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LMDCM571
Novanta IMS LMDCM571 is a stepper motor that falls under the hybrid stepper motors sub-range, featuring an integrated driver and hybrid DC stepper motor design. It incorporates an incremental magnetic encoder, a single motor stack, and operates on closed-loop hMTechnology. The connection options include a 2-pin screw-lock connector, a 7-pin spring-clamp connection, and a 9-pin D-sub male connector. It supports RS-422 and RS-485 communication protocols. The supply voltage requirement ranges from 12Vdc to 60Vdc, with optimal performance at 24Vdc and 48Vdc. This stepper motor is designed for mounting with a 57x57mm flange and has an IP20 degree of protection. The moment of inertia is specified at 0.18kg.cm^2, with a stall torque of 73N.cm. It operates with a resolution of a 1.8° step angle.
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LMDCM572
Novanta IMS LMDCM572 is a stepper motor that falls under the hybrid stepper motors sub-range, featuring an integrated driver and a hybrid DC stepper motor design. It incorporates an incremental magnetic encoder with a double motor stack and operates on closed-loop hMTechnology. The connection options include a 2-pin screw-lock connector, a 7-pin spring-clamp connection, and a 9-pin D-sub male connector, supporting RS-422 and RS-485 communication protocols. This motor is designed for a supply voltage range of 12Vdc to 60Vdc, with optimal performance at 24Vdc and 48Vdc. It mounts via a 57x57mm flange and offers a degree of protection rated at IP20. The LMDCM572 has a moment of inertia of 0.26kg.cm^2, a stall torque of 112N.cm, and a resolution characterized by a 1.8° step angle.
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LMDCM422C
Novanta IMS LMDCM422C is a stepper motor that falls under the hybrid stepper motors sub-range, featuring an integrated driver and a hybrid DC stepper motor design. It is equipped with an incremental magnetic encoder, double motor stack, and operates on closed-loop hMTechnology. This model offers a variety of connection types, including a 4-pin M12 male connector, a 12-pin M12 male connector, and a 5-pin M12 male connector. It supports RS-422 and RS-485 communication protocols. The supply voltage required for operation ranges from 12Vdc to 48Vdc, with an optimal performance at 24Vdc. The LMDCM422C is designed for mounting with a 42x42mm flange and boasts an IP65 degree of protection. It has a moment of inertia of 0.057kg.cm^2, providing a standard torque, and a stall torque of 41N.cm. The resolution is defined by a 1.8° step angle.
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LMDCM422
Novanta IMS LMDCM422 is a stepper motor that falls under the hybrid stepper motors sub-range, featuring an integrated driver and hybrid DC stepper motor design. It incorporates an incremental magnetic encoder with a double motor stack and operates on closed-loop hMTechnology. The connection options include a 2-pin screw-lock connector, a 7-pin spring-clamp connection, and a 9-pin D-sub male connector. It supports RS-422 and RS-485 communication protocols. The supply voltage requirement is between 12Vdc and 48Vdc, with 24Vdc being standard. It is designed for mounting with a 42x42mm flange and has an IP20 degree of protection. The moment of inertia is specified at 0.057kg.cm^2, offering a standard torque, and it has a stall torque of 41N.cm. The resolution is defined by a 1.8° step angle.
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LMDCE851C
Novanta IMS LMDCE851C
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LMDCE572
Novanta IMS LMDCE572 is a stepper motor that falls under the hybrid stepper motors sub-range, featuring an integrated driver and hybrid DC stepper motor design. It incorporates an incremental magnetic encoder, double motor stack, and operates on closed-loop hMTechnology. The connection options include a 2-pin screw-lock connector, a 7-pin spring-clamp connection, and a 9-pin D-sub male connector. It supports Ethernet/IP and Modbus TCP communication protocols. The supply voltage requirement ranges from 12Vdc to 60Vdc, with optimal performance at 24Vdc or 48Vdc. This stepper motor is designed for mounting with a 57x57mm flange and has an IP20 degree of protection. The moment of inertia is specified at 0.26kg.cm^2, with a stall torque of 112N.cm, and it operates with a resolution of a 1.8° step angle.
