Product Description
Product Description
Boat Stepper (Stepping) Motor DESCRIPTION
12ZYJ DC Gear Motor | |||||
Basic Info | |||||
Item | Data | ||||
Tem Rise | 40K | ||||
Working Tem | (-20ºC~+80ºC) | ||||
Insulation Resistance | 100MΩ min 500VDC | ||||
Surge Test | 500VAC for 1min | ||||
Insulation Class | E | ||||
Weight | 15g |
Product Parameters
The drawing of 12mm N20 micro metal dc gear motor for robot(stepper motor/stepping motor)
Technical Parameters | |||||||||||
PN | Rated Voltage | Initial Speed | Ratio | Power | Noload Speed | Noload Current | Rated Speed | Rated Current | Rated Torque | Stall Torque | Stall Current |
V DC | rpm | 1:xxx | W | rpm | mA | rpm | mA | Kg.cm | Kg.cm | mA | |
12ZYJ-25A | 3 | 7500 | 298 | 1 | 25 | 50 | 20 | 150 | 0.6 | 2 | 500 |
12ZYJ-150A | 6 | 15000 | 100 | 1 | 150 | 50 | 120 | 150 | 0.3 | 1.5 | 500 |
12ZYJ-80A | 6 | 20000 | 250 | 1 | 80 | 60 | 70 | 160 | 0.5 | 2 | 600 |
stepper motor/stepping motor application
Below are only some typical models, for more specification or a customed motor, pls contact us.
Our Advantages
Our promise to our Customers(stepper motor/stepping motor):
1. Answer customer’s inquiry within 2 working days.
2. Reply to our customer questions & Concerns within 3 working days.
3. Acknowledge Customer purchase orders within 24 hours.
Company Profile
About our company(stepper motor/stepping motor)
Probond motors designs brush, brushless, stepper, hysteresis and linear motors to meet customers requirements.
Our motors use standard and special components with customer selected torque/speed requirements that can be modified to your applications.
CHINAMFG motor owns professional sales team and engineer team with more than 10 years experience in motor industry, based on China mainland handling overseas business for years, we know your needs better than others.
Probond Sonicare Toothbrush Motor and Thermostatic Valve Hysteresis Motor are our hot products on sell in 2017 with highly quality level and competitive price.
Certifications
(stepper motor/stepping motor)certificate
Packaging & Shipping
Terms of Trade (stepper motor/stepping motor)
Terms of price | FOB,CIF,CFR,EXW,DDP,etc. |
Terms of payment | 100% T/T in advance for samples |
Bulk quantity payment way can be negotited | |
Warranty | 12 months limited warranty once the items are delivered to the buyer. |
Lead time | Usually within 2 weeks for trial orders, within 3 weeks for bulk orders. |
Package | Carton o plywood pallet. |
Place of loading | ZheJiang , HangZhou, etc. |
Shipment carrier | Items are usually shipped via Fedex,DHL, TNT,UPS,EMS for trial orders and via vessel for bulk orders. |
Delivery time | Usually within 5 working days by Express 15-30 working days by vessel |
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Application: | Universal, Industrial, Household Appliances, Car, Power Tools, Robot |
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Operating Speed: | High Speed |
Excitation Mode: | Excited |
Samples: |
US$ 10/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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Can you explain the role of magnetic fields in the operation of brushless motors?
In brushless motors, magnetic fields play a crucial role in the motor’s operation. These magnetic fields are generated by permanent magnets and electromagnets within the motor. Here’s a detailed explanation of the role of magnetic fields in brushless motors:
1. Permanent Magnets:
Brushless motors typically incorporate permanent magnets, often made of rare-earth materials like neodymium, in the rotor or the outer shell (stator) of the motor. These magnets create a steady magnetic field that interacts with the electromagnets in the motor’s stator. The permanent magnets establish a fixed magnetic flux pattern and provide a source of magnetic energy in the motor. The strength and arrangement of the permanent magnets determine the motor’s torque and power characteristics.
2. Electromagnets:
The stator of a brushless motor contains electromagnets, which are typically made of copper wire coils wound around iron cores. When an electric current flows through these coils, they generate magnetic fields. The interaction between the magnetic fields of the permanent magnets and the electromagnets is what enables the motor’s operation. By controlling the current flowing through the stator coils, the magnetic fields can be manipulated to produce rotational motion in the motor.
3. Magnetic Field Alignment:
The primary goal of the magnetic fields in a brushless motor is to achieve proper alignment between the rotor and the stator. As the magnetic fields interact, they create forces that cause the rotor to move in a rotational manner. The stator’s electromagnets generate magnetic fields that attract or repel the permanent magnets on the rotor, causing the rotor to rotate. By sequentially energizing different electromagnets in the stator, the magnetic field alignment is continuously adjusted, resulting in continuous rotation of the rotor.
4. Commutation:
In order to maintain the rotational motion, brushless motors employ a technique called commutation. Commutation involves switching the current flow to different stator coils at specific times during the rotation. This switching is coordinated with the position of the rotor to ensure smooth and continuous rotation. By changing the magnetic field orientation in the stator, the rotor is constantly pulled or pushed to follow the rotating magnetic field, allowing the motor to generate torque and maintain its rotational motion.
5. Sensor Feedback:
In some brushless motors, position sensors, such as Hall effect sensors or encoders, are used to provide feedback on the rotor’s position. These sensors detect the magnetic field changes as the rotor rotates and provide information to the motor controller. The motor controller uses this feedback to accurately determine the timing and sequence of stator coil energization, ensuring precise commutation and optimal motor performance.
6. Efficiency and Control:
The proper alignment and control of magnetic fields in brushless motors contribute to their efficiency and control characteristics. By using permanent magnets and carefully designed stator electromagnets, brushless motors can achieve high power density, reduced energy losses, and improved overall efficiency. Additionally, the ability to control the magnetic fields through precise commutation and feedback allows for precise speed control, torque control, and position control in various applications.
In summary, magnetic fields play a fundamental role in the operation of brushless motors. The interaction between permanent magnets and electromagnets, along with proper commutation and control, enables the conversion of electrical energy into rotational motion. Understanding and manipulating magnetic fields are essential for optimizing the performance, efficiency, and control of brushless motors in a wide range of applications.
What types of sensors are commonly used in brushless motors for feedback and control?
In brushless motors, various types of sensors are commonly used for feedback and control purposes. These sensors provide essential data to monitor and control the motor’s position, speed, and other parameters. Here are some of the commonly used sensors in brushless motors:
1. Hall Effect Sensors:
Hall effect sensors are widely used in brushless motors for commutation control. Typically, three Hall effect sensors are positioned around the motor’s stator to detect the position of the rotor’s permanent magnets. By sensing the magnetic field changes, the Hall effect sensors determine the rotor’s position relative to the stator. This information is crucial for the motor’s electronic controller to apply the correct current to the motor’s windings and ensure proper commutation.
2. Encoder Sensors:
Encoders are commonly employed in brushless motors for precise position control. There are two main types of encoders used: optical encoders and magnetic encoders. Optical encoders use an optical disc with patterns and a light-emitting diode (LED) and photodetector to detect the rotation of the motor’s shaft. Magnetic encoders, on the other hand, utilize magnetic fields and sensors to measure the shaft’s position. Encoders provide high-resolution position feedback and enable accurate closed-loop control of the motor’s position.
3. Resolver Sensors:
Resolvers are another type of position sensor used in brushless motors. They consist of a rotor and a stator with windings. As the rotor rotates, the resolver measures the angular position by detecting the voltages induced in the stator windings. Resolvers are known for their durability and resistance to harsh environmental conditions, making them suitable for various industrial applications.
4. Current Sensors:
Current sensors are used to measure the current flowing through the motor’s windings. They provide feedback on the motor’s electrical load and enable monitoring of the motor’s torque output. Current sensors can be based on different principles, such as Hall effect, shunt resistors, or current transformers. By measuring the motor’s current, the control system can adjust the motor’s performance and protect it from overcurrent conditions.
5. Temperature Sensors:
Temperature sensors are utilized to monitor the motor’s temperature and prevent overheating. These sensors can be thermocouples, thermistors, or integrated temperature sensors. By continuously monitoring the motor’s temperature, the control system can adjust the motor’s operation, activate cooling mechanisms, or trigger alarms and shutdowns if the temperature exceeds safe limits.
6. Speed Sensors:
Speed sensors are employed to measure the rotational speed of the motor. They provide feedback on the motor’s speed and enable closed-loop speed control. Speed sensors can be optical or magnetic, relying on the detection of changes in position or magnetic field patterns to determine the motor’s speed.
The specific combination and utilization of these sensors depend on the motor’s design, control system requirements, and application needs. By using these sensors, brushless motors can achieve precise control, accurate position feedback, and efficient operation, making them suitable for a wide range of applications in industries such as automotive, robotics, aerospace, and industrial automation.
What are the primary advantages of using brushless motors in various applications?
Brushless motors offer several advantages that make them preferred choices in various applications. Here are the primary advantages of using brushless motors:
1. High Efficiency:
Brushless motors are known for their high efficiency. The absence of brushes and commutators reduces friction and electrical losses, resulting in improved power conversion and energy efficiency. This efficiency translates into lower power consumption, reduced heat generation, and longer battery life in battery-powered applications. High efficiency makes brushless motors suitable for applications where energy efficiency is crucial, such as electric vehicles, renewable energy systems, and battery-operated devices.
2. Increased Reliability:
Brushless motors offer increased reliability compared to brushed motors. The lack of brushes and commutators eliminates common points of failure in brushed motors. Brushes can wear out and require periodic replacement, while commutators can experience electrical arcing and wear. By removing these components, brushless motors have longer lifespans, reduced maintenance requirements, and higher overall reliability. This advantage is particularly important in critical applications where downtime and maintenance costs must be minimized.
3. Precise Speed and Position Control:
Brushless motors provide precise speed and position control, making them suitable for applications that require accurate motion control. The electronic commutation in brushless motors allows for precise monitoring and adjustment of motor parameters, such as speed, torque, and direction. This level of control enables smooth and precise movements, making brushless motors ideal for robotics, CNC machines, automation systems, and other applications that demand precise positioning and motion control.
4. Compact Size and High Power Density:
Brushless motors have a compact design and high power density, making them suitable for applications where space is limited. The absence of brushes and commutators allows for a more streamlined motor design, reducing the overall size and weight of the motor. This compact size makes brushless motors ideal for applications with size constraints, such as drones, portable devices, and small appliances. Despite their compact size, brushless motors can deliver high power output, making them capable of driving demanding applications.
5. Reduced Electromagnetic Interference (EMI):
Brushless motors generate less electromagnetic interference (EMI) compared to brushed motors. The electronic commutation in brushless motors produces smoother and more controlled current waveforms, resulting in reduced EMI. This advantage is particularly important in applications where EMI can interfere with sensitive electronics or cause electromagnetic compatibility (EMC) issues. Brushless motors are commonly used in medical equipment, telecommunications, and audio/video equipment, where minimizing EMI is critical.
6. Higher Speed and Acceleration Capability:
Brushless motors offer higher speed and acceleration capabilities compared to brushed motors. The absence of brushes reduces friction and allows brushless motors to achieve higher rotational speeds. Additionally, the electronic commutation enables faster switching and control, resulting in faster acceleration and deceleration. These characteristics make brushless motors suitable for applications that require rapid movements, high-speed operation, and quick response times, such as robotics, industrial automation, and electric vehicles.
These advantages make brushless motors a preferred choice in a wide range of applications, including robotics, electric vehicles, aerospace, industrial automation, medical equipment, consumer electronics, and more. Their high efficiency, reliability, precise control, compact size, reduced EMI, and high-speed capabilities contribute to improved performance and enable innovative designs in various industries.
editor by CX 2024-05-17
China Best Sales 5V 12V DC Electric Speed Gear Stepper Motor vacuum pump ac system
Product Description
Product Description
Our company is an advanced leading Chinese manufacturer and supplier, which provides high performance products and efficient international services to the world.we focus on producting varies kinds of reduction stepper motors,synchronous motors,micro water pumps,which are widely used in air-conditioner,refrigerator,intelligent sanitary,automatic door lock,monitor,electronic instruments.All of our products can be customized.
Our stepper motors are used widely in the valve control system,air-condetioner,sanitary ware,CCTV monitoring system,industrial automation control,and other industries.Following is the parameters of the 30BYJ46 stepper motor:
1 rated voltage: DC 12V
2 step: 7.5 ~ /85
3 reduction ratio: 1/85
4 output torque: > 78.4mN.m
5 self positioning torque: > 49mN.m
6 noise: “40dB”
Huayang stepper motor products are widely used in the fields of household appliances,cleaning equipment,pump products and industrial automation,such as air condioner,washing machines,dishwashers ,vacuum cleaners,etc.
With the improvement of living standards, more and more families get surveillance camera. The corresponding surveillance camera motor market is developing rapidly.
