Product Description

Technical Parameter of Micro Stepper Motor
No. Model No. OD
(mm)
Step Angle
(°)
Existation
Method
Drive
Mode
Voltage
(V DC)
Current
/Phase
(mA)
Resistance
/Phase
(Ω)
Output Torque
(gf.cm)
Insolution resistance
(Ω)
Noise
(dB)
Working
environment temperature(ºC)
1 01-005-001 Φ8 18 2-2 Phase Exciting BI-Polar Drive 5.0  / 30 100.00  100V AC, 1S ≤50 -40~+80
2 07-005-001 Φ6 18 2-2 Phase Exciting BI-Polar Drive 3.3  300 40 20.00  100V AC, 1S ≤50 -20~+80
3 07-005-002 Φ6 18 2-2 Phase Exciting BI-Polar Drive 3.3  165 20 / 100V AC, 1S ≤50 -20~+80
4 07-005-011 Φ6 18 2-2 Phase Exciting BI-Polar Drive 3.3  110 30 0.06  100V AC, 1S ≤50 -20~+80
5 07-005-016 Φ6 18 2-2 Phase Exciting BI-Polar Drive 3.3  300 14 0.20  100V AC, 1S ≤50 -20~+80
6 07-005-571 Φ8 18 2-2 Phase Exciting BI-Polar Drive 3.3  160 20 80.00  100V AC, 1S ≤50 -20~+80
7 07-005-031 Φ8 18 2-2 Phase Exciting BI-Polar Drive 3.3  250 20 0.15  300V AC, 1S ≤50 -20~+80
8 07-005-032 Φ8 18 2-2 Phase Exciting BI-Polar Drive 3.3  165 20 1.50  100V AC, 1S ≤50 -20~+80
9 07-005-033 Φ8 18 2-2 Phase Exciting BI-Polar Drive 3.3  160 20 0.25  100V AC, 1S ≤50 -20~+80
10 07-005-034 Φ8 18 2-2 Phase Exciting BI-Polar Drive 5.0  100 50 0.23  100V AC, 1S ≤50 -20~+80
11 07-005-036 Φ8 18 2-2 Phase Exciting BI-Polar Drive 5.0  450 14 0.60  300V AC, 1S ≤50 -20~+80
12 07-005-041 Φ10 18 2-2 Phase Exciting BI-Polar Drive 5.0  90 55 0.30  300V AC, 1S ≤50 -20~+80
13 07-005-042 Φ10 18 2-2 Phase Exciting BI-Polar Drive 5.0  90 55 0.30  300V AC, 1S ≤50 -20~+80
14 07-005-043 Φ10 18 2-2 Phase Exciting BI-Polar Drive 5.0  160 31 5.00  100V AC, 1S ≤50 -20~+80
15 07-005-044 Φ10 0.36 2-2 Phase Exciting BI-Polar Drive 5.0  160 31 7.00  100V AC, 1S ≤50 -20~+80
16 07-005-060 Φ15 18 2-2 Phase Exciting BI-Polar Drive 12.0  400 31 180.00  100V AC, 1S ≤50 -20~+80
17 07-005-061 Φ15 18 2-2 Phase Exciting BI-Polar Drive 6.0  300 15 200.00  100V AC, 1S ≤50 -20~+80
18 07-005-062 Φ15 18 2-2 Phase Exciting BI-Polar Drive 6.0  300 15 200.00  100V AC, 1S ≤50 -20~+80
19 07-005-079 Φ15 18 2-2 Phase Exciting BI-Polar Drive 12.0  760 31 720.00  100V AC, 1S ≤50 -20~+80
20 07-005-081 Φ20 18 2-2 Phase Exciting BI-Polar Drive 12.0  300 40 30.00  100V AC, 1S ≤50 -20~+80

/* 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: Security Camera Lens Digital Camera Lens
Speed: Low Speed
Number of Stator: Two-Phase
Excitation Mode: 2-2 Phase Exciting
Function: Driving
Number of Poles: 2
Samples:
US$ 15/Piece
1 Piece(Min.Order)

|

Customization:
Available

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dc motor

What are the key differences between brushed and brushless DC motors?

Brushed and brushless DC motors are two distinct types of motors that differ in their construction, operation, and performance characteristics. Here’s a detailed explanation of the key differences between brushed and brushless DC motors:

1. Construction:

Brushed DC Motors: Brushed DC motors have a relatively simple construction. They consist of a rotor with armature windings and a commutator, and a stator with permanent magnets or electromagnets. The commutator and brushes make physical contact to provide electrical connections to the armature windings.