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LMDCE571
Novanta IMS LMDCE571 is a stepper motor that falls under the hybrid stepper motors sub-range, featuring an integrated driver and hybrid DC stepper motor design. It incorporates an incremental magnetic encoder, a single motor stack, and operates on closed-loop hMTechnology. The connection options include a 2-pin screw-lock connector, a 7-pin spring-clamp connection, and a 9-pin D-sub male connector, supporting Ethernet/IP and Modbus TCP communication protocols. This stepper motor is designed for a supply voltage range of 12Vdc to 60Vdc, with optimal performance at 24Vdc and 48Vdc. It mounts via a 57x57mm flange, has an IP20 degree of protection, a moment of inertia of 0.18kg.cm^2, a stall torque of 73N.cm, and offers a resolution of 1.8° step angle.
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LMDCA573
Novanta IMS LMDCA573 is a stepper motor within the hybrid stepper motors sub-range, featuring an integrated driver and hybrid DC stepper motor design. It incorporates an incremental magnetic encoder with a triple (3) motor stack, operating on a closed-loop hMTechnology. The connection options include a 2-pin screw-lock connector, a 7-pin spring-clamp connection, and a 9-pin D-sub male connector, supporting CANopen communication protocol. This motor is designed for a supply voltage range of 12Vdc to 60Vdc, with optimal performance at 24Vdc and 48Vdc. It mounts via a 57x57mm flange and offers a degree of protection rated at IP20. The LMDCA573 has a moment of inertia of 0.46kg.cm^2, a stall torque of 171N.cm, and a resolution characterized by a 1.8° step angle.
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LMDCA571C
Novanta IMS LMDCA571C is a stepper motor that falls under the hybrid stepper motors sub-range, featuring an integrated driver and a hybrid DC stepper motor design. It incorporates an incremental magnetic encoder, a single motor stack, and operates on closed-loop hMTechnology. This model offers a variety of connection types, including a 4-pin M12 male connector, a 12-pin M12 male connector, and a 5-pin M12 male connector, ensuring versatile connectivity options. It supports the CANopen communication protocol for seamless integration into various systems. The LMDCA571C operates on a supply voltage range of 12Vdc to 60Vdc, with optimal performance at 24Vdc and 48Vdc. It is designed for mounting with a 57x57mm flange and boasts a degree of protection rated at IP65, making it suitable for environments requiring dust and water resistance. The motor's moment of inertia is specified at 0.18kg.cm2, and it can deliver a stall torque of 73N.cm. With a resolution characterized by a 1.8° step angle, this stepper motor is engineered for precise control in a wide range of automation applications.
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LMDCA422C
Novanta IMS LMDCA422C is a stepper motor designed for precision applications, featuring an integrated driver and hybrid DC stepper motor technology. It incorporates an incremental magnetic encoder and a double motor stack with closed-loop hMTechnology for enhanced control. This motor offers a 4-pin M12 male connector, a 12-pin M12 male connector, and a 5-pin M12 male connector for versatile connectivity options. It operates on a CANopen communication protocol and is powered by a supply voltage ranging from 12Vdc to 48Vdc, optimally at 24Vdc. The LMDCA422C is mounted via a 42x42mm flange and boasts an IP65 degree of protection against dust and water ingress. With a moment of inertia of 0.057kg.cm^2 for standard torque and a stall torque of 41N.cm, it achieves a resolution of 1.8° step angle, making it suitable for a wide range of automation tasks.
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LMDCA423
Novanta IMS LMDCA423 is a stepper motor that falls under the hybrid stepper motors sub-range, featuring an integrated driver and a hybrid DC stepper motor design. It incorporates an incremental magnetic encoder with a triple motor stack and operates on closed-loop hMTechnology. This part offers a variety of connection types, including a 2-pin screw-lock connector, a 7-pin spring-clamp connection, and a 9-pin D-sub male connector, ensuring versatile integration options. It supports the CANopen communication protocol for seamless data exchange. The LMDCA423 operates on a supply voltage range of 12Vdc to 48Vdc, with 24Vdc as the standard. It is designed for mounting with a 42x42mm flange and has an IP20 degree of protection. The motor's moment of inertia is rated at 0.082kg.cm2, providing a standard torque, and it delivers a stall torque of 62N.cm. Its resolution is defined by a 1.8° step angle.
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LMDAM852
Novanta IMS LMDAM852 is a stepper motor that falls under the hybrid stepper motors sub-range, featuring an integrated driver and hybrid DC stepper motor design. It is equipped with an absolute multi-turn encoder, double motor stack, and operates on closed-loop hMTechnology. For connections, it offers a 2-pin screw-lock connector, a 7-pin spring-clamp connection, and a 9-pin D-sub male connector. The LMDAM852 supports RS-422 and RS-485 communication protocols. It operates on a supply voltage ranging from 12Vdc to 70Vdc, with optimal performance at 24Vdc and 48Vdc. The motor is designed for mounting with an 85x85mm flange and has an IP20 degree of protection. It features a moment of inertia of 1.35kg.cm^2, providing a standard torque, and a stall torque of 339N.cm. The resolution is defined by a 1.8° step angle.
