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China Good quality DC Motor/Three Phase Electro-Magnetic Brake Induction Motor with 2pole-0.37kw vacuum pump oil near me

Product Description

   

  HMEJ (DC) Series Self-braking Electric Motor 
HMEJ (DC) Series Self-braking Electric Motor which is totally enclosed squirrel cage with additional DC brake of disk type. It has advantage of fast brake, simple structure, high reliability and good versatility. In additional, the brake has manual work releasing structure which is widely used in mechanical equipment and transmissions devices for various requirements of rapid stop and accurate positioning.
HMEJ (DC) Series Self-braking Electric Motor 
HMEJ (DC) Series Self-braking Electric Motor which is totally enclosed squirrel cage with additional DC brake of disk type. It has advantage of fast brake, simple structure, high reliability and good versatility. In additional, the brake has manual work releasing structure which is widely used in mechanical equipment and transmissions devices for various requirements of rapid stop and accurate positioning.

 

                Energizing Power Ist/In Tst/TN Tmax/Tn  
KW RPM A % CosΦ N.m S W       KG
380V/50HZ  2POLE 3000RPM
HMEJ(DC) 63M1 0.18 2720 0.53 65 0.8 4 0.2 18 5.5 2.2 2.2 12
HMEJ(DC) 63M1 0.25 2720 0.69 68 0.81 4 0.2 18 5.5 2.2 2.2 13
HMEJ(DC) 71M1 0.37 2740 0.99 70 0.81 4 0.2 18 6.1 2.2 2.2 14
HMEJ(DC) 71M2 0.55 2740 1.4 73 0.82 4 0.2 18 6.1 2.2 2.3 15
HMEJ(DC) 80M1 0.75 2845 1.83 75 0.83 7.5 0.2 30 6.1 2.2 2.3 17
HMEJ(DC) 80M2 1.1 2840 2.58 77 0.84 7.5 0.2 30 7 2.2 2.3 18
HMEJ(DC) 90S 1.5 2840 3.43 79 0.84 15 0.2 50 7 2.2 2.3 23
HMEJ(DC) 90L 2.2 2840 4.85 81 0.85 15 0.2 50 7 2.2 2.3 26
HMEJ(DC) 100L 3 2860 6.31 83 0.87 30 0.2 65 7.5 2.2 2.3 37
HMEJ(DC) 112M 4 2880 8.1 85 0.88 40 0.25 90 7.5 2.2 2.3 45
HMEJ(DC) 132S1 5.5 2900 11 86 0.88 75 0.25 90 7.5 2.2 2.3 69
HMEJ(DC) 132S2 7.5 2900 14.9 87 0.88 75 0.25 90 7.5 2.2 2.3 72
HMEJ(DC) 160M1 11 2930 21.3 88 0.89 150 0.35 150 7.5 2.2 2.3 120
HMEJ(DC) 160M2 15 2930 28.8 89 0.89 150 0.35 150 7.5 2.2 2.3 130
HMEJ(DC) 160L 18.5 2930 34.7 90 0.9 150 0.35 150 7.5 2.2 2.3 149
HMEJ(DC) 180M 22 2940 40.8 91 0.9 200 0.35 150 7.5 2 2.3 189
HMEJ(DC) 200L1 30 2950 55.3 91.6 0.9 300 0.45 200 7.5 2 2.3 243
HMEJ(DC) 200L2 37 2950 67.6 92.4 0.9 300 0.45 200 7.5 2 2.3 267
HMEJ(DC) 225M 45 2970 82 92.7 0.9 400 0.45 200 7.5 2 2.3 323
380V/50HZ  4POLE 1500RPM
HMEJ(DC) 63M1 0.12 1310 0.44 57 0.72 4 0.2 18 4.4 2.1 2.2 13
