.4A | 208-230 | 213/5T | ||||
| CMF157115T | 10 | 3600 | 48.0-46.0A | 208-230 | 213/5T | |||
| CMF15715T | 1800 | 41.0-40.0A | 208-230 | 213/5T |
Company Profile
HangZhou CHINAMFG Motor Factory is located in China’s coastal city – in HangZhou City. The transportation is very convenient. (Close to NO.104 National Road, HangZhou)Founded in 2003, we have many years of motor manufacturing history. Our company has strong scientific and technological strength, advanced development tools, high-efficient production facilities, and complete testing means. We have improved the modern management system. We produce IEC standard aluminum shell, die-casting aluminum casing and NEMA standard electrical motor shell plate, which are used in air compressors, agricultural machinery, electric tools, pumps, and fans. With superior performance and good prices, we have enjoyed a high reputation.We are actively plHangZhou and making technical innovation, and look CHINAMFG to further improving the modern enterprise management system. We hope to provide more advanced technology, more internationally competitive products and higher quality services to our customers. We are committed to constantly striving for excellence, and create a glorious future in the field!
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Packaging & Shipping
Certifications
The exhibition
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FAQ
Q:Are you a manufacturer ? And where is it ?
A:We are a professional manufacturer in electric motors, and our factory is located in HangZhou City, ZHangZhoug province, China.
Q:What’is your terms of payment ?
A:T/T is available. (30%deposit before production, 70%balance before shipping)
Q:What’s your delivery time ?
A:Products will usually be shipped in 20 days after the initial payment.
Q:How do you pack your products ?
A:Small motors are packed in plywood cases, and large motors in wooden cases.
Q:what service can we provide ?
A:Accepted Delivery Terms: FOB;Accepted Payment Currency:USD;Accepted Payment Type: T/T;Language Spoken:English,Chinese;
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| Application: | Machine Tool |
|---|---|
| Speed: | Low Speed |
| Number of Stator: | Single-Phase |
| Function: | Control |
| Casing Protection: | Open Type |
| Number of Poles: | 2 |
| Samples: |
US$ 150/Piece
1 Piece(Min.Order) | |
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| Customization: |
Available
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Are there environmental considerations associated with the use of AC motors?
Yes, there are several environmental considerations associated with the use of AC motors. These considerations are primarily related to energy consumption, greenhouse gas emissions, and the disposal of motors at the end of their life cycle. Let’s explore these environmental considerations in detail:
- Energy Efficiency: AC motors can have varying levels of energy efficiency, which directly impacts their environmental impact. Motors with higher efficiency convert a larger percentage of electrical energy into useful mechanical work, resulting in reduced energy consumption. By selecting and using high-efficiency AC motors, energy usage can be minimized, leading to lower greenhouse gas emissions and reduced reliance on fossil fuels for electricity generation.
- Greenhouse Gas Emissions: The electricity consumed by AC motors is often produced by power plants that burn fossil fuels, such as coal, natural gas, or oil. The generation of electricity from these fossil fuels releases greenhouse gases, contributing to climate change. By employing energy-efficient motors and optimizing motor systems, businesses and individuals can reduce their electricity demand, leading to lower greenhouse gas emissions and a smaller carbon footprint.
- Motor Disposal and Recycling: AC motors contain various materials, including metals, plastics, and electrical components. At the end of their life cycle, proper disposal or recycling is important to minimize their environmental impact. Some components, such as copper windings and steel casings, can be recycled, reducing the need for new raw materials and energy-intensive manufacturing processes. It is crucial to follow local regulations and guidelines for the disposal and recycling of motors to prevent environmental pollution and promote resource conservation.
- Manufacturing and Production: The manufacturing and production processes associated with AC motors can have environmental implications. The extraction and processing of raw materials, such as metals and plastics, can result in habitat destruction, energy consumption, and greenhouse gas emissions. Additionally, the manufacturing processes themselves can generate waste and pollutants. Motor manufacturers can mitigate these environmental impacts by adopting sustainable practices, using recycled materials, reducing waste generation, and implementing energy-efficient production methods.