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LMDAM573
Novanta IMS LMDAM573 is a stepper motor within the hybrid stepper motors sub-range, featuring an integrated driver and hybrid DC stepper motor design. It incorporates an absolute multi-turn encoder and a triple motor stack with closed-loop hMTechnology. This part offers a variety of connection types, including a 2-pin screw-lock connector, a 7-pin spring-clamp connection, and a 9-pin D-sub male connector. It supports RS-422 and RS-485 communication protocols. The supply voltage ranges from 12Vdc to 60Vdc, with optimal performance at 24Vdc and 48Vdc. The LMDAM573 is designed for mounting with a 57x57mm flange and has an IP20 degree of protection. It features a moment of inertia of 0.46kg.cm^2 and a stall torque of 171N.cm. The resolution is specified as a 1.8° step angle.
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LMDAM421
Novanta IMS LMDAM421 is a stepper motor that falls under the hybrid stepper motors sub-range, featuring an integrated driver and a hybrid DC stepper motor design. It is equipped with an absolute multi-turn encoder, a single motor stack, and operates on closed-loop hMTechnology. The connection options include a 2-pin screw-lock connector, a 7-pin spring-clamp connection, and a 9-pin D-sub male connector, supporting RS-422 and RS-485 communication protocols. This motor is designed for a supply voltage range of 12Vdc to 48Vdc, with an optimal performance at 24Vdc. It mounts via a 42x42mm flange and offers a degree of protection rated at IP20. The LMDAM421 has a moment of inertia of 0.038kg.cm^2, providing a standard torque, a stall torque of 31N.cm, and a resolution characterized by a 1.8° step angle.
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LMDAE851C
Novanta IMS LMDAE851C is a stepper motor that falls under the hybrid stepper motors sub-range, featuring an integrated driver and hybrid DC stepper motor design. It is equipped with an absolute multi-turn encoder, utilizing a single motor stack and operates on closed-loop hMTechnology. The connection is facilitated through a 4-pin M12 male connector, a 12-pin M12 male connector, and a 5-pin M12 male connector, supporting Ethernet/IP and Modbus TCP communication protocols. This stepper motor is designed for a supply voltage ranging from 12Vdc to 70Vdc, with optimal performance at 24Vdc and 48Vdc. It mounts via an 85x85mm flange and offers a degree of protection rated at IP65. The moment of inertia is specified at 0.9kg.cm^2, with a standard torque, and it delivers a stall torque of 237N.cm. The resolution is defined by a 1.8° step angle.
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LMDAE572C
Novanta IMS LMDAE572C is a stepper motor that falls under the hybrid stepper motors sub-range, featuring an integrated driver and hybrid DC stepper motor design. It is equipped with an absolute multi-turn encoder and a double motor stack, operating on a closed-loop hMTechnology. The connection options include a 4-pin M12 male connector, a 12-pin M12 male connector, and a 5-pin M12 male connector, supporting Ethernet/IP and Modbus TCP communication protocols. This stepper motor is designed for a supply voltage range of 12Vdc to 60Vdc, with optimal performance at 24Vdc and 48Vdc. It mounts via a 57x57mm flange and offers a degree of protection rated at IP65. The moment of inertia is specified at 0.26kg.cm^2, with a stall torque of 112N.cm and a resolution characterized by a 1.8° step angle.
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LMDAE423C
Novanta IMS LMDAE423C is a stepper motor within the hybrid stepper motors sub-range, featuring an integrated driver and hybrid DC stepper motor design. It incorporates an absolute multi-turn encoder, triple motor stack, and closed-loop hMTechnology for precise control. The connection options include a 4-pin M12 male connector, a 12-pin M12 male connector, and a 5-pin M12 male connector, supporting Ethernet/IP and Modbus TCP communication protocols. This motor operates on a supply voltage of 12Vdc to 48Vdc, with 24Vdc as the standard. It is designed for mounting with a 42x42mm flange and offers a degree of protection rated at IP65. The moment of inertia is specified at 0.082kg.cm^2 for standard torque, with a stall torque of 62N.cm and a resolution characterized by a 1.8° step angle.