Performance Parameters
Model | Voltage V |
Resistance (Q)/Phase (at 25ºC) (Ω) |
Operating Frequenc (PPS) |
Pull-in Torque (mN.m) 100PPS |
Detent Torque (mN.m) |
Max. Freeload Pull-in (PPS) |
Max. Freeload Pull-out Frequency (PPS) |
Temperature Rise K |
Noise dB (A) |
Step Angle (1-2Phase) |
nsulation Class |
30BYJ46 | 12 | 110 | 100 | ≥98 | ≥78.4 | ≥350 | ≥800 | ≤ 50 | ≤40 | 7.5°/85.25 | E |
12 | 130 | 100 | ≥78.4 | ≥39.2 | ≥350 | ≥800 | ≤50 | ≤40 | |||
12 | 200 | 100 | ≥58.8 | ≥39.7 | ≥350 | ≥600 | ≤50 | ≤40 |
Mechanical Dimensions:mm
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Application: | Home Applications |
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Speed: | Low Speed |
Number of Stator: | Three-Phase |
Excitation Mode: | PM-Permanent Magnet |
Function: | Control, Driving |
Number of Poles: | 12 |
Customization: |
Available
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What factors should be considered when selecting the right electric motor for a task?
When selecting the right electric motor for a task, several factors need to be considered to ensure optimal performance and compatibility. Here’s a detailed overview of the factors that should be taken into account:
- Load Requirements: The first consideration is understanding the specific load requirements of the task. This includes factors such as the torque or force needed to drive the load, the speed range required, and any variations in load that may occur. By accurately assessing the load requirements, you can determine the appropriate motor type, size, and characteristics needed to handle the task effectively.
- Motor Type: Different motor types are suited for specific applications. Common motor types include AC induction motors, brushless DC motors, brushed DC motors, and stepper motors. Each type has its own advantages and limitations in terms of speed range, torque characteristics, efficiency, control requirements, and cost. Choosing the right motor type depends on the task’s specific requirements and the desired performance.
- Power Supply: Consider the available power supply for the motor. Determine whether the application requires AC or DC power and the voltage and frequency range of the power source. Ensure that the motor’s power requirements align with the available power supply to avoid compatibility issues.
- Efficiency and Energy Consumption: Efficiency is an important factor to consider, especially for applications where energy consumption is a concern. Higher motor efficiency translates to lower energy losses and reduced operating costs over the motor’s lifetime. Look for motors with high efficiency ratings to minimize energy consumption and improve overall system efficiency.
- Environmental Factors: Assess the environmental conditions in which the motor will operate. Consider factors such as temperature, humidity, dust, and vibration. Some motors are specifically designed to withstand harsh environmental conditions, while others may require additional protection or enclosures. Choosing a motor that is suitable for the intended environment will ensure reliable and long-lasting operation.
- Control and Feedback Requirements: Determine whether the application requires precise control over motor speed, position, or torque. Some tasks may benefit from closed-loop control systems that incorporate feedback devices like encoders or sensors to provide accurate motor control. Evaluate the control and feedback requirements of the task and select a motor that is compatible with the desired control mechanism.
- Physical Constraints: Consider any physical constraints or limitations that may impact motor selection. These constraints may include space restrictions, weight limitations, mounting options, and mechanical compatibility with other components or equipment. Ensure that the chosen motor can physically fit and integrate into the system without compromising performance or functionality.
- Cost and Budget: Finally, consider the budget and cost constraints associated with the motor selection. Evaluate the initial purchase cost of the motor as well as the long-term operating costs, including maintenance and energy consumption. Strive to strike a balance between performance and cost-effectiveness to ensure the best value for your specific application.
By considering these factors, you can make an informed decision when selecting the right electric motor for a task. It is crucial to thoroughly analyze the requirements and match them with the motor’s specifications to achieve optimal performance, reliability, and efficiency.
How do electric motors impact the overall productivity of manufacturing processes?
Electric motors have a significant impact on the overall productivity of manufacturing processes. Their versatility, reliability, and efficiency make them essential components in a wide range of industrial applications. Here’s a detailed explanation of how electric motors contribute to enhancing productivity in manufacturing:
- Mechanization and Automation: Electric motors serve as the primary power source for a vast array of industrial machinery and equipment. By providing mechanical power, electric motors enable mechanization and automation of manufacturing processes. They drive conveyor belts, pumps, compressors, robots, and other machinery, allowing for efficient material handling, assembly, and production operations. The use of electric motors in mechanized and automated systems reduces manual labor, accelerates production rates, and improves overall productivity.
- Precise Control and Repeatable Movements: Electric motors offer precise control over speed, position, and torque, enabling accurate and repeatable movements in manufacturing processes. This precision is crucial for tasks that require consistent and controlled operations, such as precision cutting, drilling, machining, and assembly. Electric motors allow for fine adjustments and control, ensuring that manufacturing operations are performed with high levels of accuracy and repeatability, which ultimately enhances productivity and product quality.
- High Speed and Acceleration: Electric motors are capable of achieving high rotational speeds and rapid acceleration, enabling fast-paced manufacturing processes. Motors with high-speed capabilities are utilized in applications that require quick operations, such as high-speed machining, packaging, and sorting. The ability of electric motors to rapidly accelerate and decelerate facilitates efficient cycle times and overall process throughput, contributing to increased productivity.
- Reliability and Durability: Electric motors are known for their reliability and durability, making them well-suited for demanding manufacturing environments. With proper maintenance, electric motors can operate continuously for extended periods, minimizing downtime due to motor failures. The reliability of electric motors ensures consistent and uninterrupted production, optimizing manufacturing productivity and reducing costly disruptions.
- Energy Efficiency: Electric motors have witnessed significant advancements in energy efficiency, leading to reduced energy consumption in manufacturing processes. Energy-efficient motors convert a higher percentage of electrical input power into useful mechanical output power, resulting in lower energy costs. By utilizing energy-efficient electric motors, manufacturers can achieve cost savings and improve the overall sustainability of their operations. Additionally, energy-efficient motors generate less heat, reducing the need for cooling and improving the overall efficiency of auxiliary systems.
- Integration with Control Systems: Electric motors can be seamlessly integrated with sophisticated control systems and automation technologies. This integration allows for centralized control, monitoring, and optimization of manufacturing processes. Control systems can regulate motor speed, torque, and performance based on real-time data, enabling adaptive and efficient operations. The integration of electric motors with control systems enhances the overall productivity by optimizing process parameters, minimizing errors, and facilitating seamless coordination between different stages of manufacturing.
Electric motors significantly impact the overall productivity of manufacturing processes by enabling mechanization, automation, precise control, high-speed operations, reliability, energy efficiency, and integration with advanced control systems. Their versatility and performance characteristics make them indispensable in a wide range of industries, including automotive, electronics, aerospace, food processing, and more. By harnessing the power of electric motors, manufacturers can streamline operations, improve product quality, increase throughput, and ultimately enhance productivity in their manufacturing processes.
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 supplier The Three Phase Induction Motor AC Gear Motor 60 Rpm General Electric AC Motor vacuum pump belt
Product Description
The Three Phase Induction Motor Ac Gear Motor 60 Rpm General Electric Ac Motor
Motor type | Induction motor, brake motor, torque motor, speed adjustable motor, reversible motor |
Frame size | 60 mm, 70mm, 80mm, 90mm, 104mm |
Motor Output speed | 1250rpm – 1500rpm |
Gearbox Speed Ratio | 1:3 – 1: 500
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Output power | 60mm: 6W, 10W
70mm: 15W, 20W 80mm: 25W, 30W 90mm: 40W, 60W, 80W, 90W,120W 104mm: 140W, 200W, 250W, 370W |
Output shaft | 8mm ~ 50mm; round shaft, D-cut shaft, key-way shaft, hollow shaft |
Voltage | 110v, 220v, 230v, 380v |
Phase | 1 phase, 3 phase |
Frequency | 50Hz, 60Hz |
If you need any customized AC or DC motors, pls freely contact us. We shall reply soon. |
Greensky Product Category
About CHINAMFG Power
Greensky Power Company Limited is a Chinabased international company who is specialized in electric motor, gearbox and controlling system developing, manufacturing, quality controlling and trading.
Mission:
We are dedicated to develop an international electric motor company who can deliver one-stop reliable products with customer-oriented service.
History:
Greensky was established in 2571 by CHINAMFG Cheng in Los Angeles, USA and moved to HangZhou, China in 2011. In the past 8 years, the team of CHINAMFG continues to create the value to our esteemed customers all over the world by building up wide and reliable supply chain management system, effective quality & delivery time control system, cost efficiency manufacturing system and fast-respond professional service.
Location: Xihu (West Lake) Dis. district, HangZhou, China
Xihu (West Lake) Dis. is a high-tech zone which is the center of oversea Chinese talent entrepreneurs. Some famous neighbours include Alibaba, Netease and Geely corporation.
Background:
Greensky is a subsidiary of EagleEye Capital Limited who has 3 manufacturing plants and 1 sales office with more than 500 employees and overall 200 million sales.
Company Facilities
Certificates
Overseas Exhibitions
FAQ:
1 Q: What’s your MOQ ?
A: 1unit is acceptable.
2 Q: What about your warranty?
A: 1-2 years.
3 Q: Do you provide OEM service with customer-logo?
A: Yes, we could do OEM orders.
4 Q: How about your payment terms ?
A: TT, western union and paypal. 100% payment in advanced for orders less $10,000. 30% deposit and balance before delivery for orders over $10,000.
5 Q: How about your packing ?
A: Carton, Plywood case and foam inside. If you need more, we can pack all goods with pallet
6 Q: What information should be given in the inquiry?
A: Rated power, gearbox ratio, input speed, mounting position. More details, better!
7 Q: How do you deliver our order?
A: We will compare and choose the most suitable ways of delivery by sea, air or express courier.
Welcome your inquiry! We’re always at your service.
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Application: | Industrial |
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Speed: | Variable Speed |
Number of Stator: | Single-Phase |
Function: | Driving, Control |
Casing Protection: | Protection Type |
Number of Poles: | 4 |
Samples: |
US$ 100/Piece
1 Piece(Min.Order) | |
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Customization: |
Available
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What types of feedback mechanisms are commonly integrated into gear motors for control?
Gear motors often incorporate feedback mechanisms to provide control and improve their performance. These feedback mechanisms enable the motor to monitor and adjust its operation based on various parameters. Here are some commonly integrated feedback mechanisms in gear motors:
1. Encoder Feedback:
An encoder is a device that provides position and speed feedback by converting the motor’s mechanical motion into electrical signals. Encoders commonly used in gear motors include:
- Incremental Encoders: These encoders provide information about the motor’s shaft position and speed relative to a reference point. They generate pulses as the motor rotates, allowing precise measurement of position and speed changes.
- Absolute Encoders: Absolute encoders provide the precise position of the motor’s shaft within a full revolution. They do not require a reference point and provide accurate feedback even after power loss or motor restart.
2. Hall Effect Sensors:
Hall effect sensors use the principle of the Hall effect to detect the presence and strength of a magnetic field. They are commonly used in gear motors for speed and position sensing. Hall effect sensors provide feedback by detecting changes in the motor’s magnetic field and converting them into electrical signals.
3. Current Sensors:
Current sensors monitor the electrical current flowing through the motor’s windings. By measuring the current, these sensors provide feedback regarding the motor’s torque, load conditions, and power consumption. Current sensors are essential for motor control strategies such as current limiting, overcurrent protection, and closed-loop control.
4. Temperature Sensors:
Temperature sensors are integrated into gear motors to monitor the motor’s temperature. They provide feedback on the motor’s thermal conditions, allowing the control system to adjust the motor’s operation to prevent overheating. Temperature sensors are crucial for ensuring the motor’s reliability and preventing damage due to excessive heat.
5. Hall Effect Limit Switches:
Hall effect limit switches are used to detect the presence or absence of a magnetic field within a specific range. They are commonly employed as end-of-travel or limit switches in gear motors. Hall effect limit switches provide feedback to the control system, indicating when the motor has reached a specific position or when it has moved beyond the allowed range.
6. Resolver Feedback:
A resolver is an electromagnetic device used to determine the position and speed of a rotating shaft. It provides feedback by generating sine and cosine signals that correspond to the shaft’s angular position. Resolver feedback is commonly used in high-performance gear motors requiring accurate position and speed control.
These feedback mechanisms, when integrated into gear motors, enable precise control, monitoring, and adjustment of various motor parameters. By utilizing feedback signals from encoders, Hall effect sensors, current sensors, temperature sensors, limit switches, or resolvers, the control system can optimize the motor’s performance, ensure accurate positioning, maintain speed control, and protect the motor from excessive loads or overheating.
Are there environmental benefits to using gear motors in certain applications?
Yes, there are several environmental benefits associated with the use of gear motors in certain applications. Gear motors offer advantages that can contribute to increased energy efficiency, reduced resource consumption, and lower environmental impact. Here’s a detailed explanation of the environmental benefits of using gear motors:
1. Energy Efficiency:
Gear motors can improve energy efficiency in various ways:
- Torque Conversion: Gear reduction allows gear motors to deliver higher torque output while operating at lower speeds. This enables the motor to perform tasks that require high torque, such as lifting heavy loads or driving machinery with high inertia, more efficiently. By matching the motor’s power characteristics to the load requirements, gear motors can operate closer to their peak efficiency, minimizing energy waste.