- Life Cycle Assessment: Conducting a life cycle assessment (LCA) of AC motors can provide a holistic view of their environmental impact. An LCA considers the environmental aspects associated with the entire life cycle of the motor, including raw material extraction, manufacturing, transportation, use, and end-of-life disposal or recycling. By analyzing the different stages of the motor’s life cycle, stakeholders can identify opportunities for improvement, such as optimizing energy efficiency, reducing emissions, and implementing sustainable practices.
To address these environmental considerations, governments, organizations, and industry standards bodies have developed regulations and guidelines to promote energy efficiency and reduce the environmental impact of AC motors. These include efficiency standards, labeling programs, and incentives for the use of high-efficiency motors. Additionally, initiatives promoting motor system optimization, such as proper motor sizing, maintenance, and control, can further enhance energy efficiency and minimize environmental impact.
In summary, the environmental considerations associated with the use of AC motors include energy efficiency, greenhouse gas emissions, motor disposal and recycling, manufacturing processes, and life cycle assessment. By prioritizing energy efficiency, proper disposal, recycling, and sustainable manufacturing practices, the environmental impact of AC motors can be minimized, contributing to a more sustainable and environmentally conscious approach to motor usage.
What are the common signs of AC motor failure, and how can they be addressed?
AC motor failure can lead to disruptions in various industrial and commercial applications. Recognizing the common signs of motor failure is crucial for timely intervention and preventing further damage. Here are some typical signs of AC motor failure and potential ways to address them:
- Excessive Heat: Excessive heat is a common indicator of motor failure. If a motor feels excessively hot to the touch or emits a burning smell, it could signify issues such as overloaded windings, poor ventilation, or bearing problems. To address this, first, ensure that the motor is properly sized for the application. Check for obstructions around the motor that may be impeding airflow and causing overheating. Clean or replace dirty or clogged ventilation systems. If the issue persists, consult a qualified technician to inspect the motor windings and bearings and make any necessary repairs or replacements.
- Abnormal Noise or Vibration: Unusual noises or vibrations coming from an AC motor can indicate various problems. Excessive noise may be caused by loose or damaged components, misaligned shafts, or worn bearings. Excessive vibration can result from imbalanced rotors, misalignment, or worn-out motor parts. Addressing these issues involves inspecting and adjusting motor components, ensuring proper alignment, and replacing damaged or worn-out parts. Regular maintenance, including lubrication of bearings, can help prevent excessive noise and vibration and extend the motor’s lifespan.
- Intermittent Operation: Intermittent motor operation, where the motor starts and stops unexpectedly or fails to start consistently, can be a sign of motor failure. This can be caused by issues such as faulty wiring connections, damaged or worn motor brushes, or problems with the motor’s control circuitry. Check for loose or damaged wiring connections and make any necessary repairs. Inspect and replace worn or damaged motor brushes. If the motor still exhibits intermittent operation, it may require professional troubleshooting and repair by a qualified technician.
- Overheating or Tripping of Circuit Breakers: If an AC motor consistently causes circuit breakers to trip or if it repeatedly overheats, it indicates a problem that needs attention. Possible causes include high starting currents, excessive loads, or insulation breakdown. Verify that the motor is not overloaded and that the load is within the motor’s rated capacity. Check the motor’s insulation resistance to ensure it is within acceptable limits. If these measures do not resolve the issue, consult a professional to assess the motor and its electrical connections for any faults or insulation breakdown that may require repair or replacement.
- Decreased Performance or Efficiency: A decline in motor performance or efficiency can be an indication of impending failure. This may manifest as reduced speed, decreased torque, increased energy consumption, or inadequate power output. Factors contributing to decreased performance can include worn bearings, damaged windings, or deteriorated insulation. Regular maintenance, including lubrication and cleaning, can help prevent these issues. If performance continues to decline, consult a qualified technician to inspect the motor and perform any necessary repairs or replacements.
- Inoperative Motor: If an AC motor fails to operate entirely, there may be an issue with the power supply, control circuitry, or internal motor components. Check the power supply and connections for any faults or interruptions. Inspect control circuitry, such as motor starters or contactors, for any damage or malfunction. If no external faults are found, it may be necessary to dismantle the motor and inspect internal components, such as windings or brushes, for any faults or failures that require repair or replacement.