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LMDAE421
Novanta IMS LMDAE421 is a stepper motor that falls under the hybrid stepper motors sub-range, featuring an integrated driver and hybrid DC stepper motor. It is designed with an absolute multi-turn encoder, utilizing a single motor stack and operates on closed-loop hMTechnology. For connections, it offers a 2-pin screw-lock connector, a 7-pin spring-clamp connection, and a 9-pin D-sub male connector. The LMDAE421 supports Ethernet/IP and Modbus TCP communication protocols. It requires a supply voltage ranging from 12Vdc to 48Vdc, with 24Vdc being standard. The motor is mounted via a 42x42mm flange and has an IP20 degree of protection. Its moment of inertia is rated at 0.038kg.cm^2, standard for its torque class, and it delivers a stall torque of 31N.cm. The resolution is specified as a 1.8° step angle.
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LMDAA853
Novanta IMS LMDAA853 is a stepper motor that falls under the hybrid stepper motors sub-range, featuring an integrated driver and hybrid DC stepper motor design. It is equipped with an absolute multi-turn encoder and a triple (3) motor stack, operating on a closed-loop hMTechnology. The connection options include a 2-pin screw-lock connector, a 7-pin spring-clamp connection, and a 9-pin D-sub male connector, supporting CANopen communication protocol. This motor is designed for a supply voltage range of 12Vdc to 70Vdc, with optimal performance at 24Vdc and 48Vdc. It mounts via an 85x85mm flange and offers a degree of protection rated at IP20. The moment of inertia is specified at 2.7kg.cm2, indicating standard torque, with a stall torque of 650N.cm. The resolution is defined by a 1.8° step angle.
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LMDAA852C
Novanta IMS LMDAA852C is a stepper motor that falls under the hybrid stepper motors sub-range, featuring an integrated driver and hybrid DC stepper motor design. It is equipped with an absolute multi-turn encoder, double motor stack, and operates on closed-loop hMTechnology. The connection options include a 4-pin M12 male connector, a 12-pin M12 male connector, and a 5-pin M12 male connector, supporting CANopen communication protocol. This stepper motor is designed for a supply voltage range of 12Vdc to 70Vdc, with optimal performance at 24Vdc and 48Vdc. It mounts via an 85x85mm flange and offers a degree of protection rated at IP65. The moment of inertia is specified at 1.35kg.cm2 for standard torque, with a stall torque of 339N.cm and a resolution characterized by a 1.8° step angle.
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Stepper Motors
General Guide & Overview
Stepper motors are powerful electromechanical devices that play a crucial role in precise and controlled mechanical movement. They are commonly used in various industries and applications that require accurate position control. But what exactly is a stepper motor, and how does it work? In this comprehensive guide, we will delve into the intricacies of stepper motors, explore their different types, discuss the advantages they offer, and touch upon the importance of stepper motor controllers.
So, what is a stepper motor? A stepper motor, also known as a step or stepping motor, is an electromechanical device that converts electrical pulses into precise mechanical movement. Unlike conventional motors, stepper motors rotate in fixed angular increments. They are designed to move in steps, making them ideal for applications that require precise control over position and speed.
Now that we know what a stepper motor is, how do stepper motors work? Stepper motors receive digital pulses that trigger the motor to rotate in fixed step increments. Each pulse corresponds to a specific rotational step, and the motor moves in either a clockwise or counterclockwise direction depending on the pulse sequence. This allows for precise control over the motor's movement, making it an excellent choice for systems that demand accuracy.
There are different types of stepper motors available, each with its own unique characteristics and advantages. Some of the common types include Variable Reluctance, Permanent Magnet, and Hybrid Stepper Motors. These motors offer varying levels of performance, allowing engineers and designers to choose the most suitable option for their specific requirements.
Stepper motors are widely used in industrial applications, robotics, and other systems that require precise motion control. They are known for their accuracy, quick response times, and the ability to handle both low and high speeds with ease. Additionally, stepper motor controllers play a vital role in enabling seamless communication and coordination between stepper motors and the control systems.
How Stepper Motors Work
Stepper motors are fascinating electromechanical devices that operate based on digital pulses. These pulses control the motor's movement by initiating fixed step increments. With each pulse, the motor rotates a specific angular step, allowing for precise control over its position. The direction of rotation, whether clockwise or counterclockwise, is determined by the pulse sequence applied to the motor.
The speed at which a stepper motor rotates can be regulated by adjusting the frequency of the input pulses. By increasing or decreasing the pulse frequency, you can control the motor's rotational speed to suit your specific application requirements.
