MHD093B-035-PP1-AA In Stock, Fast Shipping! | MHD Synchronous Motors

Name: MHD093B-035-PP1-AA
Brand: Bosch Rexroth Indramat
Price: 487 USD
Availability: InStock
Rating: 4.5 (6 reviews)

Product Description:

Bosch Rexroth Indramat is a renowned manufacturer specializing in industrial automation solutions. The company provides top tier products such as electric drives, motors, and control systems.

The MHD093B-035-PP1-AA is a synchronous motor that offers exceptional efficiency and durability. It features natural cooling and operates under a range of motor overtemperatures including 60 K and 100 K scenarios. This motor provides robust continuous torque at a standstill with values of 17.5 Nm at 60 K and 26.3 Nm with surface cooling. The peak current reaches up to 58.0 A and the torque constant at 20 degrees C is 1.5 Nm/A. This motor operates at a characteristic speed of 3000 rpm with a rated speed of 2500 rpm across various cooling modes. The rated torque ranges from 8.8 Nm to 20.9 Nm depending on cooling. The motor includes a winding resistance of 1.26 ? and a winding inductivity of 10.7 mH with 4 pole pairs for optimized motor performance. The rated voltage spans from 350 V to 374 V with a rated frequency of 167 Hz. The maximum permissible speed is 4500 rpm and the moment of inertia is 25.5 x 10^-4 kgm^2.

The MHD093B-035-PP1-AA synchronous motor also incorporates an IP65 rated degree of protection allowing it to function in challenging conditions. The motor also features a holding brake with a torque of 22.0 Nm operating at 24 V DC ~ 10 %. The brake's rated current is 0.71 A with connection and disconnection times of 25 ms and 50 ms respectively. Its compact design weighing 19 kg with a brake mass of 1.1 kg makes it easy to integrate into systems. The motor has a permissible ambient temperature range from 0 degrees C to 40 degrees C with a maximum setup height of 1000 meters above sea level.

Specs
Revisions
Acceleration Torque Calculator
Pid Control Calculator
Power Converter

Encoder type
Digital multiturn absolute encoder

Holding brake
Available

Insulation class
F

Mass
19 kg

Pole pairs
4

Protection rating
IP65

Rotor moment of inertia
25.5 x10⁻⁴ kg·m²

Series
MHD

Shaft type
Keyed

Theoretical max torque
66 Nm

Torque constant
1.5 Nm/A

Winding resistance
1.26 Ω

MHD093B035PP1AA
MHD093B 035 PP1 AA
mhd093b-035-pp1-aa
MHD93B-035-PP1-AA

Instructions

Use this calculator to compute the acceleration torque required to accelerate a load in a servomotor system. Enter the total inertia and angular acceleration, then click "Calculate Acceleration Torque" to see the result.

The acceleration torque is calculated using the formula: T_acc = J_total * α, where:

T_acc is the acceleration torque (Nm)
J_total is the total inertia of the system (kg·m²)
α (alpha) is the angular acceleration (rad/s²)

The total inertia (J_total) should include both the motor inertia and the load inertia reflected to the motor shaft.

Understanding Acceleration Torque

Acceleration torque is essential in defining the capability of a servomotor to initiate rotational motion. It's the torque required to overcome inertia and achieve a desired angular acceleration. In servomotor systems, proper torque calculation ensures optimal performance, preventing motor strain and energy inefficiency.

Importance for Industrial Automation

In industrial automation, precise motion control is vital. Calculating acceleration torque enables designers to choose suitable motors that meet dynamic motion demands, essential for the smooth operation of automated systems. This consideration enhances efficiency and prolongs motor lifespan in applications such as robotic arms and precision manufacturing equipment.

Total Inertia (J_total) in kg·m²

Angular Acceleration (α) in rad/s²

Result

Instructions

Use this calculator to compute the acceleration torque required to accelerate a load in a servomotor system. Enter the total inertia and angular acceleration, then click "Calculate Acceleration Torque" to see the result.

The acceleration torque is calculated using the formula: T_acc = J_total * α, where:

T_acc is the acceleration torque (Nm)
J_total is the total inertia of the system (kg·m²)
α (alpha) is the angular acceleration (rad/s²)

The total inertia (J_total) should include both the motor inertia and the load inertia reflected to the motor shaft.

Understanding Acceleration Torque

Acceleration torque is essential in defining the capability of a servomotor to initiate rotational motion. It's the torque required to overcome inertia and achieve a desired angular acceleration. In servomotor systems, proper torque calculation ensures optimal performance, preventing motor strain and energy inefficiency.

Importance for Industrial Automation

In industrial automation, precise motion control is vital. Calculating acceleration torque enables designers to choose suitable motors that meet dynamic motion demands, essential for the smooth operation of automated systems. This consideration enhances efficiency and prolongs motor lifespan in applications such as robotic arms and precision manufacturing equipment.

Instructions

Use this calculator to compute the control output for a PID controller in a servomotor system. Enter the PID gains (Kp, Ki, Kd), the current error, and the time step, then click "Calculate Control Output" to see the result.

The calculation uses the PID control law: u(t) = Kp * e(t) + Ki * ∫e(t)dt + Kd * de(t)/dt, where:

u(t) is the control output (e.g., motor voltage)
e(t) is the error (desired position - actual position)
Kp is the proportional gain
Ki is the integral gain
Kd is the derivative gain

Note: This calculator provides a simplified single-step calculation. In a real system, the PID controller would run continuously, updating the control output at each time step.