- Controlled Speed: Gear reduction provides finer control over the motor’s rotational speed. This allows for more precise speed regulation, reducing the likelihood of energy overconsumption and optimizing energy usage.
2. Reduced Resource Consumption:
The use of gear motors can lead to reduced resource consumption and environmental impact:
- Smaller Motor Size: Gear reduction allows gear motors to deliver higher torque with smaller, more compact motors. This reduction in motor size translates to reduced material and resource requirements during manufacturing. It also enables the use of smaller and lighter equipment, which can contribute to energy savings during operation and transportation.
- Extended Motor Lifespan: The gear mechanism in gear motors helps reduce the load and stress on the motor itself. By distributing the load more evenly, gear motors can help extend the lifespan of the motor, reducing the need for frequent replacements and the associated resource consumption.
3. Noise Reduction:
Gear motors can contribute to a quieter and more environmentally friendly working environment:
- Noise Dampening: Gear reduction can help reduce the noise generated by the motor. The gear mechanism acts as a noise dampener, absorbing and dispersing vibrations and reducing overall noise emission. This is particularly beneficial in applications where noise reduction is important, such as residential areas, offices, or noise-sensitive environments.
4. Precision and Control:
Gear motors offer enhanced precision and control, which can lead to environmental benefits:
- Precise Positioning: Gear motors, especially stepper motors and servo motors, provide precise positioning capabilities. This accuracy allows for more efficient use of resources, minimizing waste and optimizing the performance of machinery or systems.
- Optimized Control: Gear motors enable precise control over speed, torque, and movement. This control allows for better optimization of processes, reducing energy consumption and minimizing unnecessary wear and tear on equipment.
In summary, using gear motors in certain applications can have significant environmental benefits. Gear motors offer improved energy efficiency, reduced resource consumption, noise reduction, and enhanced precision and control. These advantages contribute to lower energy consumption, reduced environmental impact, and a more sustainable approach to power transmission and control. When selecting motor systems for specific applications, considering the environmental benefits of gear motors can help promote energy efficiency and sustainability.
Are there specific considerations for selecting the right gear motor for a particular application?
When selecting a gear motor for a specific application, several considerations need to be taken into account. The choice of the right gear motor is crucial to ensure optimal performance, efficiency, and reliability. Here’s a detailed explanation of the specific considerations for selecting the right gear motor for a particular application:
1. Torque Requirement:
The torque requirement of the application is a critical factor in gear motor selection. Determine the maximum torque that the gear motor needs to deliver to perform the required tasks. Consider both the starting torque (the torque required to initiate motion) and the operating torque (the torque required to sustain motion). Select a gear motor that can provide adequate torque to handle the load requirements of the application. It’s important to account for any potential torque spikes or variations during operation.
2. Speed Requirement:
Consider the desired speed range or specific speed requirements of the application. Determine the rotational speed (in RPM) that the gear motor needs to achieve to meet the application’s performance criteria. Select a gear motor with a suitable gear ratio that can achieve the desired speed at the output shaft. Ensure that the gear motor can maintain the required speed consistently and accurately throughout the operation.
3. Duty Cycle:
Evaluate the duty cycle of the application, which refers to the ratio of operating time to rest or idle time. Consider whether the application requires continuous operation or intermittent operation. Determine the duty cycle’s impact on the gear motor, including factors such as heat generation, cooling requirements, and potential wear and tear. Select a gear motor that is designed to handle the expected duty cycle and ensure long-term reliability and durability.
4. Environmental Factors:
Take into account the environmental conditions in which the gear motor will operate. Consider factors such as temperature extremes, humidity, dust, vibrations, and exposure to chemicals or corrosive substances. Choose a gear motor that is specifically designed to withstand and perform optimally under the anticipated environmental conditions. This may involve selecting gear motors with appropriate sealing, protective coatings, or materials that can resist corrosion and withstand harsh environments.
5. Efficiency and Power Requirements:
Consider the desired efficiency and power consumption of the gear motor. Evaluate the power supply available for the application and select a gear motor that operates within the specified voltage and current ranges. Assess the gear motor’s efficiency to ensure that it maximizes power transmission and minimizes wasted energy. Choosing an efficient gear motor can contribute to cost savings and reduced environmental impact.
6. Physical Constraints:
Assess the physical constraints of the application, including space limitations, mounting options, and integration requirements. Consider the size, dimensions, and weight of the gear motor to ensure it can be accommodated within the available space. Evaluate the mounting options and compatibility with the application’s mechanical structure. Additionally, consider any specific integration requirements, such as shaft dimensions, connectors, or interfaces that need to align with the application’s design.
7. Noise and Vibration:
Depending on the application, noise and vibration levels may be critical factors. Evaluate the acceptable noise and vibration levels for the application’s environment and operation. Choose a gear motor that is designed to minimize noise and vibration, such as those with helical gears or precision engineering. This is particularly important in applications that require quiet operation or where excessive noise and vibration may cause issues or discomfort.
By considering these specific factors when selecting a gear motor for a particular application, you can ensure that the chosen gear motor meets the performance requirements, operates efficiently, and provides reliable and consistent power transmission. It’s important to consult with gear motor manufacturers or experts to determine the most suitable gear motor based on the specific application’s needs.
editor by CX 2024-05-16
China Professional Mini Electric Motor with Low Rpm N20 Mini Micro Metal Gear Motor wholesaler
Product Description
Product Description
HangZhou Xihu (West Lake) Dis. Motor Co., Ltd.
Specializing in high-quality N10, N20, N30 motors and gearboxes made of durable steel material for longevity and wear-resistance.
Key Features:
- High performance lock-in current: 1.6A (HP)
- Medium performance lock-in current: 0.7A (MP)
- Low performance lock-in current: 0.36A (LP)
- Voltage range: 3V to 12V
- Gearbox ratios: 1:5 to 1:1000
- Compliance with CE, RoHS, and other EU requirements
- Equipped with rear shaft and 12PPR encoder
- Choice of precious metal brushes or carbon brushes
- Insulated and coated rotor for added protection
Applicati
Perfect for door locks, shared bicycles, robots, automatic curtains, household appliances, medical devices, and more.
High Power Version (HP):
- Stall current: 1.6A
- Available with 12CPR without encoder
- Option for back shaft
- Choice of metal brush or carbon brush
Model | Voltage
Unit: VDC |
No load speed
Unit: rpm |
Noload current
Unit: mA |
Stall torque
Unit: kg.cm |
Gear ratio |
N20H5 | 6V/12V | 6000 rpm | 120/60mA | 0.1 kg.cm | 5:1 |
N20H10 | 6V/12V | 3000 rpm | 120/60mA | 0.2 kg.cm | 10:1 |
N20H20 | 6V/12V | 1500 rpm | 120/60mA | 0.4 kg.cm | 20:1 |
N20H30 | 6V/12V | 1000 rpm | 120/60mA | 0.6 kg.cm | 30:1 |
N20H50 | 6V/12V | 625 rpm | 120/60mA | 1.0 kg.cm | 50:1 |
N20H75 | 6V/12V | 400 rpm | 120/60mA | 1.5 kg.cm | 75:1 |
N20H100 | 6V/12V | 320 rpm | 120/60mA | 2.0 kg.cm | 100:1 |
N20H150 | 6V/12V | 200 rpm | 120/60mA | 3.0 kg.cm | 150:1 |
N20H210 | 6V/12V | 140 rpm | 120/60mA | 3.6 kg.cm | 210:1 |
N20H250 | 6V/12V | 120 rpm | 120/60mA | 4.2 kg.cm | 250:1 |
N20H298 | 6V/12V | 100 rpm | 120/60mA | 5.0 kg.cm | 298:1 |
N20H380 | 6V/12V | 78 rpm | 120/60mA | 6.3 kg.cm | 380:1 |
N20H1000 | 6V/12V | 32 rpm | 120/60mA | 9.0 kg.cm | 1000:1 |
Introducing our Micro DC Gear Motor with Encoder from HangZhou Xihu (West Lake) Dis. Motor Co., Ltd. This motor boasts a compact 12mm diameter, providing high torque for a wide range of applications. With options for a 0.7A stall current, this motor is perfect for projects requiring precision and power.
Model | Voltage
Unit: VDC |
No load speed
Unit: rpm |
Noload current
Unit: mA |
Stall torque
Unit: kg.cm |
Gear ratio |
N20M5 | 6V/12V | 4400 rpm | 40/20mA | 0.1kg.cm | 5:1 |
N20M10 | 6V/12V | 2200 rpm | 40/20mA | 0.2 kg.cm | 10:1 |
N20M20 | 6V/12V | 1100 rpm | 40/20mA | 0.4 kg.cm | 20:1 |
N20M30 | 6V/12V | 730 rpm | 40/20mA | 0.5 kg.cm | 30:1 |
N20M50 | 6V/12V | 420 rpm | 40/20mA | 0.8 kg.cm | 50:1 |
N20M75 | 6V/12V | 290 rpm | 40/20mA | 1.2 kg.cm | 75:1 |
N20M100 | 6V/12V | 220 rpm | 40/20mA | 1.5 kg.cm | 100:1 |
N20M150 | 6V/12V | 150 rpm | 40/20mA | 1.7 kg.cm | 150:1 |
N20M210 | 6V/12V | 100 rpm | 40/20mA | 2.4 kg.cm | 210:1 |
N20M250 | 6V/12V | 90 rpm | 40/20mA | 2.8 kg.cm | 250:1 |
N20M298 | 6V/12V | 75 rpm | 40/20mA | 3.3 kg.cm | 298:1 |
N20M380 | 6V/12V | 58 rpm | 40/20mA | 4.2 kg.cm | 380:1 |
N20M1000 | 6V/12V | 22 rpm | 40/20mA | 6.0 kg.cm | 1000:1 |
Introducing the 12mm DC Gear Motor Encoder from HangZhou Xihu (West Lake) Dis. Motor Co., Ltd. This motor boasts a low power consumption of 0.36A stall current and offers customizable options including encoder type, back shaft, and brush material. Versatile and efficient, this motor is perfect for a wide range of applicati
HangZhou Xihu (West Lake) Dis. Motor Co., Ltd.
Specializing in high-quality N10, N20, N30 motors and gearboxes. The gearbox cover plate is made of durable steel material.
Key Features:
- High performance lock-in current: 1.6A
- Medium performance lock-in current: 0.7A
- Low performance lock-in current: 0.36A
- Versatile motors with voltage ranging from 3V to 12V
- Gearbox ratios from 1:5 to 1:1000
- CE, RoHS, and other EU requirements compliant
- Equipped with rear shaft and 12PPR encoder
- Precious metal brush or carbon brush options
- Insulated and coated rotoR
Applications:
- Door locks
- Shared bicycles
- Robots
- Automatic curtains
- Household appliances
- Medical devices
Certifications
Discover the 12mm Diameter DC Gear Motor Encoder by HangZhou Xihu (West Lake) Dis. Motor Co., Ltd. Perfect for compact high torque applications.
Company Profile
FAQ
/* 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: | DC Gear Motor |
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Operating Speed: | Low Speed |
Excitation Mode: | Excited |
Function: | Driving |
Casing Protection: | Open Type |
Number of Poles: | 2 |
Customization: |
Available
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How can individuals troubleshoot common issues related to micro gear motor performance?
When encountering common issues related to micro gear motor performance, individuals can follow these troubleshooting steps:
- Check Power Supply: Ensure that the micro gear motor is receiving an adequate power supply. Verify the voltage and current levels are within the motor’s specifications. Check for loose connections, damaged cables, or faulty power sources.
- Inspect Mechanical Components: Examine the mechanical components of the micro gear motor, including gears, bearings, and shafts. Look for signs of wear, damage, or misalignment. Lubricate the gears and bearings if necessary. Tighten any loose screws or fasteners.
- Verify Control Signals: If the micro gear motor is controlled electronically, check the control signals. Ensure that the motor is receiving the correct signals and that the control circuitry is functioning properly. Test the motor with different control inputs to verify its response.
- Check for Overheating: Overheating can adversely affect micro gear motor performance. Monitor the motor’s temperature during operation. If it becomes excessively hot, check for proper ventilation and cooling. Remove any obstructions that may impede airflow around the motor.
- Inspect Wiring and Connections: Examine the wiring and connections of the micro gear motor. Look for loose or damaged wires, poor solder joints, or faulty connectors. Ensure that all electrical connections are secure and properly insulated.
- Review Motor Specifications: Refer to the motor’s specifications and documentation. Compare the operating conditions and requirements with the actual operating parameters. Ensure that the motor is being used within its specified limits regarding voltage, current, temperature, and load.
- Clean the Motor: Dust, debris, or contaminants can affect the performance of micro gear motors. Clean the motor and its components using appropriate methods and materials. Be careful not to damage any sensitive parts during the cleaning process.