Brushless DC Motors: Brushless DC motors have a more complex construction. They typically consist of a stationary stator with permanent magnets or electromagnets and a rotor with multiple coils or windings. The rotor does not have a commutator or brushes.

2. Commutation:

Brushed DC Motors: In brushed DC motors, the commutator and brushes are responsible for the commutation process. The brushes make contact with different segments of the commutator, reversing the direction of the current through the armature windings as the rotor rotates. This switching of the current direction generates the necessary torque for motor rotation.

Brushless DC Motors: Brushless DC motors use electronic commutation instead of mechanical commutation. The commutation process is managed by an external electronic controller or driver. The controller determines the timing and sequence of energizing the stator windings based on the rotor position, allowing for precise control of motor operation.

3. Efficiency:

Brushed DC Motors: Brushed DC motors tend to have lower efficiency compared to brushless DC motors. This is primarily due to the energy losses associated with the brushes and commutation process. The friction and wear between the brushes and commutator result in additional power dissipation and reduce overall motor efficiency.

Brushless DC Motors: Brushless DC motors are known for their higher efficiency. Since they eliminate the use of brushes and commutators, there are fewer energy losses and lower frictional losses. The electronic commutation system allows for precise control of the motor’s operation, maximizing efficiency and reducing power consumption.

4. Maintenance:

Brushed DC Motors: Brushed DC motors require regular maintenance due to the wear and tear of the brushes and commutator. The brushes need periodic replacement, and the commutator requires cleaning to maintain proper electrical contact. The maintenance requirements contribute to additional costs and downtime for brushed DC motors.

Brushless DC Motors: Brushless DC motors have a relatively maintenance-free operation. As they do not have brushes or commutators, there is no need for brush replacement or commutator cleaning. This results in reduced maintenance costs and increased reliability of brushless DC motors.

5. Speed Control:

Brushed DC Motors: Brushed DC motors offer simpler speed control options. The speed can be controlled by adjusting the applied voltage or by varying the resistance in the armature circuit. This allows for relatively straightforward speed regulation.

Brushless DC Motors: Brushless DC motors provide more advanced and precise speed control capabilities. The speed can be controlled through the electronic commutation system by adjusting the timing and sequence of the stator windings’ energization. This allows for precise control of the motor’s speed and acceleration.

These key differences between brushed and brushless DC motors make each type suitable for different applications depending on factors such as efficiency requirements, maintenance considerations, and control complexity.

dc motor

What is the significance of back EMF (electromotive force) in DC motor performance?

The significance of back EMF (electromotive force) in DC motor performance is crucial to understanding the behavior and operation of DC motors. Back EMF is an inherent characteristic of DC motors and plays a pivotal role in their efficiency, speed regulation, and overall performance. Here’s a detailed explanation of the significance of back EMF in DC motor performance:

When a DC motor operates, it generates a voltage known as back EMF or counter electromotive force. This voltage opposes the applied voltage and is caused by the rotation of the motor’s armature within the magnetic field. The back EMF is directly proportional to the rotational speed of the motor.

The significance of back EMF can be understood through the following aspects:

1. Speed Regulation:

Back EMF is crucial for regulating the speed of a DC motor. As the motor rotates faster, the back EMF increases, which reduces the effective voltage across the motor’s armature. Consequently, the armature current decreases, limiting the motor’s speed. This self-regulating characteristic helps maintain a relatively constant speed under varying load conditions. It allows the motor to deliver the required torque while preventing excessive speed that can potentially damage the motor or the driven equipment.

2. Efficiency:

Back EMF plays a significant role in the efficiency of a DC motor. When the motor is loaded and drawing current, the power supplied to the motor is the product of the armature current and the applied voltage. However, the electrical power converted into mechanical power is reduced by the power consumed by the back EMF. The back EMF represents the energy returned to the power supply as the motor generates its own voltage. By reducing the effective voltage across the motor, it helps minimize power losses due to electrical resistance and improves the overall efficiency of the motor.