It’s important to note that motor failure causes can vary depending on factors such as motor type, operating conditions, and maintenance practices. Regular motor maintenance, including inspections, lubrication, and cleaning, is essential for early detection of potential failure signs and for addressing issues promptly. When in doubt, it is advisable to consult a qualified electrician, motor technician, or manufacturer’s guidelines for appropriate troubleshooting and repair procedures specific to the motor model and application.
How does the speed control mechanism work in AC motors?
The speed control mechanism in AC motors varies depending on the type of motor. Here, we will discuss the speed control methods used in two common types of AC motors: induction motors and synchronous motors.
Speed Control in Induction Motors:
Induction motors are typically designed to operate at a constant speed determined by the frequency of the AC power supply and the number of motor poles. However, there are several methods for controlling the speed of induction motors:
- Varying the Frequency: By varying the frequency of the AC power supply, the speed of an induction motor can be adjusted. This method is known as variable frequency drive (VFD) control. VFDs convert the incoming AC power supply into a variable frequency and voltage output, allowing precise control of motor speed. This method is commonly used in industrial applications where speed control is crucial, such as conveyors, pumps, and fans.
- Changing the Number of Stator Poles: The speed of an induction motor is inversely proportional to the number of stator poles. By changing the connections of the stator windings or using a motor with a different pole configuration, the speed can be adjusted. However, this method is less commonly used and is typically employed in specialized applications.
- Adding External Resistance: In some cases, external resistance can be added to the rotor circuit of an induction motor to control its speed. This method, known as rotor resistance control, involves inserting resistors in series with the rotor windings. By varying the resistance, the rotor current and torque can be adjusted, resulting in speed control. However, this method is less efficient and is mainly used in specific applications where precise control is not required.
Speed Control in Synchronous Motors:
Synchronous motors offer more precise speed control compared to induction motors due to their inherent synchronous operation. The following methods are commonly used for speed control in synchronous motors:
- Adjusting the AC Power Frequency: Similar to induction motors, changing the frequency of the AC power supply can control the speed of synchronous motors. By adjusting the power frequency, the synchronous speed of the motor can be altered. This method is often used in applications where precise speed control is required, such as industrial machinery and processes.
- Using a Variable Frequency Drive: Variable frequency drives (VFDs) can also be used to control the speed of synchronous motors. By converting the incoming AC power supply into a variable frequency and voltage output, VFDs can adjust the motor speed with high accuracy and efficiency.
- DC Field Control: In some synchronous motors, the rotor field is supplied by a direct current (DC) source, allowing for precise control over the motor’s speed. By adjusting the DC field current, the magnetic field strength and speed of the motor can be controlled. This method is commonly used in applications that require fine-tuned speed control, such as industrial processes and high-performance machinery.
These methods provide different ways to control the speed of AC motors, allowing for flexibility and adaptability in various applications. The choice of speed control mechanism depends on factors such as the motor type, desired speed range, accuracy requirements, efficiency considerations, and cost constraints.
editor by CX 2024-04-09
China factory 5.5HP AC Single Phase Motor 2880rpm Induction Fan Motor for Air Compressor vacuum pump ac
Product Description
YC series motor is a kind of heavy-duty single-phase induction electric motor with the feature of totally enclosed fan cooled (TEFC). The mounting dimension is fully comformed with IEC standard. This type features of easy maintenance, reliable operation, low temperature rise, low noise, small starting current and large starting torque. YC series is ideal for small workshops and water pump and is the best choice for house using with 220VAC power supply.
– Powerful Ac motor: The compact and small-sized AC motors feature output 5.5 HP, steel frame and single phase.
– High Efficiency: The electric motor can run at the maximum speed 2880 RPM, high working efficiency. 220V/50Hz input volts, 1.1″ (28mm) shaft diameter, 2.36″ (60mm) shaft length. The upper hardness shaft is more durable.
– Steel Frame: The compressor duty motor is made of high quality steel material. The firm and CHINAMFG material can protect the engine well. Class F insulation.
– Super Quiet: Quiet series design at only 78 dB noise level for operator. Very ideal for the home workbench and outdoor use.
– High Speed Cooling Fan: Big fan at 1 end cools the motor in hours’ running, even in dusty or damp environments, reducing energy costs or overheads, increasing winding lifetimes.