One of the key factors that contribute to the performance of stepper motors is their motor windings configuration. Different stepper motor models have varying setups for their winding arrangements, which impact their operation and characteristics. Understanding the motor windings configuration is crucial in harnessing the full potential of stepper motors and optimizing their performance.
To accurately determine the behavior and capabilities of a stepper motor, various stepper motor formulas can be used. These formulas offer insights into essential parameters such as the number of steps per revolution, step angle, and other critical specifications. By utilizing stepper motor formulas, you can tailor your stepper motor system to meet your specific needs and achieve the desired level of precision and control.
Types of Stepper Motors
Stepper motors are widely used in various industries and applications and come in different types to suit specific requirements. The three main types of stepper motors are Variable Reluctance (VR) stepper motors, Permanent Magnet (PM) stepper motors, and Hybrid stepper motors.
Variable Reluctance (VR) Stepper Motors: VR stepper motors are designed with multiple soft iron rotors and a wound stator. These motors operate on the principle of magnetic flux finding the lowest reluctance pathway through a magnetic circuit. They offer precise control and are commonly used in applications where high torque is required.
Permanent Magnet (PM) Stepper Motors: PM stepper motors have a permanent magnet rotor with no teeth. They operate by energizing the four phases in sequence, producing accurate and reliable motion control. PM stepper motors are known for their simplicity and high torque output.
Hybrid Stepper Motors: Hybrid stepper motors combine the features of both VR and PM stepper motors, making them versatile and efficient. They provide an increase in detent torque and performance enhancement in terms of step resolution, torque, and speed. Hybrid stepper motors are widely used in applications that require precise positioning and smooth operation.
Each type of stepper motor has its own advantages and is suitable for different applications. By understanding the characteristics of each type, engineers and system designers can select the most appropriate stepper motor for their specific requirements and achieve optimal performance.
Stepper motors are versatile and precise electromechanical devices that find extensive applications in various industries. With their ability to provide accurate position control and quick response times, stepper motors are indispensable in systems that require precise motion control. Their capability to handle both low and high speeds make them suitable for a wide range of applications.
Stepper motors are widely used in robotics, CNC machines, 3D printers, and medical equipment, among other applications. The different types of stepper motors, including Variable Reluctance, Permanent Magnet, and Hybrid, offer unique performance characteristics to cater to specific requirements.
When designing and using stepper motor systems, it is essential to consider the availability of stepper motor accessories for seamless integration and enhanced functionality. Additionally, environmental considerations, such as temperature and humidity, should be taken into account to ensure optimal performance and longevity of the stepper motors.
In summary, stepper motors are a reliable choice for applications that demand precise control and accuracy. Their versatility, combined with a wide range of available accessories, allows for seamless integration into various industries and systems. By considering environmental factors and selecting the appropriate stepper motor type for specific requirements, engineers and designers can harness the full potential of stepper motors in their applications.
FAQ
What is a stepper motor?
A stepper motor is an electromechanical device that converts electrical pulses into precise mechanical movement in fixed angular increments.
How do stepper motors work?
Stepper motors work by receiving digital pulses that move the motor in fixed step increments, with each pulse corresponding to a specific rotational step.
What are the types of stepper motors?
The main types of stepper motors are Variable Reluctance, Permanent Magnet, and Hybrid stepper motors.
What is the function of a stepper motor?
The function of a stepper motor is to provide accurate position control without requiring feedback for maintaining position.
What are stepper motors used for?
Stepper motors are used in various industries and applications such as robotics, CNC machines, 3D printers, and medical equipment.
How can stepper motors be controlled?
Stepper motors can be controlled through digital instructions using stepper motor controllers.
What are the advantages of stepper motors?
Stepper motors offer advantages such as accurate position control, quick response times, and the ability to handle both low and high speeds.
What is the motor windings configuration in a stepper motor?
Stepper motors have different configurations for their motor windings, which affect their performance and characteristics.
Are there formulas to calculate stepper motor performance?
Yes, there are stepper motor formulas that can help determine important parameters such as the number of steps per revolution and step angle.
What is a Variable Reluctance stepper motor?
A Variable Reluctance stepper motor has multiple soft iron rotors and a wound stator, operating based on the principle of magnetic flux finding the lowest reluctance pathway.
What is a Permanent Magnet stepper motor?
A Permanent Magnet stepper motor has a permanent magnet rotor with no teeth and operates by energizing the four phases in sequence.
What is a Hybrid stepper motor?
A Hybrid stepper motor combines the features of Variable Reluctance and Permanent Magnet stepper motors, offering increased detent torque and performance enhancement in terms of step resolution, torque, and speed.