3. Motor Protection:

The presence of back EMF also provides a level of protection to the motor. When a DC motor is operating and the load on the motor suddenly decreases, such as when the driven equipment is disconnected, the motor’s speed can increase rapidly. This increase in speed leads to a higher back EMF, which reduces the armature current and prevents excessive current flow. By limiting the current, the back EMF helps protect the motor from overloading and potential damage.

4. Voltage Regulation:

Back EMF affects the voltage regulation in a DC motor. When the motor is operating, the back EMF opposes the applied voltage. As the motor load increases, the voltage drop across the armature resistance and other internal losses also increase. The back EMF helps compensate for these voltage drops, ensuring that the motor receives an adequate voltage to maintain its performance and torque output.

5. Control and Dynamic Response:

Back EMF provides valuable information for motor control and dynamic response. By measuring the back EMF voltage, the rotational speed of the motor can be estimated, allowing for precise speed control and feedback. This information is crucial for applications that require accurate speed regulation, such as robotics or industrial automation.

In summary, the significance of back EMF in DC motor performance cannot be overstated. It influences speed regulation, efficiency, motor protection, voltage regulation, and control capabilities. By understanding and utilizing the inherent characteristics of back EMF, engineers can design and optimize DC motor systems for various applications, ensuring reliable and efficient operation.

dc motor

Can DC motors be used in robotics, and if so, what are some notable applications?

Yes, DC (Direct Current) motors can be used in robotics, and they are widely employed in various robotic applications. DC motors offer several advantages that make them suitable for robotic systems, including their controllability, compact size, and versatility. Here’s a detailed explanation of how DC motors are used in robotics and some notable applications:

DC Motors in Robotics:

DC motors are commonly used in robotics due to their ability to provide precise speed control and torque output. They can be easily controlled by adjusting the voltage applied to the motor, allowing for accurate and responsive motion control in robotic systems. Additionally, DC motors can be designed in compact sizes, making them suitable for applications with limited space and weight constraints.

There are two main types of DC motors used in robotics:

  1. DC Brushed Motors: These motors have a commutator and carbon brushes that provide the electrical connection to the rotating armature. They are relatively simple in design and cost-effective. However, they may require maintenance due to brush wear.
  2. DC Brushless Motors: These motors use electronic commutation instead of brushes, resulting in improved reliability and reduced maintenance requirements. They are often more efficient and offer higher power density compared to brushed motors.

Notable Applications of DC Motors in Robotics:

DC motors find applications in various robotic systems across different industries. Here are some notable examples:

1. Robotic Manipulators: DC motors are commonly used in robotic arms and manipulators to control the movement of joints and end-effectors. They provide precise control over position, speed, and torque, allowing robots to perform tasks such as pick-and-place operations, assembly, and material handling in industrial automation, manufacturing, and logistics.

2. Mobile Robots: DC motors are extensively utilized in mobile robots, including autonomous vehicles, drones, and rovers. They power the wheels or propellers, enabling the robot to navigate and move in different environments. DC motors with high torque output are particularly useful for off-road or rugged terrain applications.

3. Humanoid Robots: DC motors play a critical role in humanoid robots, which aim to replicate human-like movements and capabilities. They are employed in various joints, including those of the head, arms, legs, and hands, allowing humanoid robots to perform complex movements and tasks such as walking, grasping objects, and facial expressions.

4. Robotic Exoskeletons: DC motors are used in robotic exoskeletons, which are wearable devices designed to enhance human strength and mobility. They provide the necessary actuation and power for assisting or augmenting human movements, such as walking, lifting heavy objects, and rehabilitation purposes.

5. Educational Robotics: DC motors are popular in educational robotics platforms and kits, including those used in schools, universities, and hobbyist projects. They provide a cost-effective and accessible way for students and enthusiasts to learn about robotics, programming, and control systems.

6. Precision Robotics: DC motors with high-precision control are employed in applications that require precise positioning and motion control, such as robotic surgery systems, laboratory automation, and 3D printing. The ability of DC motors to achieve accurate and repeatable movements makes them suitable for tasks that demand high levels of precision.

These are just a few examples of how DC motors are used in robotics. The flexibility, controllability, and compactness of DC motors make them a popular choice in a wide range of robotic applications, contributing to the advancement of automation, exploration, healthcare, and other industries.

China Best Sales 6mm 3.3V DC Micro Stepper Mini Stepping Motor   supplier China Best Sales 6mm 3.3V DC Micro Stepper Mini Stepping Motor   supplier
editor by CX 2024-05-09