- Seek Professional Assistance: If the troubleshooting steps do not resolve the issues or if the problems persist, it may be necessary to seek professional assistance. Contact the manufacturer, consult technical support, or seek the expertise of a qualified technician who specializes in micro gear motors.
By following these troubleshooting steps, individuals can diagnose and address common issues related to micro gear motor performance. It is important to approach troubleshooting with caution and adhere to safety guidelines to prevent further damage or injury.
What factors should be considered when selecting a micro gear motor for a particular application?
When selecting a micro gear motor for a particular application, several important factors should be taken into consideration. These factors help ensure that the chosen motor meets the specific requirements of the application and performs optimally. Here are the key factors to consider:
1. Torque Requirement:
Determine the torque requirements of the application. Consider both the maximum torque needed and the continuous torque required for sustained operation. Select a micro gear motor that can deliver the required torque output while considering factors such as load variations, start-up torque, and intermittent peak torque demands.
2. Speed Requirement:
Consider the desired speed range for the application. Determine the required output speed of the micro gear motor to ensure that it can meet the speed requirements of the specific task. It is important to select a motor with an appropriate gear ratio that can achieve the desired speed while considering the motor’s inherent speed limitations.
3. Power Supply:
Take into account the available power supply for the micro gear motor. Consider the voltage and current requirements of the motor and ensure compatibility with the available power source. Additionally, consider the power consumption and efficiency of the motor to optimize energy usage and minimize heat generation.
4. Physical Size and Mounting:
Consider the physical size and mounting requirements of the micro gear motor. Evaluate the available space for installation and ensure that the motor dimensions fit within the allotted space. Consider the mounting options, such as through-hole mounting, flange mounting, or custom mounting brackets, and choose a motor that can be easily integrated into the application.
5. Environmental Conditions:
Assess the environmental conditions in which the micro gear motor will operate. Consider factors such as temperature range, humidity, dust, vibration, and exposure to chemicals or corrosive substances. Select a motor that is designed to withstand and perform reliably under the specific environmental conditions of the application.
6. Expected Lifetime and Reliability:
Evaluate the expected lifetime and reliability requirements of the micro gear motor. Consider the duty cycle of the application, the expected operating hours, and the required maintenance intervals. Choose a motor with a reputation for reliability and durability to ensure long-term performance without frequent breakdowns or the need for premature replacements.
7. Control and Feedback:
Consider the control and feedback requirements of the micro gear motor. Determine if the application requires specific control interfaces, such as analog or digital signals, PWM control, or communication protocols like Modbus or CAN bus. Additionally, assess whether feedback mechanisms like encoders or sensors are necessary to provide accurate position or speed control.
8. Cost and Budget:
Evaluate the cost and budget constraints for the micro gear motor. Consider the overall cost of the motor, including the initial purchase price, installation costs, and any additional accessories or components required for proper operation. Balance the desired performance and features with the available budget to select a motor that provides the best value for the specific application.
9. Supplier and Support:
Consider the reputation and support provided by the micro gear motor supplier. Choose a reliable supplier with a track record of delivering quality products and excellent customer support. Ensure that the supplier offers technical assistance, documentation, and warranty coverage to address any potential issues or concerns that may arise during the motor’s lifespan.
By considering these factors, you can make an informed decision when selecting a micro gear motor for a particular application. It is essential to carefully evaluate the requirements and characteristics of the application to choose a motor that will meet performance expectations, ensure reliability, and provide optimal functionality.
Are there specific industries or fields where micro gear motors play a crucial role?
Micro gear motors play a crucial role in various industries and fields due to their compact size, precise motion control capabilities, and efficient power transmission. Here are some specific industries and fields where micro gear motors are commonly employed:
1. Consumer Electronics:
Micro gear motors are extensively used in consumer electronics, such as smartphones, tablets, digital cameras, and wearable devices. They enable precise movements in camera autofocus, lens zooming, vibration feedback, haptic feedback, and other functions requiring controlled motion. The compact size of micro gear motors allows for integration into small electronic devices without compromising on functionality or performance.
2. Medical Devices:
In the medical field, micro gear motors find applications in various devices and equipment. They are used in surgical robots, miniature pumps for drug delivery systems, insulin pumps, prosthetic limbs, robotic exoskeletons, and lab automation devices. Micro gear motors provide precise motion control and reliable operation, contributing to the accuracy and effectiveness of medical procedures and treatments.
3. Robotics and Automation:
Micro gear motors are crucial components in robotics and automation systems. They are used in miniature robots, robotic arms, automated guided vehicles (AGVs), and industrial machinery. Micro gear motors offer high torque output and precise motion control, enabling robots and automated systems to perform intricate tasks with accuracy and efficiency.
4. Automotive:
In the automotive industry, micro gear motors play a vital role in various applications. They are used in power windows, power seats, HVAC systems, side mirror adjustments, headlight leveling mechanisms, and automatic door locks. Micro gear motors provide reliable and precise movement control for these automotive components, enhancing comfort, convenience, and safety for vehicle occupants.
5. Aerospace and Defense:
Micro gear motors are utilized in the aerospace and defense sectors for critical applications. They are incorporated into aircraft systems, satellite mechanisms, unmanned aerial vehicles (UAVs), missile guidance systems, and military equipment. The compact size, lightweight nature, and precise motion control capabilities of micro gear motors are essential for meeting the stringent requirements of these industries.
6. Industrial Equipment:
In industrial settings, micro gear motors are employed in various equipment and machinery. They are used in conveyor systems, packaging machines, printing presses, CNC machines, textile machinery, and robotic assembly lines. Micro gear motors provide reliable and efficient power transmission, allowing for precise control and automation of industrial processes.
7. Precision Instruments:
Micro gear motors are integral to precision instruments where accurate motion control is crucial. They are used in scientific instruments, laboratory equipment, optical devices, surveying instruments, and measuring devices. The precise positioning capabilities of micro gear motors contribute to the accuracy and reliability of these instruments.
8. Smart Home and IoT:
In the realm of smart homes and the Internet of Things (IoT), micro gear motors play a significant role. They are utilized in smart locks, motorized blinds and curtains, robotic vacuum cleaners, smart appliances, and home automation systems. Micro gear motors enable the automation and remote control of various household tasks, enhancing convenience and energy efficiency.
These are just a few examples of industries and fields where micro gear motors play a crucial role. Their compact size, precise motion control, and efficient power transmission capabilities make them indispensable components in numerous applications across diverse sectors.
editor by CX 2024-05-16
China supplier 6W~660W, 24V Small Electric DC Brushless Gear Motor with Best Sales
Product Description
6W~400W DC/BLDC Motor, Gear Motor
Introduction
We have both DC gear motor and Brushless dc gear motor, including 6 kinds of products. The watt is from 6W to 660W, voltage is from 6V to 220V. The feature of our motors are steady work, low rpm and high torque, low noise, high efficiency and long life.
Specification
The datasheet is 200W bldc Motor’s info as reference.
Motor Voltage 6V to 220V, Power 6W to 660W (DC/BLDC) is also can be provided.
Model | Voltage V |
Rated Power W |
No-load Parameters | Load Parameters | Motor Life H |
Motor Weight kg |
|||
Speed RPM |
Current A |
Speed RPM |
Torque N.m |
Current A |
|||||
GS5BLD200-24 | 24 | 200 | 3500 | MAX0.80 | 3000 | 0.64 | 10.5 | >5000 | 1.6 |
GS5BLD200-36 | 36 | 200 | 3400 | MAX0.65 | 3000 | 0.64 | 7.0 | >5000 | 1.6 |
GS5BLD200-48 | 48 | 200 | 3300 | MAX0.45 | 3000 | 0.64 | 5.2 | >5000 | 1.6 |
Note:
The Voltage, Power and Speed can be customized according to your request under the allowed circumstance of adoptable dimension.
View Of Item
About CHINAMFG Mechanical
- History: Greensky Mechanical was founded in 2012 with purchasing of a 15 year old cooperative factory in ZHangZhoug Province. CHINAMFG Power brought new management concept to the new joint company and increase the quality of the motors as CHINAMFG Power only provides best quality and best service to the society.
- Introduce: Greensky Mechanical Co., ltd is a subsidiary company of CHINAMFG Power which is producing micro AC and DC gear motor, small AC gear motor, precision planetary gearbox for servo motor, and it has capability to design and develop the micro motor, customized motor and precision gearbox, motor controller with high quality.
- Philosophy:We save cost by increasing the efficiency of production and delivery. “Once and forever” is our goal to serve customers in the world. Once we do business with customer, we will do business forever.
Greensky’s Advantage
On the site you can find a range of renewable products including AC/DC motor,AC Induction Motor,Reversible Motor,Blake Motor,Speed motor,AC Angel Motor,Gear Motor,Planetary Gear Box,Worm Gear Box and their relevant components.
If you have any other questions, please feel free to contact us. /* 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: | Universal, Industrial, Household Appliances, Car, Power Tools |
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Operating Speed: | Low Speed |
Excitation Mode: | Excited |
Function: | Driving |
Casing Protection: | Protection Type |
Number of Poles: | 4 |
Customization: |
Available
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How do electric motors contribute to the efficiency of tasks like transportation?
Electric motors play a significant role in enhancing the efficiency of various transportation tasks. Their unique characteristics and advantages contribute to improved performance, reduced energy consumption, and environmental benefits. Here’s a detailed explanation of how electric motors contribute to the efficiency of tasks like transportation:
- High Energy Conversion Efficiency: Electric motors are known for their high energy conversion efficiency. They can convert a large percentage of electrical energy supplied to them into mechanical energy, resulting in minimal energy losses. Compared to internal combustion engines (ICEs), electric motors can achieve significantly higher efficiencies, which translates to improved energy utilization and reduced fuel consumption.
- Instant Torque and Responsive Performance: Electric motors deliver instant torque, providing quick acceleration and responsive performance. This characteristic is particularly advantageous in transportation tasks, such as electric vehicles (EVs) and electric trains, where rapid acceleration and deceleration are required. The immediate response of electric motors enhances overall vehicle efficiency and driver experience.
- Regenerative Braking: Electric motors enable regenerative braking, a process where the motor acts as a generator to convert kinetic energy into electrical energy during deceleration or braking. This recovered energy is then stored in batteries or fed back into the power grid, reducing energy waste and extending the vehicle’s range. Regenerative braking improves overall efficiency and helps maximize the energy efficiency of electric vehicles.
- Efficient Power Distribution: Electric motors in transportation systems can be powered by electricity generated from various sources, including renewable energy. This allows for a diversified and cleaner energy mix, contributing to reduced greenhouse gas emissions and environmental impact. By utilizing electric motors, transportation tasks can leverage the increasing availability of renewable energy resources, leading to a more sustainable and efficient transport ecosystem.
- Reduced Maintenance Requirements: Electric motors have fewer moving parts compared to ICEs, resulting in reduced maintenance requirements. They eliminate the need for components like spark plugs, fuel injection systems, and complex exhaust systems. As a result, electric motors typically have longer service intervals, lower maintenance costs, and reduced downtime. This enhances operational efficiency and reduces the overall maintenance burden in transportation applications.
- Quiet and Vibration-Free Operation: Electric motors operate quietly and produce minimal vibrations compared to ICEs. This characteristic contributes to a more comfortable and pleasant passenger experience, especially in electric vehicles and electric trains. The reduced noise and vibration levels enhance the overall efficiency and comfort of transportation tasks while minimizing noise pollution in urban environments.
- Efficient Power Management and Control: Electric motors can be integrated with advanced power management and control systems. This allows for precise control over motor speed, torque, and power output, optimizing efficiency for specific transportation tasks. Intelligent control algorithms and energy management systems can further enhance the efficiency of electric motors by dynamically adjusting power delivery based on demand, driving conditions, and energy availability.
- Reduction of Emissions and Environmental Impact: Electric motors contribute to significant reductions in emissions and environmental impact compared to traditional combustion engines. By eliminating direct emissions at the point of use, electric motors help improve air quality and reduce greenhouse gas emissions. When powered by renewable energy sources, electric motors enable nearly zero-emission transportation, paving the way for a cleaner and more sustainable transportation sector.
Through their high energy conversion efficiency, instant torque, regenerative braking, efficient power distribution, reduced maintenance requirements, quiet operation, efficient power management, and environmental benefits, electric motors significantly enhance the efficiency of tasks like transportation. The widespread adoption of electric motors in transportation systems has the potential to revolutionize the industry, promoting energy efficiency, reducing reliance on fossil fuels, and mitigating environmental impact.
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 2024-05-16
China Good quality Micro AC Electric Gear AC Motor for Pellet Boiler vacuum pump
Product Description
Introduction
Our AC induction motor widely used in home appliances,Like pellet stove,biomass boilers,ovens,commerical grills,rotisseries,air fresher,blender,heater,dehumidifiers,etc.
Specification
Note:
Motor voltage, power and speed will be customized according to your request under the allowed circumstance of adoptable dimension.
View Of Item
About CHINAMFG Mechanical
- History: Greensky Mechanical was founded in 2012 with purchasing of a 15 year old cooperative factory in ZHangZhoug Province. CHINAMFG Power brought new management concept to the new joint company and increase the quality of the motors as CHINAMFG Power only provides best quality and best service to the society.