– Heavy-duty oversized ball bearings. High tensile strength steel shaft. Large all-metal capacitor cover and large easy-to-wire junction box.
Technical Data
| Type | Power (Kw) |
Speed (r/min) |
Current (A) |
Voltage (V) |
Efficiency | Power Factor |
Noise Level |
Tst |
Overall Dimension (inch) |
| YC112M-2 | 4 | 2880 | 24.8 | 220/230 | 79% | 0.86 | 78 | 2.2 | 17.9×9.65×11.8 |
Workshops
| Application: | Machine Tool |
|---|---|
| Speed: | 2880 Rpm |
| Number of Stator: | Single-Phase |
| Casing Protection: | Closed Type |
| Number of Poles: | 2 |
| Starting Mode: | Capacitor |
| Samples: |
US$ 103.99/PC
1 PC(Min.Order) | |
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| Customization: |
Available
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Can you explain the concept of motor efficiency and how it relates to AC motors?
Motor efficiency is a measure of how effectively an electric motor converts electrical power into mechanical power. It represents the ratio of the motor’s useful output power (mechanical power) to the input power (electrical power) it consumes. Higher efficiency indicates that the motor converts a larger percentage of the electrical energy into useful mechanical work, while minimizing energy losses in the form of heat and other inefficiencies.
In the case of AC motors, efficiency is particularly important due to their wide usage in various applications, ranging from residential appliances to industrial machinery. AC motors can be both induction motors, which are the most common type, and synchronous motors, which operate at a constant speed synchronized with the frequency of the power supply.
The efficiency of an AC motor is influenced by several factors:
- Motor Design: The design of the motor, including its core materials, winding configuration, and rotor construction, affects its efficiency. Motors that are designed with low-resistance windings, high-quality magnetic materials, and optimized rotor designs tend to have higher efficiency.
- Motor Size: The physical size of the motor can also impact its efficiency. Larger motors generally have higher efficiency because they can dissipate heat more effectively, reducing losses. However, it’s important to select a motor size that matches the application requirements to avoid operating the motor at low efficiency due to underloading.
- Operating Conditions: The operating conditions, such as load demand, speed, and temperature, can influence motor efficiency. Motors are typically designed for maximum efficiency at or near their rated load. Operating the motor beyond its rated load or at very light loads can reduce efficiency. Additionally, high ambient temperatures can cause increased losses and reduced efficiency.
- Magnetic Losses: AC motors experience losses due to magnetic effects, such as hysteresis and eddy current losses in the core materials. These losses result in heat generation and reduce overall efficiency. Motor designs that minimize magnetic losses through the use of high-quality magnetic materials and optimized core designs can improve efficiency.
- Mechanical Friction and Windage Losses: Friction and windage losses in the motor’s bearings, shaft, and rotating parts also contribute to energy losses and reduced efficiency. Proper lubrication, bearing selection, and reducing unnecessary mechanical resistance can help minimize these losses.
Efficiency is an important consideration when selecting an AC motor, as it directly impacts energy consumption and operating costs. Motors with higher efficiency consume less electrical power, resulting in reduced energy bills and a smaller environmental footprint. Additionally, higher efficiency often translates to less heat generation, which can enhance the motor’s reliability and lifespan.
Regulatory bodies and standards organizations, such as the International Electrotechnical Commission (IEC) and the National Electrical Manufacturers Association (NEMA), provide efficiency classes and standards for AC motors, such as IE efficiency classes and NEMA premium efficiency standards. These standards help consumers compare the efficiency levels of different motors and make informed choices to optimize energy efficiency.
In summary, motor efficiency is a measure of how effectively an AC motor converts electrical power into mechanical power. By selecting motors with higher efficiency, users can reduce energy consumption, operating costs, and environmental impact while ensuring reliable and sustainable motor performance.
Can AC motors be used in renewable energy systems, such as wind turbines?
Yes, AC motors can be used in renewable energy systems, including wind turbines. In fact, AC motors are commonly employed in various applications within wind turbines due to their numerous advantages. Here’s a detailed explanation:
1. Generator: In a wind turbine system, the AC motor often functions as a generator. As the wind turbine blades rotate, they drive the rotor of the generator, which converts the mechanical energy of the wind into electrical energy. AC generators are commonly used in wind turbines due to their efficiency, reliability, and compatibility with power grid systems.