Understanding PID Controllers

PID controllers are essential in control systems, offering a way to regulate processes through feedback loops. They adjust control inputs based on the error between desired and actual outputs. The proportional term addresses present errors, the integral term corrects accumulated past errors, and the derivative term predicts future errors, enabling precise control.

Importance in Servo Systems

In servomotor applications, PID controllers ensure precise movement and positioning, which is crucial for industrial automation. By continuously adjusting the control signal (e.g., motor voltage), they maintain the desired position despite external disturbances or changes in system dynamics.

Proportional Gain (Kp)

Integral Gain (Ki)

Derivative Gain (Kd)

Error (e)

Time Step (dt) in seconds

Result

Instructions

Use this calculator to compute the control output for a PID controller in a servomotor system. Enter the PID gains (Kp, Ki, Kd), the current error, and the time step, then click "Calculate Control Output" to see the result.

The calculation uses the PID control law: u(t) = Kp * e(t) + Ki * ∫e(t)dt + Kd * de(t)/dt, where:

u(t) is the control output (e.g., motor voltage)
e(t) is the error (desired position - actual position)
Kp is the proportional gain
Ki is the integral gain
Kd is the derivative gain

Note: This calculator provides a simplified single-step calculation. In a real system, the PID controller would run continuously, updating the control output at each time step.

Understanding PID Controllers

PID controllers are essential in control systems, offering a way to regulate processes through feedback loops. They adjust control inputs based on the error between desired and actual outputs. The proportional term addresses present errors, the integral term corrects accumulated past errors, and the derivative term predicts future errors, enabling precise control.

Importance in Servo Systems

In servomotor applications, PID controllers ensure precise movement and positioning, which is crucial for industrial automation. By continuously adjusting the control signal (e.g., motor voltage), they maintain the desired position despite external disturbances or changes in system dynamics.

Instructions

Use this calculator to convert between different units of power. Select the units you want to convert from and to, enter the value, and click "Convert" to see the result.

Understanding Power Units

Power is a foundational concept in both everyday life and industrial applications. The term "watts" is ubiquitous, named after James Watt, a pivotal figure in the industrial revolution known for his advancements in steam engine technology. A watt represents the rate at which energy is transferred or converted and forms the basis for other power units such as kilowatts (1,000 watts), megawatts (1,000,000 watts), and more.

Importance in Industrial Automation and Servomotors

In industrial automation, precise power control is critical for maximizing efficiency and accuracy. Servomotors, essential components in automation systems, rely heavily on accurate power measurement. These motors, often used in robotics and CNC machinery, require specific power inputs to function correctly, translating electrical energy into controlled movements. The ability to convert between different power units helps engineers and technicians optimize these systems for energy consumption and performance. Whether ensuring that a robotic arm operates with sufficient power or managing the electrical requirements of a complex assembly line, understanding and converting power units is a crucial skill.

As technology advances, the necessity for precision grows. Power conversion tools, therefore, play an indispensable role in maintaining system efficiency and reliability, making them a staple in the toolkit of modern engineers and industrial technicians.

From

To

Value

Result

Instructions

Use this calculator to convert between different units of power. Select the units you want to convert from and to, enter the value, and click "Convert" to see the result.

Understanding Power Units

Power is a foundational concept in both everyday life and industrial applications. The term "watts" is ubiquitous, named after James Watt, a pivotal figure in the industrial revolution known for his advancements in steam engine technology. A watt represents the rate at which energy is transferred or converted and forms the basis for other power units such as kilowatts (1,000 watts), megawatts (1,000,000 watts), and more.

Importance in Industrial Automation and Servomotors

In industrial automation, precise power control is critical for maximizing efficiency and accuracy. Servomotors, essential components in automation systems, rely heavily on accurate power measurement. These motors, often used in robotics and CNC machinery, require specific power inputs to function correctly, translating electrical energy into controlled movements. The ability to convert between different power units helps engineers and technicians optimize these systems for energy consumption and performance. Whether ensuring that a robotic arm operates with sufficient power or managing the electrical requirements of a complex assembly line, understanding and converting power units is a crucial skill.

As technology advances, the necessity for precision grows. Power conversion tools, therefore, play an indispensable role in maintaining system efficiency and reliability, making them a staple in the toolkit of modern engineers and industrial technicians.

Frequently Asked Questions about MHD093B-035-PP1-AA:

Q: What are the cooling options available in the MHD093B-035-PP1-AA motor?

A: The MHD093B-035-PP1-AA motor supports natural cooling and surface cooling, ideal for industrial applications requiring efficient heat dissipation. It can also operate under various motor overtemperatures including 60 K and 100 K.

Q: What is the peak current capacity of the MHD093B-035-PP1-AA motor?

A: The MHD093B-035-PP1-AA motor has a peak current capacity of 58.0 A. This allows for high-torque demands during acceleration and ensures stable performance under heavy load conditions.

Q: What protection rating does the MHD093B-035-PP1-AA motor have?

A: This motor features an IP65 protection rating. It is designed to perform reliably in challenging industrial environments, offering resistance to dust and low-pressure water jets.

Q: What are the connectivity options for the MHD093B-035-PP1-AA motor brake system?

A: The brake system operates at 24 V DC ~ 10 % and requires a rated current of 0.71 A. It has quick connection and disconnection times of 25 ms and 50 ms, respectively.

Q: What are the environmental operating conditions for the MHD093B-035-PP1-AA motor?

A: The MHD093B-035-PP1-AA operates within a permissible ambient temperature range of 0 degrees C to 40 degrees C. It supports installations up to 1000 meters above sea level, ensuring flexible integration.