- Introduce: Greensky Mechanical Co., ltd is a subsidiary company of CHINAMFG Power which is producing micro AC and DC gear motor, small AC gear motor, precision planetary gearbox for servo motor, and it has capability to design and develop the micro motor, customized motor and precision gearbox, motor controller with high quality.
- Philosophy:We save cost by increasing the efficiency of production and delivery. “Once and forever” is our goal to serve customers in the world. Once we do business with customer, we will do business forever.
Greensky’s Advantage
On the site you can find a range of renewable products including ac/dc motor, induction motor, reversible motor, brake motor, speed control motor, ac angel motor, gear motor, planetary gearbox, worm gearbox and their relevant components.
If you have any other questions, please feel free to contact us.
/* 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: | High Speed |
Number of Stator: | Single-Phase |
Function: | Driving, Control |
Casing Protection: | Closed Type |
Number of Poles: | 4 |
Customization: |
Available
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What safety considerations should be taken into account when working with micro gear motors?
When working with micro gear motors, it is important to consider the following safety considerations:
- Electrical Safety: Micro gear motors are powered by electricity, so it is crucial to follow electrical safety practices. Ensure that the motor is properly grounded, and use appropriate insulation and protective measures to prevent electrical shock hazards. Avoid working on the motor while it is energized.
- Mechanical Hazards: Micro gear motors may have rotating components, such as shafts and gears, that can pose mechanical hazards. Take precautions to prevent accidental contact with moving parts. Use protective covers or enclosures to shield the motor, and avoid reaching into the motor assembly during operation.
- Proper Installation: Follow the manufacturer’s instructions for the correct installation of the micro gear motor. Improper installation can lead to malfunctions, increased risks, and reduced performance. Ensure that the motor is securely mounted and aligned according to the recommended guidelines.
- Overloading and Overheating: Avoid overloading the micro gear motor beyond its specified limits. Exceeding the motor’s maximum torque or operating it at excessively high temperatures can lead to performance degradation, premature wear, and potential safety hazards. Monitor the motor’s operating conditions and ensure adequate cooling to prevent overheating.
- Environmental Considerations: Consider the environmental conditions in which the micro gear motor will be operated. If the motor is exposed to moisture, dust, or extreme temperatures, choose a motor with appropriate protection ratings or implement additional protective measures, such as sealing or thermal management solutions.
- Control and Automation: When integrating micro gear motors into control systems or automation setups, ensure that the control circuits and interfaces are designed and implemented correctly. Improper wiring, incorrect signal levels, or faulty control circuits can lead to unpredictable motor behavior, safety risks, or damage to the motor and other components.
- Maintenance and Inspection: Regularly inspect and maintain the micro gear motor according to the manufacturer’s recommendations. This includes cleaning, lubrication, and checking for signs of wear or damage. Perform maintenance tasks with the motor turned off and power sources disconnected to prevent accidental activation.
- Personal Protective Equipment (PPE): Depending on the specific application and associated hazards, it may be necessary to wear appropriate personal protective equipment, such as safety glasses, gloves, or protective clothing, when working with micro gear motors. Assess the risks and adhere to safety guidelines to determine the necessary PPE.
Paying attention to these safety considerations when working with micro gear motors helps mitigate risks, ensures proper functionality, and promotes a safe working environment. It is important to familiarize oneself with the specific safety guidelines provided by the manufacturer and adhere to any local safety regulations or standards applicable to the industry or application.
How does the construction of micro gear motors contribute to their durability and longevity?
The construction of micro gear motors plays a crucial role in determining their durability and longevity. A well-designed and robust construction ensures that the motor can withstand the demands of its intended application and operate reliably over an extended period of time. Here’s a detailed explanation of how the construction of micro gear motors contributes to their durability and longevity:
1. Housing and Enclosure:
The housing and enclosure of a micro gear motor provide protection to its internal components. The housing is typically made of durable materials such as metal or high-quality plastics that can withstand mechanical stress, temperature variations, and environmental factors. The housing also helps to prevent dust, moisture, and other contaminants from entering the motor, reducing the risk of damage or malfunction. A sturdy and well-sealed housing enhances the durability and longevity of the motor by safeguarding its internal components from external influences.
2. Gear Train:
The gear train in a micro gear motor is responsible for transferring power from the motor to the output shaft. The gears are precision-engineered components that are designed to mesh smoothly and efficiently. The use of high-quality materials, such as hardened steel or engineered plastics, ensures that the gears can withstand the mechanical forces and stresses imposed during operation. Proper lubrication and maintenance of the gear train are also essential for reducing wear and extending the lifespan of the motor. A well-constructed and properly maintained gear train contributes to the overall durability and longevity of the micro gear motor.
3. Bearings:
Bearings are critical components in micro gear motors as they allow smooth rotation and support the shafts and gears. High-quality bearings, such as ball bearings or sleeve bearings, are used to minimize friction, reduce wear, and provide stable and reliable operation. The selection of bearings with appropriate load capacity and durability is crucial for ensuring the longevity of the motor. Additionally, proper lubrication and periodic maintenance of the bearings are necessary to prevent premature failure and maintain optimal performance over time.
4. Motor Windings and Cores:
The motor windings and cores are integral parts of a micro gear motor’s construction. The windings are typically made of copper or other conductive materials and are wound around a laminated core. The quality and insulation of the winding wires, as well as the core material, contribute to the motor’s efficiency and durability. High-quality windings and cores minimize energy losses, reduce heat generation, and ensure reliable electrical performance. Proper insulation and protection of the windings from mechanical stress, moisture, and temperature fluctuations are essential for the motor’s longevity.
5. Brushes and Commutator (in brushed motors):
In brushed micro gear motors, the brushes and commutator play a critical role in the motor’s construction and durability. The brushes are made of carbon or other materials with good electrical conductivity and wear resistance. They make contact with the commutator, which is a segmented copper or metal ring, to control the flow of current and generate the necessary electromagnetic forces. The brushes and commutator should be designed and manufactured to minimize wear, reduce sparking, and ensure consistent electrical contact. Regular maintenance, such as brush replacement, is necessary to maintain optimal performance and extend the lifespan of brushed micro gear motors.
6. Motor Cooling:
Efficient cooling is important for the durability and longevity of micro gear motors, especially those that operate at high speeds or under heavy loads. Motor constructions may incorporate cooling mechanisms such as fins, fans, or heat sinks to dissipate heat generated during operation. Proper cooling helps prevent overheating, which can lead to insulation breakdown, component degradation, and premature failure. Well-designed cooling systems improve the motor’s thermal management and contribute to its overall durability and longevity.
7. Quality Control and Manufacturing Processes:
The construction quality and manufacturing processes employed in the production of micro gear motors significantly impact their durability and longevity. Manufacturers that adhere to strict quality control standards, precision machining, and assembly processes produce motors with higher reliability and durability. Thorough testing, inspections, and quality assurance protocols ensure that the motors meet or exceed specified performance standards. By employing robust construction techniques and rigorous quality control measures, manufacturers can enhance the durability and longevity of micro gear motors.
In conclusion, the construction of micro gear motors directly influences their durability and longevity. A combination of factors such as sturdy housing, reliable gear train, high-quality bearings, well-designed windings and cores, optimized cooling, and adherence to quality control standards all contribute to the motor’s ability to withstand the demands of its application and operate reliably over an extended period. By selecting motors with robust constructions and performing regular maintenance, users can maximize the durability“`html
How does the construction of micro gear motors contribute to their durability and longevity?
The construction of micro gear motors plays a crucial role in determining their durability and longevity. A well-designed and robust construction ensures that the motor can withstand the demands of its intended application and operate reliably over an extended period of time. Here’s a detailed explanation of how the construction of micro gear motors contributes to their durability and longevity:
1. Housing and Enclosure:
The housing and enclosure of a micro gear motor provide protection to its internal components. The housing is typically made of durable materials such as metal or high-quality plastics that can withstand mechanical stress, temperature variations, and environmental factors. The housing also helps to prevent dust, moisture, and other contaminants from entering the motor, reducing the risk of damage or malfunction. A sturdy and well-sealed housing enhances the durability and longevity of the motor by safeguarding its internal components from external influences.
2. Gear Train:
The gear train in a micro gear motor is responsible for transferring power from the motor to the output shaft. The gears are precision-engineered components that are designed to mesh smoothly and efficiently. The use of high-quality materials, such as hardened steel or engineered plastics, ensures that the gears can withstand the mechanical forces and stresses imposed during operation. Proper lubrication and maintenance of the gear train are also essential for reducing wear and extending the lifespan of the motor. A well-constructed and properly maintained gear train contributes to the overall durability and longevity of the micro gear motor.
3. Bearings:
Bearings are critical components in micro gear motors as they allow smooth rotation and support the shafts and gears. High-quality bearings, such as ball bearings or sleeve bearings, are used to minimize friction, reduce wear, and provide stable and reliable operation. The selection of bearings with appropriate load capacity and durability is crucial for ensuring the longevity of the motor. Additionally, proper lubrication and periodic maintenance of the bearings are necessary to prevent premature failure and maintain optimal performance over time.
4. Motor Windings and Cores:
The motor windings and cores are integral parts of a micro gear motor’s construction. The windings are typically made of copper or other conductive materials and are wound around a laminated core. The quality and insulation of the winding wires, as well as the core material, contribute to the motor’s efficiency and durability. High-quality windings and cores minimize energy losses, reduce heat generation, and ensure reliable electrical performance. Proper insulation and protection of the windings from mechanical stress, moisture, and temperature fluctuations are essential for the motor’s longevity.
5. Brushes and Commutator (in brushed motors):
In brushed micro gear motors, the brushes and commutator play a critical role in the motor’s construction and durability. The brushes are made of carbon or other materials with good electrical conductivity and wear resistance. They make contact with the commutator, which is a segmented copper or metal ring, to control the flow of current and generate the necessary electromagnetic forces. The brushes and commutator should be designed and manufactured to minimize wear, reduce sparking, and ensure consistent electrical contact. Regular maintenance, such as brush replacement, is necessary to maintain optimal performance and extend the lifespan of brushed micro gear motors.
6. Motor Cooling:
Efficient cooling is important for the durability and longevity of micro gear motors, especially those that operate at high speeds or under heavy loads. Motor constructions may incorporate cooling mechanisms such as fins, fans, or heat sinks to dissipate heat generated during operation. Proper cooling helps prevent overheating, which can lead to insulation breakdown, component degradation, and premature failure. Well-designed cooling systems improve the motor’s thermal management and contribute to its overall durability and longevity.
7. Quality Control and Manufacturing Processes:
The construction quality and manufacturing processes employed in the production of micro gear motors significantly impact their durability and longevity. Manufacturers that adhere to strict quality control standards, precision machining, and assembly processes produce motors with higher reliability and durability. Thorough testing, inspections, and quality assurance protocols ensure that the motors meet or exceed specified performance standards. By employing robust construction techniques and rigorous quality control measures, manufacturers can enhance the durability and longevity of micro gear motors.
In conclusion, the construction of micro gear motors directly influences their durability and longevity. A combination of factors such as sturdy housing, reliable gear train, high-quality bearings, well-designed windings and cores, optimized cooling, and adherence to quality control standards all contribute to the motor’s ability to withstand the demands of its application and operate reliably over an extended period. By selecting motors with robust constructions and performing regular maintenance, users cmaximize the durability and longevity of micro gear motors, ensuring their continued performance and reliability.
Are there specific industries or fields where micro gear motors play a crucial role?
Micro gear motors play a crucial role in various industries and fields due to their compact size, precise motion control capabilities, and efficient power transmission. Here are some specific industries and fields where micro gear motors are commonly employed:
1. Consumer Electronics:
Micro gear motors are extensively used in consumer electronics, such as smartphones, tablets, digital cameras, and wearable devices. They enable precise movements in camera autofocus, lens zooming, vibration feedback, haptic feedback, and other functions requiring controlled motion. The compact size of micro gear motors allows for integration into small electronic devices without compromising on functionality or performance.
2. Medical Devices:
In the medical field, micro gear motors find applications in various devices and equipment. They are used in surgical robots, miniature pumps for drug delivery systems, insulin pumps, prosthetic limbs, robotic exoskeletons, and lab automation devices. Micro gear motors provide precise motion control and reliable operation, contributing to the accuracy and effectiveness of medical procedures and treatments.
3. Robotics and Automation:
Micro gear motors are crucial components in robotics and automation systems. They are used in miniature robots, robotic arms, automated guided vehicles (AGVs), and industrial machinery. Micro gear motors offer high torque output and precise motion control, enabling robots and automated systems to perform intricate tasks with accuracy and efficiency.
4. Automotive:
In the automotive industry, micro gear motors play a vital role in various applications. They are used in power windows, power seats, HVAC systems, side mirror adjustments, headlight leveling mechanisms, and automatic door locks. Micro gear motors provide reliable and precise movement control for these automotive components, enhancing comfort, convenience, and safety for vehicle occupants.