2. Variable Speed Control: AC motors offer the advantage of variable speed control, which is crucial for wind turbines. The wind speed is variable, and in order to maximize energy capture, the rotor speed needs to be adjusted accordingly. AC motors, when used as generators, can adjust their rotational speed with the changing wind conditions by modifying the frequency and voltage of the output electrical signal.
3. Efficiency: AC motors are known for their high efficiency, which is an important factor in renewable energy systems. Wind turbines aim to convert as much of the wind energy into electrical energy as possible. AC motors, especially those designed for high efficiency, can help maximize the overall energy conversion efficiency of the wind turbine system.
4. Grid Integration: AC motors are well-suited for grid integration in renewable energy systems. The electrical output from the AC generator can be easily synchronized with the grid frequency and voltage, allowing for seamless integration of the wind turbine system with the existing power grid infrastructure. This facilitates the efficient distribution of the generated electricity to consumers.
5. Control and Monitoring: AC motors offer advanced control and monitoring capabilities, which are essential for wind turbine systems. The electrical parameters, such as voltage, frequency, and power output, can be easily monitored and controlled in AC motor-based generators. This allows for real-time monitoring of the wind turbine performance, fault detection, and optimization of the power generation process.
6. Availability and Standardization: AC motors are widely available in various sizes and power ratings, making them readily accessible for wind turbine applications. They are also well-standardized, ensuring compatibility with other system components and facilitating maintenance, repair, and replacement activities.
It’s worth noting that while AC motors are commonly used in wind turbines, there are other types of generators and motor technologies utilized in specific wind turbine designs, such as permanent magnet synchronous generators (PMSGs) or doubly-fed induction generators (DFIGs). These alternatives offer their own advantages and may be preferred in certain wind turbine configurations.
In summary, AC motors can indeed be used in renewable energy systems, including wind turbines. Their efficiency, variable speed control, grid integration capabilities, and advanced control features make them a suitable choice for converting wind energy into electrical energy in a reliable and efficient manner.
What are the key advantages of using AC motors in industrial applications?
AC motors offer several key advantages that make them highly suitable for industrial applications. Here are some of the main advantages:
- Simple and Robust Design: AC motors, particularly induction motors, have a simple and robust design, making them reliable and easy to maintain. They consist of fewer moving parts compared to other types of motors, which reduces the likelihood of mechanical failure and the need for frequent maintenance.
- Wide Range of Power Ratings: AC motors are available in a wide range of power ratings, from small fractional horsepower motors to large industrial motors with several megawatts of power. This versatility allows for their application in various industrial processes and machinery, catering to different power requirements.
- High Efficiency: AC motors, especially modern designs, offer high levels of efficiency. They convert electrical energy into mechanical energy with minimal energy loss, resulting in cost savings and reduced environmental impact. High efficiency also means less heat generation, contributing to the longevity and reliability of the motor.
- Cost-Effectiveness: AC motors are generally cost-effective compared to other types of motors. Their simple construction and widespread use contribute to economies of scale, making them more affordable for industrial applications. Additionally, AC motors often have lower installation and maintenance costs due to their robust design and ease of operation.
- Flexible Speed Control: AC motors, particularly induction motors, offer various methods for speed control, allowing for precise adjustment of motor speed to meet specific industrial requirements. Speed control mechanisms such as variable frequency drives (VFDs) enable enhanced process control, energy savings, and improved productivity.
- Compatibility with AC Power Grid: AC motors are compatible with the standard AC power grid, which is widely available in industrial settings. This compatibility simplifies the motor installation process and eliminates the need for additional power conversion equipment, reducing complexity and cost.
- Adaptability to Various Environments: AC motors are designed to operate reliably in a wide range of environments. They can withstand variations in temperature, humidity, and dust levels commonly encountered in industrial settings. Additionally, AC motors can be equipped with protective enclosures to provide additional resistance to harsh conditions.
These advantages make AC motors a popular choice for industrial applications across various industries. Their simplicity, reliability, cost-effectiveness, energy efficiency, and speed control capabilities contribute to improved productivity, reduced operational costs, and enhanced process control in industrial settings.
editor by CX 2023-10-20