5. Aerospace and Defense:
Micro gear motors are utilized in the aerospace and defense sectors for critical applications. They are incorporated into aircraft systems, satellite mechanisms, unmanned aerial vehicles (UAVs), missile guidance systems, and military equipment. The compact size, lightweight nature, and precise motion control capabilities of micro gear motors are essential for meeting the stringent requirements of these industries.
6. Industrial Equipment:
In industrial settings, micro gear motors are employed in various equipment and machinery. They are used in conveyor systems, packaging machines, printing presses, CNC machines, textile machinery, and robotic assembly lines. Micro gear motors provide reliable and efficient power transmission, allowing for precise control and automation of industrial processes.
7. Precision Instruments:
Micro gear motors are integral to precision instruments where accurate motion control is crucial. They are used in scientific instruments, laboratory equipment, optical devices, surveying instruments, and measuring devices. The precise positioning capabilities of micro gear motors contribute to the accuracy and reliability of these instruments.
8. Smart Home and IoT:
In the realm of smart homes and the Internet of Things (IoT), micro gear motors play a significant role. They are utilized in smart locks, motorized blinds and curtains, robotic vacuum cleaners, smart appliances, and home automation systems. Micro gear motors enable the automation and remote control of various household tasks, enhancing convenience and energy efficiency.
These are just a few examples of industries and fields where micro gear motors play a crucial role. Their compact size, precise motion control, and efficient power transmission capabilities make them indispensable components in numerous applications across diverse sectors.
editor by CX 2024-05-16
China high quality 110V 6W Electric Induction AC Gear Motor manufacturer
Product Description
110V 6W Electric Induction AC Gear Motor
Model #: 3RK15GN-C(3GN200K)
Specification
Model•Type | Output power | Voltage | Frequency | Current | Starting Torque | Rated Torque |
Ratad Speed |
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Lead Wire Type | ||||||||
Pinion Shaft | Round Shaft | W | V | Hz | A | mN.m | mN.m | r/min |
3IK15GN-A | 3IK15A-A | 15 | 1ph 100 | 50 | 0.35 | 90 | 125 | 1200 |
60 | 0.33 | 85 | 105 | 1450 | ||||
3IK15GN-E | 3IK15A-E | 15 | Iph 110 | 60 | 0.3 | 65 | 105 | 1450 |
1ph 120 | 0.32 | |||||||
3IK15GN-C | 3IK15A-C | 15 | 1ph 220 | 50 | 0.18 | 90 | 125 | 1200 |
1ph 230 | 0.2 | |||||||
3IK15GN-H | 3IK15A-H | 15 | 1ph 220 | 60 | 0.16 | 65 | 1G5 | 1450 |
1ph 230 | 0.15 | 70 | ||||||
3IK15GN-S | 3IK15A-S | 15 | 3ph 220 | 50 | 0.14 | 220 | 125 | 1200 |
60 | 0.12 | 180 | 105 | 1450 |
Parallel Shaft Gearhead
Gearhead Type | Gearhead Model | Gear Ratio | ||||||
Long Life • Low Noise | 3GN()K | 3,3.6,5,6,7,5,9, 12.5,15,18, 25,30, 36, 50, 60, 75, 90, 100, 120, 150, 180, 200 | ||||||
3GN10XK(Decimal Gearhead ) |
Dimensions
Motor Model | Gearhead Model | Gear Ratio | L1 | |||||
3IK15GN-A | 3GN(K | 3~18 | 32 | |||||
3IK15GN-E | ||||||||
3IK15GN-C | ||||||||
3IK15GN-H | ||||||||
3IK15GN-S | 25~200 | 42 |
Company Information
FAQ
Q: What’re your main products?
A: We currently produce Brushed Dc Motors, Brushed Dc Gear Motors, Planetary Dc Gear Motors, Brushless Dc Motors, Stepper motors, Ac Motors and High Precision Planetary Gear Box etc. You can check the specifications for above motors on our website and you can email us to recommend needed motors per your specification too.
Q: How to select a suitable motor?
A:If you have motor pictures or drawings to show us, or you have detailed specs like voltage, speed, torque, motor size, working mode of the motor, needed lifetime and noise level etc, please do not hesitate to let us know, then we can recommend suitable motor per your request accordingly.
Q: Do you have a customized service for your standard motors?
A: Yes, we can customize per your request for the voltage, speed, torque and shaft size/shape. If you need additional wires/cables soldered on the terminal or need to add connectors, or capacitors or EMC we can make it too.
Q: Do you have an individual design service for motors?
A: Yes, we would like to design motors individually for our customers, but it may need some mold developing cost and design charge.
Q: What’s your lead time?
A: Generally speaking, our regular standard product will need 15-30days, a bit longer for customized products. But we are very flexible on the lead time, it will depend on the specific orders.
Please contact us if you have detailed requests, thank you ! /* 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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Function: | Driving |
Brand: | ZD MOTOR |
Voltage: | 1pH 100 V |
Frequency: | 50-60Hz |
Current: | 0.33-0.35A |
Customization: |
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Can electric motors be adapted for use in both residential and industrial settings?
Yes, electric motors can be adapted for use in both residential and industrial settings. Their versatility, efficiency, and wide range of power options make them suitable for various applications in both environments. Here’s a detailed explanation of how electric motors can be adapted for use in residential and industrial settings:
- Residential Applications: Electric motors find numerous applications in residential settings, where their compact size, quiet operation, and energy efficiency are highly valued. Some common residential uses of electric motors include:
- Home Appliances: Electric motors power a wide range of home appliances such as refrigerators, washing machines, dishwashers, vacuum cleaners, fans, and air conditioners. These motors are designed to provide efficient and reliable operation while minimizing noise and energy consumption.
- Garage Door Openers: Electric motors are commonly used in residential garage door openers, providing convenient and automated access to the garage.
- HVAC Systems: Electric motors drive the fans and compressors in heating, ventilation, and air conditioning (HVAC) systems, contributing to efficient climate control and indoor comfort.
- Pool Pumps: Electric motors power pool pumps, circulating water and maintaining water quality in residential swimming pools.
- Power Tools: Electric motors are integral components of various power tools used in residential settings, including drills, saws, and trimmers.
- Industrial Applications: Electric motors are extensively used in industrial settings due to their reliability, controllability, and adaptability to various industrial processes. Some common industrial applications of electric motors include:
- Manufacturing Machinery: Electric motors drive a wide range of manufacturing machinery, including conveyor systems, pumps, compressors, mixers, and agitators. These motors are capable of providing precise speed and torque control, enhancing productivity and process efficiency.
- Industrial Fans and Blowers: Electric motors power fans and blowers for ventilation, cooling, and air circulation in industrial facilities, contributing to a comfortable and safe working environment.
- Machine Tools: Electric motors drive machine tools such as lathes, milling machines, and grinders, enabling precision machining operations in industrial manufacturing processes.
- Material Handling Equipment: Electric motors are widely used in material handling equipment such as forklifts, conveyor systems, and hoists, facilitating efficient movement and transportation of goods within industrial facilities.
- Pumps and Compressors: Electric motors power pumps and compressors in industrial applications, such as water supply systems, HVAC systems, and pneumatic systems.
- Adaptability and Customization: Electric motors can be adapted and customized to meet specific requirements in both residential and industrial settings. They are available in a wide range of sizes, power ratings, and configurations to accommodate diverse applications. Motors can be designed for different voltages, frequencies, and environmental conditions, allowing for seamless integration into various systems and equipment. Additionally, advancements in motor control technologies, such as variable frequency drives (VFDs), enable precise speed and torque control, making electric motors highly versatile and adaptable to different operational needs.
- Energy Efficiency and Environmental Benefits: The use of electric motors in both residential and industrial settings offers significant energy efficiency advantages. Electric motors have higher efficiency compared to other types of motors, resulting in reduced energy consumption and operational costs. Furthermore, electric motors produce zero direct emissions at the point of use, contributing to a cleaner and more sustainable environment. In residential settings, energy-efficient electric motors in appliances and HVAC systems help homeowners reduce their energy bills and minimize their carbon footprint. In industrial applications, the adoption of electric motors supports energy conservation initiatives and aligns with sustainability goals.
In summary, electric motors are adaptable for use in both residential and industrial settings. Their compact size, energy efficiency, controllability, and versatility make them suitable for a wide range of applications, from home appliances and garage door openers to manufacturing machinery and material handling equipment. The use of electric motors brings benefits such as improved energy efficiency, reduced emissions, quieter operation, and enhanced control, contributing to the efficiency and sustainability of residential and industrial operations.
How do electric motors impact the overall productivity of manufacturing processes?
Electric motors have a significant impact on the overall productivity of manufacturing processes. Their versatility, reliability, and efficiency make them essential components in a wide range of industrial applications. Here’s a detailed explanation of how electric motors contribute to enhancing productivity in manufacturing:
- Mechanization and Automation: Electric motors serve as the primary power source for a vast array of industrial machinery and equipment. By providing mechanical power, electric motors enable mechanization and automation of manufacturing processes. They drive conveyor belts, pumps, compressors, robots, and other machinery, allowing for efficient material handling, assembly, and production operations. The use of electric motors in mechanized and automated systems reduces manual labor, accelerates production rates, and improves overall productivity.
- Precise Control and Repeatable Movements: Electric motors offer precise control over speed, position, and torque, enabling accurate and repeatable movements in manufacturing processes. This precision is crucial for tasks that require consistent and controlled operations, such as precision cutting, drilling, machining, and assembly. Electric motors allow for fine adjustments and control, ensuring that manufacturing operations are performed with high levels of accuracy and repeatability, which ultimately enhances productivity and product quality.
- High Speed and Acceleration: Electric motors are capable of achieving high rotational speeds and rapid acceleration, enabling fast-paced manufacturing processes. Motors with high-speed capabilities are utilized in applications that require quick operations, such as high-speed machining, packaging, and sorting. The ability of electric motors to rapidly accelerate and decelerate facilitates efficient cycle times and overall process throughput, contributing to increased productivity.
- Reliability and Durability: Electric motors are known for their reliability and durability, making them well-suited for demanding manufacturing environments. With proper maintenance, electric motors can operate continuously for extended periods, minimizing downtime due to motor failures. The reliability of electric motors ensures consistent and uninterrupted production, optimizing manufacturing productivity and reducing costly disruptions.
- Energy Efficiency: Electric motors have witnessed significant advancements in energy efficiency, leading to reduced energy consumption in manufacturing processes. Energy-efficient motors convert a higher percentage of electrical input power into useful mechanical output power, resulting in lower energy costs. By utilizing energy-efficient electric motors, manufacturers can achieve cost savings and improve the overall sustainability of their operations. Additionally, energy-efficient motors generate less heat, reducing the need for cooling and improving the overall efficiency of auxiliary systems.
- Integration with Control Systems: Electric motors can be seamlessly integrated with sophisticated control systems and automation technologies. This integration allows for centralized control, monitoring, and optimization of manufacturing processes. Control systems can regulate motor speed, torque, and performance based on real-time data, enabling adaptive and efficient operations. The integration of electric motors with control systems enhances the overall productivity by optimizing process parameters, minimizing errors, and facilitating seamless coordination between different stages of manufacturing.
Electric motors significantly impact the overall productivity of manufacturing processes by enabling mechanization, automation, precise control, high-speed operations, reliability, energy efficiency, and integration with advanced control systems. Their versatility and performance characteristics make them indispensable in a wide range of industries, including automotive, electronics, aerospace, food processing, and more. By harnessing the power of electric motors, manufacturers can streamline operations, improve product quality, increase throughput, and ultimately enhance productivity in their manufacturing processes.
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 2024-05-16
China Good quality ZD Leader 60mm-104mm High Torque Low RPM 6W 15W 25W 30W 40W 60W 90W 120W 150W- 300W 12V 24V 48V 90V 110-220V Brushed Electric DC Gear Motor vacuum pump oil
Product Description
Model Selection
ZD Leader has a wide range of micro motor production lines in the industry, including DC Motor, AC Motor, Brushless Motor, Planetary Gear Motor, Drum Motor, Planetary Gearbox, RV Reducer and Harmonic Gearbox etc. Through technical innovation and customization, we help you create outstanding application systems and provide flexible solutions for various industrial automation situations.
• Model Selection
Our professional sales representive and technical team will choose the right model and transmission solutions for your usage depend on your specific parameters.
• Drawing Request
If you need more product parameters, catalogues, CAD or 3D drawings, please contact us.
• On Your Need
We can modify standard products or customize them to meet your specific needs.
Product Parameters
DC Gear Motor
MOTOR FRAME SIZE | 60 mm / 70mm / 80mm / 90mm / 104mm |
MOTOR TYPE | Brushed |
OUTPUT POWER | 10W / 15W / 25W / 40W / 60W / 90W / 120 W / 140W / 180W / 200W / 300W(Can Be Customized) |
OUTPUT SHAFT | 8mm / 10mm / 12mm / 15mm ; Round Shaft, D-Cut Shaft, Key-Way Shaft (Can Be Customized) |
Voltage type | 12V,24V,90V,220V |
Accessories | Electric Brake / Encoder |
GEARBOX FRAME SIZE | 60 mm / 70mm / 80mm / 90mm / 104mm |
Gear Ratio | 3K-200K |
Type Of Pinion | GN Type / GU Type |
Gearbox Type | Regular Square Case gearbox / Right Angle Gearbox / L Type Gearbox |
Type Of DC Motor
Other Products
Company Profile
/* 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: | Universal, Industrial, Household Appliances, Equipment |
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Operating Speed: | Constant Speed |
Excitation Mode: | Excited |
Function: | Control, Driving |
Casing Protection: | Closed Type |
Number of Poles: | 2-6 |
Customization: |
Available
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How do brake motors handle variations in brake torque and response time?
Brake motors are designed to handle variations in brake torque and response time to ensure reliable and efficient braking performance. These variations can arise due to different operating conditions, load characteristics, or specific application requirements. Here’s a detailed explanation of how brake motors handle variations in brake torque and response time:
- Brake Design and Construction: The design and construction of brake systems in brake motors play a crucial role in handling variations in brake torque and response time. Brake systems typically consist of brake pads or shoes that press against a brake disc or drum to generate frictional forces and provide braking action. The materials used for the brake components, such as brake linings, can be selected or designed to offer a wide range of torque capacities and response characteristics. By choosing the appropriate materials and optimizing the brake system design, brake motors can accommodate variations in torque requirements and response times.
- Brake Control Mechanisms: Brake motors employ different control mechanisms to manage brake torque and response time. These mechanisms can be mechanical, electrical, or a combination of both. Mechanical control mechanisms often utilize springs or levers to apply and release the brake, while electrical control mechanisms rely on electromagnets or solenoids to engage or disengage the brake. The control mechanisms can be adjusted or configured to modulate the brake torque and response time based on the specific needs of the application.
- Brake Torque Adjustments: Brake motors may offer provisions for adjusting the brake torque to accommodate variations in load requirements. This can be achieved through the selection of different brake linings or by adjusting the spring tension or magnetic force within the brake system. By modifying the brake torque, brake motors can provide the necessary braking force to meet the demands of different operating conditions or load characteristics.
- Response Time Optimization: Brake motors can be engineered to optimize the response time of the braking system. The response time refers to the time it takes for the brake to engage or disengage once the control signal is applied. Several factors can influence the response time, including the design of the control mechanism, the characteristics of the brake linings, and the braking system’s overall dynamics. By fine-tuning these factors, brake motors can achieve faster or slower response times as required by the application, ensuring effective and timely braking action.
- Electronic Control Systems: In modern brake motors, electronic control systems are often employed to enhance the flexibility and precision of brake torque and response time adjustments. These systems utilize sensors, feedback mechanisms, and advanced control algorithms to monitor and regulate the brake performance. Electronic control allows for real-time adjustments and precise control of the brake torque and response time, making brake motors more adaptable to variations in operating conditions and load requirements.
By combining appropriate brake design and construction, control mechanisms, torque adjustments, response time optimization, and electronic control systems, brake motors can effectively handle variations in brake torque and response time. This enables them to provide reliable and efficient braking performance across a wide range of operating conditions, load characteristics, and application requirements.
What factors should be considered when selecting the right brake motor for a task?
When selecting the right brake motor for a task, several factors should be carefully considered to ensure optimal performance and compatibility with the specific application requirements. These factors help determine the suitability of the brake motor for the intended task and play a crucial role in achieving efficient and reliable operation. Here’s a detailed explanation of the key factors that should be considered when selecting a brake motor:
1. Load Characteristics: The characteristics of the load being driven by the brake motor are essential considerations. Factors such as load size, weight, and inertia influence the torque, power, and braking requirements of the motor. It is crucial to accurately assess the load characteristics to select a brake motor with the appropriate power rating, torque capacity, and braking capability to handle the specific load requirements effectively.
2. Stopping Requirements: The desired stopping performance of the brake motor is another critical factor to consider. Different applications may have specific stopping time, speed, or precision requirements. The brake motor should be selected based on its ability to meet these stopping requirements, such as adjustable braking torque, controlled response time, and stability during stopping. Understanding the desired stopping behavior is crucial for selecting a brake motor that can provide the necessary control and accuracy.
3. Environmental Conditions: The operating environment in which the brake motor will be installed plays a significant role in its selection. Factors such as temperature, humidity, dust, vibration, and corrosive substances can affect the performance and lifespan of the motor. It is essential to choose a brake motor that is designed to withstand the specific environmental conditions of the application, ensuring reliable and durable operation over time.
4. Mounting and Space Constraints: The available space and mounting requirements should be considered when selecting a brake motor. The physical dimensions and mounting options of the motor should align with the space constraints and mounting configuration of the application. It is crucial to ensure that the brake motor can be properly installed and integrated into the existing machinery or system without compromising the performance or safety of the overall setup.
5. Power Supply: The availability and characteristics of the power supply should be taken into account. The voltage, frequency, and power quality of the electrical supply should match the specifications of the brake motor. It is important to consider factors such as single-phase or three-phase power supply, voltage fluctuations, and compatibility with other electrical components to ensure proper operation and avoid electrical issues or motor damage.
6. Brake Type and Design: Different brake types, such as electromagnetic brakes or spring-loaded brakes, offer specific advantages and considerations. The choice of brake type should align with the requirements of the application, taking into account factors such as braking torque, response time, and reliability. The design features of the brake, such as braking surface area, cooling methods, and wear indicators, should also be evaluated to ensure efficient and long-lasting braking performance.
7. Regulatory and Safety Standards: Compliance with applicable regulatory and safety standards is crucial when selecting a brake motor. Depending on the industry and application, specific standards and certifications may be required. It is essential to choose a brake motor that meets the necessary standards and safety requirements to ensure the protection of personnel, equipment, and compliance with legal obligations.
8. Cost and Lifecycle Considerations: Finally, the cost-effectiveness and lifecycle considerations should be evaluated. This includes factors such as initial investment, maintenance requirements, expected lifespan, and availability of spare parts. It is important to strike a balance between upfront costs and long-term reliability, selecting a brake motor that offers a favorable cost-to-performance ratio and aligns with the expected lifecycle and maintenance budget.
Considering these factors when selecting a brake motor helps ensure that the chosen motor is well-suited for the intended task, provides reliable and efficient operation, and meets the specific requirements of the application. Proper evaluation and assessment of these factors contribute to the overall success and performance of the brake motor in its designated task.
What are the key components of a typical brake motor system?
A typical brake motor system consists of several key components that work together to provide controlled stopping and holding capabilities. These components are carefully designed and integrated to ensure the efficient operation of the brake motor. Here’s a detailed explanation of the key components of a typical brake motor system:
1. Electric Motor: The electric motor is the primary component of the brake motor system. It converts electrical energy into mechanical energy to drive the rotation of the equipment. The motor provides the necessary power and torque to perform the desired work. It can be an AC (alternating current) motor or a DC (direct current) motor, depending on the specific application requirements.
2. Braking Mechanism: The braking mechanism is a crucial component of the brake motor system that enables controlled stopping of the rotating equipment. It consists of various types of brakes, such as electromagnetic brakes or spring-loaded brakes. The braking mechanism engages when the power to the motor is cut off or the motor is de-energized, creating friction or applying pressure to halt the rotation.
3. Brake Coil or Actuator: In brake motors with electromagnetic brakes, a brake coil or actuator is employed. The coil generates a magnetic field when an electrical current passes through it, attracting the brake disc or plate and creating braking force. The coil is energized when the motor is powered, and it de-energizes when the power is cut off, allowing the brake to engage and stop the rotation.
4. Brake Disc or Plate: The brake disc or plate is a key component of the braking mechanism. It is attached to the motor shaft and rotates with it. When the brake engages, the disc or plate is pressed against a stationary surface, creating friction and stopping the rotation of the motor shaft. The material composition and design of the brake disc or plate are optimized for efficient braking performance.
5. Control System: Brake motor systems often incorporate a control system that enables precise control over the braking process. The control system allows for adjustable braking torque, response time, and braking profiles. It may include control devices such as switches, relays, or electronic control units (ECUs). The control system ensures the desired level of control and facilitates the integration of the brake motor system with other machinery or automation systems.
6. Power Supply: A reliable power supply is essential for the operation of the brake motor system. The power supply provides electrical energy to the motor and the brake mechanism. It can be a mains power supply or a dedicated power source, depending on the specific requirements of the application and the motor’s power rating.
7. Mounting and Housing: Brake motors are typically housed in a sturdy enclosure that protects the components from environmental factors, such as dust, moisture, or vibration. The housing also provides mounting points for the motor and facilitates the connection of external devices or machinery. The design of the mounting and housing ensures the stability and safety of the brake motor system.
8. Optional Accessories: Depending on the application, a brake motor system may include optional accessories such as temperature sensors, shaft encoders, or position sensors. These accessories provide additional functionality and feedback, allowing for advanced control and monitoring of the brake motor system.
These are the key components of a typical brake motor system. The integration and interaction of these components ensure controlled stopping, load holding, and precise positioning capabilities, making brake motors suitable for a wide range of industrial applications.
editor by CX 2024-05-15
China Custom Horizontal Attached Single-Phase Three-Phase Aluminum Shell (brake) Gear Reducer Motor vacuum pump electric
Product Description
Product Overview
NCH horizontal attached single-phase three-phase,aluminum shell (brake) gear reducer motor
When you need a reliable and efficient deceleration motor, MANVAC’s products are your best choice!
Our deceleration motors utilize advanced technologies, ensuring the highest standards of performance and quality. CHINAMFG motors feature high torque, low noise, and long lifespan benefits, making them suitable for various applications.
Whether you need precision control in industrial production or more efficient energy consumption in home appliances, MANVAC’s deceleration motors can easily handle the job. Our products are designed with eco-friendly materials and concepts to help you achieve your energy-saving and environmental goals.
CHINAMFG deceleration motors have received high praise and trust from our customers, enabling you to choose our products with peace of mind. Whatever type of deceleration motor you need, CHINAMFG can provide the optimal solution to make your production and life more convenient and efficient
FEATURES AT A GLANCE
High precision
Small size
Large torque
Low temperature
Regular payment With brake tailored colour
PRODUCT SPECIFICATIONS
CAPACITY |
220V |
380V |
415V |
440V |
RPM |
100W |
0.87 |
0.5 |
0.32 |
0.30 |
1410 |
200W |
1.39 |
0.8 |
0.70 |
0.58 |
1410 |
400W |
2.4 |
1.4 |
1.13 |
1.07 |
1420 |
750W |
3.8 |
2.2 |
1.94 |
1.84 |
1420 |
1500W |
6.9 |
4.0 |
3.94 |
3.30 |
1430 |
2200W |
9.5 |
5.5 |
4.74 |
4.47 |
1430 |
3700W |
15.9 |
9.2 |
6.93 |
6.93 |
1440 |
5500W |
23.5 |
13.5 |
– |
– |
1440 |
PRODUCT CONFIGURATION
Our factory
SIMILAR PRODUCTS
FAQ
1. What is the warranty of your machine?
R: 1 years, any product itself question,you can contact with us.
2. What is the material of your machine , is oil free?
R: our machine is aluminum alloy, motor is 100% copper coil , of course, we are oil free.
3. How to operate your machine?
R: Connect with wire, and turn on the power, so you can use it directly, about the wiring method, we will tell you how to do
according to your voltage, so at first , you need to tell us your voltage and phase,its important.
4. You are trading company or manufacture?
R: We are manufacture, we can provide long-term supply with fast speed.
5. How to contact with you?
R: You can send messages to me directly by alibaba trade manager, or add me like below
/* 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: | Low Speed |
Number of Stator: | Three-Phase |
Function: | Gear Reduction Motor |
Casing Protection: | Protection Type |
Number of Poles: | 6 |
Samples: |
US$ 85/Piece
1 Piece(Min.Order) | |
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Customization: |
Available
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Can you explain the advantages of using a 3-phase motor?
Using a 3-phase motor offers several advantages over other types of motors. Here’s a detailed explanation of the advantages of using a 3-phase motor:
- High Efficiency: 3-phase motors are known for their high efficiency. They can convert electrical energy into mechanical energy with minimal losses. The balanced three-phase power supply and the design of the motor result in a smoother and more efficient operation compared to single-phase motors.
- Power Factor: 3-phase motors have a better power factor compared to single-phase motors. Power factor is a measure of how effectively the motor utilizes the electrical power. By having a higher power factor, 3-phase motors reduce the amount of reactive power required from the power supply, resulting in improved overall power system efficiency.
- High Starting Torque: 3-phase motors can provide high starting torque, making them suitable for applications that require the motor to start under load. The three-phase power supply and the design of the motor enable it to produce a strong rotating magnetic field, which allows for efficient starting and acceleration of the motor’s rotor.
- Smooth Operation: The rotating magnetic field produced by the three-phase power supply results in smooth and continuous operation of the motor. This characteristic makes 3-phase motors ideal for applications that require constant and reliable operation, such as industrial machinery, pumps, compressors, and HVAC systems.
- Compact Size and Weight: 3-phase motors tend to be more compact and lightweight compared to equivalent power single-phase motors. This compactness is due to the even distribution of the windings around the stator and the absence of additional starting components often required in single-phase motors.
- Higher Power Output: 3-phase motors can deliver higher power output compared to single-phase motors of similar size. The balanced three-phase power supply and the design of the motor allow for efficient utilization of electrical power, enabling the motor to provide greater mechanical power output.
- Lower Maintenance: 3-phase motors generally require lower maintenance compared to other types of motors. The balanced three-phase power supply and the absence of starting components, such as capacitors or centrifugal switches, reduce wear and tear, resulting in longer motor life and reduced maintenance requirements.
- Wide Availability and Standardization: 3-phase motors are widely available and standardized, making them easily accessible for various applications. They are manufactured in a wide range of sizes and power ratings, allowing for flexibility in selecting the appropriate motor for specific requirements.
Overall, the advantages of using a 3-phase motor include high efficiency, better power factor, high starting torque, smooth operation, compact size and weight, higher power output, lower maintenance requirements, and wide availability. These advantages make 3-phase motors suitable for a wide range of applications in industrial, commercial, and residential settings.
Can 3-phase motors be adapted for use in both small and large-scale applications?
Yes, 3-phase motors are highly adaptable and can be used in both small and large-scale applications. Here’s a detailed explanation of their adaptability:
- Small-Scale Applications: 3-phase motors are available in a wide range of sizes and power ratings, making them suitable for small-scale applications. These motors can be found in various small industrial machines, appliances, and equipment. They are commonly used in small pumps, compressors, fans, conveyors, blowers, and other devices requiring reliable and efficient motor operation.
- Large-Scale Applications: 3-phase motors are also well-suited for large-scale applications that demand high power and torque. They can be found in heavy-duty industrial machinery and equipment used in manufacturing plants, mining operations, oil refineries, and other industrial sectors. Large-scale applications of 3-phase motors include motor-driven compressors, generators, crushers, mills, conveyor systems, and large HVAC (heating, ventilation, and air conditioning) units.
- Flexibility in Voltage and Frequency: 3-phase motors can operate with different voltage and frequency configurations, allowing for adaptation to various power systems worldwide. They can be designed and configured to accommodate specific voltage and frequency requirements, making them compatible with the electrical infrastructure of different regions and countries. This flexibility in voltage and frequency makes 3-phase motors suitable for both small and large-scale applications globally.
- Motor Control Options: 3-phase motors can be coupled with various control devices and technologies to adapt to different application requirements. For small-scale applications, simple motor starters or contactors can provide basic control functionality. In contrast, large-scale applications often utilize more advanced control systems, such as variable frequency drives (VFDs) or adjustable speed drives (ASDs), which offer precise speed and torque control. These control options allow 3-phase motors to meet the specific needs of both small and large-scale applications.
- Application-Specific Designs: Manufacturers offer a wide range of 3-phase motor designs and configurations to cater to different application requirements. Motors can be customized to meet specific performance criteria, environmental conditions, and industry standards. This adaptability allows 3-phase motors to be optimized for both small and large-scale applications, ensuring optimal efficiency, reliability, and performance.
Overall, the adaptability of 3-phase motors makes them suitable for a wide range of applications, from small-scale to large-scale. Their availability in various sizes, flexibility in voltage and frequency, compatibility with different control options, and ability to be customized for specific applications make them a versatile choice for different industrial needs. Whether it’s powering small machines or driving heavy-duty equipment, 3-phase motors can be adapted to meet the requirements of both small and large-scale applications.
How does a 3-phase motor ensure consistent and reliable performance in machinery?
A 3-phase motor is designed to ensure consistent and reliable performance in machinery. Here’s a detailed explanation of how it achieves this:
- Rotating Magnetic Field:
- A 3-phase motor operates by creating a rotating magnetic field in its stator. This rotating magnetic field induces a current in the rotor, causing it to rotate.
- The design of the 3-phase motor, with three separate windings spaced 120 degrees apart, ensures a smooth and continuous rotation of the magnetic field. This results in a consistent and reliable rotation of the motor’s rotor.
- Power Distribution:
- 3-phase motors are typically connected to a 3-phase power supply. The three phases of the power supply provide a balanced and continuous flow of electrical power to the motor.
- This balanced distribution of power across the three phases helps maintain a consistent and steady supply of electrical energy to the motor. It ensures that the motor receives a continuous and reliable power source, minimizing fluctuations and interruptions in performance.
- Higher Efficiency:
- Compared to single-phase motors, 3-phase motors are known for their higher efficiency and smoother operation. The balanced three-phase power supply and the rotating magnetic field contribute to this superior performance.
- The balanced power distribution reduces power losses and minimizes voltage drops, resulting in improved energy efficiency. Additionally, the rotating magnetic field provides a more uniform torque output, reducing vibrations and ensuring smoother operation.
- Robust Construction:
- 3-phase motors are constructed to withstand the demanding conditions often encountered in industrial machinery.
- Their robust design, including sturdy frames, high-quality materials, and effective cooling mechanisms, enhances their durability and reliability. This allows 3-phase motors to consistently deliver reliable performance, even in challenging environments.
- Motor Protection:
- To ensure reliable performance, 3-phase motors are equipped with various protective features.
- These may include thermal overload protection, which safeguards the motor against excessive heat by monitoring the motor’s temperature and tripping a protective device if it exceeds a safe threshold.
- Other protective features may include voltage and current monitoring, short circuit protection, and phase failure protection. These mechanisms help prevent damage to the motor and ensure its consistent and reliable operation.
Overall, a 3-phase motor ensures consistent and reliable performance in machinery through its design characteristics, balanced power distribution, higher efficiency, robust construction, and built-in protective features. These elements work together to deliver smooth operation, minimal interruptions, and long-term reliability, making 3-phase motors a preferred choice for a wide range of industrial applications.
editor by CX 2024-05-15
China best K Series Micro Gear Motor Speed Reducer Motor AC vacuum pump electric
Product Description
If you have any question,please contact us, we will go all out to provide all the customers with high quality and service. /* 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(/(.*?):(.*)$/))&&1
Application: | Motor, Electric Cars, Motorcycle, Machinery, Marine, Toy, Agricultural Machinery, Car |
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Hardness: | Hardened Tooth Surface |
Installation: | Vertical Type |
Samples: |
US$ 8.2/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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What role do materials play in the design and manufacturing of reliable micro gear motors?
Materials play a critical role in the design and manufacturing of reliable micro gear motors. Here’s how they contribute:
- Gear Material: The choice of material for the gears is crucial for the overall performance and reliability of micro gear motors. Gears are subjected to high loads, friction, and wear during operation. Common materials used for gears include steel, stainless steel, brass, and various engineering plastics. The selected material should have high strength, good wear resistance, and low friction characteristics to ensure smooth and efficient power transmission, minimize gear failure, and prolong the motor’s lifespan.
- Motor Housing: The material used for the motor housing affects its durability, thermal management, and protection against environmental factors. Common materials for motor housings include aluminum, stainless steel, and engineering plastics. The housing should provide structural integrity, efficient heat dissipation, and protection against dust, moisture, and other contaminants to maintain the motor’s reliability and performance in various operating conditions.
- Bearing Materials: Bearings are essential components in micro gear motors as they reduce friction and enable smooth rotation of the motor shaft. The choice of bearing material is crucial for ensuring reliable and long-lasting operation. Common bearing materials include stainless steel, ceramics, and various self-lubricating materials. The selected material should have low friction, high load-bearing capacity, and resistance to wear and corrosion to minimize power losses, maintain efficiency, and extend the motor’s lifespan.
- Magnetic Materials: In motors that utilize permanent magnets, such as brushless DC (BLDC) motors, the choice of magnetic material is crucial for generating and maintaining magnetic fields. Neodymium magnets are commonly used due to their high magnetic strength and energy efficiency. The quality and characteristics of the magnetic material directly impact the motor’s performance, torque output, and overall efficiency.
- Electrical Insulation: Micro gear motors often involve the flow of electrical current through the motor windings. Insulation materials, such as enamel or varnish, are used to electrically isolate the windings and prevent short circuits. The selected insulation material should have high dielectric strength, good thermal stability, and resistance to environmental factors to ensure reliable electrical insulation and prevent motor failures.
By carefully selecting appropriate materials for gears, motor housing, bearings, magnetic components, and electrical insulation, designers and manufacturers can optimize the reliability, efficiency, and performance of micro gear motors. The materials should be chosen based on the specific requirements of the application, considering factors such as load capacity, operating conditions, environmental factors, and cost-effectiveness.
How does the control system of micro gear motors contribute to precision in small-scale applications?
The control system of micro gear motors plays a crucial role in achieving precision in small-scale applications. Here’s how it contributes to precision:
- Speed Control: The control system allows precise regulation of the motor’s speed, enabling accurate and consistent movement in small-scale applications. By adjusting the voltage or current supplied to the motor, the control system can control the rotational speed of the motor shaft, ensuring precise motion according to the application’s requirements.
- Position Control: Micro gear motors with advanced control systems, such as stepper motors, offer precise position control. The control system sends specific signals or pulses to the motor, causing it to move in discrete steps or increments. This allows for accurate positioning in small-scale applications where precise movements and alignment are critical. The control system can also maintain the motor’s position without the need for external feedback devices, enhancing precision and simplifying the overall system.
- Torque Control: In some applications, maintaining consistent torque is essential for precision. The control system of micro gear motors can regulate the torque output, ensuring that the motor delivers the required amount of force accurately and consistently. This is particularly important in tasks that involve delicate or precise movements, such as robotics, where excessive torque can cause damage or imprecise results.
- Feedback Mechanisms: Many micro gear motors incorporate feedback mechanisms into their control systems. These mechanisms provide information about the motor’s performance, such as speed, position, or current, and allow the control system to make adjustments in real-time. Feedback mechanisms, such as encoders or sensors, enable closed-loop control, where the control system continuously monitors and adjusts the motor’s operation to maintain precision and accuracy.
- Control Algorithms: The control system of micro gear motors often incorporates sophisticated control algorithms that optimize performance and precision. These algorithms can include proportional-integral-derivative (PID) controllers, adaptive control, or advanced motion control algorithms. By analyzing the input signals, sensory feedback, and desired output, these algorithms can adjust the motor’s operation to minimize errors, disturbances, or deviations from the desired motion, thus enhancing precision in small-scale applications.
By integrating precise speed control, position control, torque control, feedback mechanisms, and advanced control algorithms, the control system of micro gear motors enables precise and accurate operation in small-scale applications. This precision is crucial for tasks that require fine movements, tight tolerances, or intricate positioning, such as robotics, automation, medical devices, and miniature mechanisms.
What are micro gear motors, and how do they differ from standard-sized gear motors?
Micro gear motors are compact and lightweight motor units that combine a small electric motor with a gear mechanism. They are designed to provide precise and controlled motion in applications where space is limited and weight reduction is crucial. Here’s how micro gear motors differ from standard-sized gear motors:
1. Size and Weight:
The most apparent difference between micro gear motors and standard-sized gear motors is their size and weight. Micro gear motors are significantly smaller and lighter than standard-sized gear motors. They are typically designed to fit in tight spaces or applications where size and weight constraints are critical, such as miniature robots, drones, or portable devices.
2. Power and Torque Output:
Due to their smaller size, micro gear motors generally have lower power and torque output compared to standard-sized gear motors. They are optimized for applications that require precise and low-power motion, rather than heavy-duty or high-torque operations. Micro gear motors are commonly used in applications such as micro robotics, medical devices, or small-scale automation systems.
3. Gearing Ratio:
The gearing ratio of micro gear motors is often higher compared to standard-sized gear motors. This means that the gear mechanism in micro gear motors provides a greater reduction in rotational speed and an increase in torque. The higher gearing ratio allows micro gear motors to deliver more torque output relative to their small motor size, enabling precise motion control in miniature applications.
4. Efficiency and Performance:
Micro gear motors may have slightly lower efficiency and performance compared to standard-sized gear motors. The smaller size and compact design can result in higher power losses and increased heat generation. However, advancements in motor and gear manufacturing technologies have significantly improved the efficiency and performance of micro gear motors, making them suitable for a wide range of applications.
5. Operating Characteristics:
Micro gear motors often exhibit different operating characteristics compared to standard-sized gear motors. They may have lower inertia, faster response times, and reduced backlash in the gear mechanism. These characteristics make micro gear motors suitable for applications requiring precise positioning, quick acceleration, and deceleration, such as miniature robotic arms or camera gimbal systems.
6. Cost:
Micro gear motors generally tend to be more expensive compared to standard-sized gear motors. The smaller size and specialized design of micro gear motors involve higher manufacturing costs. Additionally, the demand for micro gear motors is often driven by niche or specialized applications, which can contribute to their higher price point.
Despite their differences, both micro gear motors and standard-sized gear motors serve specific purposes in different applications. The choice between the two depends on the specific requirements of the application, including available space, weight limitations, power and torque requirements, and the desired level of precision and control.
editor by CX 2024-05-15