HMEJ(DC) 63M2 0.18 1310 0.62 60 0.73 4 0.2 18 4.4 2.1 2.2 14
HMEJ(DC) 71M1 0.25 1330 0.79 65 0.74 4 0.2 18 5.2 2.1 2.2 15
HMEJ(DC) 71M2 0.37 1330 1.12 67 0.75 4 0.2 18 5.2 2.1 2.2 16
HMEJ(DC) 80M1 0.55 1390 1.57 71 0.75 7.5 0.2 30 5.2 2.4 2.3 17
HMEJ(DC) 80M2 0.75 1390 2.03 73 0.76 7.5 0.2 30 6 2.3 2.3 18
HMEJ(DC) 90S 1.1 1380 2.89 75 0.77 15 0.2 50 6 2.3 2.3 22
HMEJ(DC) 90L 1.5 1390 3.07 78 0.79 15 0.2 50 6 2.3 2.3 27
HMEJ(DC) 100L 2.2 1390 5.16 80 0.81 30 0.2 65 7 2.3 2.3 34
HMEJ(DC) 100L2 3 1410 6.78 82 0.82 30 0.2 65 7 2.3 2.3 38
HMEJ(DC) 112M 4 1410 8.8 84 0.82 40 0.25 90 7 2.3 2.3 48
HMEJ(DC) 132S 5.5 1435 11.7 85 0.83 75 0.25 90 7 2.3 2.3 71
HMEJ(DC) 132M 7.5 1440 15.6 87 0.84 75 0.25 150 7 2.3 2.3 83
HMEJ(DC) 160M 11 1440 22.3 88 0.84 150 0.35 150 7 2.2 2.3 128
HMEJ(DC) 160L 15 1460 30.1 89 0.85 150 0.35 150 7 2.2 2.3 142
HMEJ(DC) 180M 18.5 1470 35.9 91 0.86 200 0.35 150 8 2.2 2.3 184
HMEJ(DC) 180L 22 1470 42.6 91.3 0.86 200 0.35 150 8 2.2 2.3 197
HMEJ(DC) 200L 30 1470 57.4 92.4 0.86 300 0.45 200 7 2.2 2.3 264
HMEJ(DC) 225S 37 1480 69.6 92.9 0.87 300 0.45 200 7 2.2 2.3 303
HMEJ(DC) 225M 45 1480 84.3 93.3 0.87 400 0.45 200 7 2.2 2.3 337
HMEJ(DC) 71M1 0.18 850 0.74 56 0.66 4 0.2 18 4 1.9 2 9.5
HMEJ(DC) 71M2 0.25 850 0.95 59 0.68 4 0.2 18 4 1.9 2 11
HMEJ(DC) 80M1 0.37 885 1.3 62 0.7 7.5 0.2 30 4.7 1.9 2 17
HMEJ(DC) 80M2 0.55 885 1.79 65 0.72 7.5 0.2 30 4.7 1.9 2.1 19
HMEJ(DC) 90S 0.75 910 2.29 69 0.72 15 0.2 50 5.5 2 2.1 22
HMEJ(DC) 90L 1.1 910 3.18 72 0.73 15 0.2 50 5.5 2 2.1 26
HMEJ(DC) 100L 1.5 920 3.94 76 0.75 30 0.2 65 6.5 2 2.1 34
HMEJ(DC) 112M 2.2 935 5.6 79 0.76 40 0.25 90 6.5 2 2.1 42
HMEJ(DC) 132S 3 960 7.4 81 0.76 75 0.25 90 6.5 2.1 2.1 68
HMEJ(DC) 132M1 4 960 9.8 82 0.76 75 0.25 90 6.5 2.1 2.1 79
HMEJ(DC) 132M2 5.5 960 12.9 84 0.77 75 0.25 90 6.5 2.1 2.1 87
HMEJ(DC) 160M 7.5 970 17 86 0.77 150 0.35 150 6.5 2 2.1 122
HMEJ(DC) 160L 11 970 24.2 87 0.78 150 0.35 150 6.5 2 2.1 141
HMEJ(DC) 180L 15 979 31.5 89.2 0.81 200 0.35 150 7 2 2.1 195
HMEJ(DC) 200L1 18.5 970 38.4 90.3 0.81 300 0.45 200 7 2.1 2.1 217
HMEJ(DC) 200L2 22 970 44.5 90.4 0.83 300 0.45 200 7 2.2 2.1 240
HMEJ(DC) 225M 30 980 59.1 91.8 0.84 400 0.45 200 7 2 2.1 323
380V/50HZ  8POLE 750RPM
HMEJ(DC) 80M1 0.18 645 0.88 51 0.61 7.5 0.2 30 3.3 1.8 1.9 17
HMEJ(DC) 80M2 0.25 645 1.15 54 0.61 7.5 0.2 50 3.3 1.8 1.9 19
HMEJ(DC) 90S 0.37 670 1.49 62 0.61 15 0.2 50 4 1.8 1.9 23
HMEJ(DC) 90L 0.55 670 2.18 63 0.61 15 0.2 50 4 1.8 2 25
HMEJ(DC) 100L1 0.75 680 2.17 71 0.67 30 0.2 65 4 1.8 2 33
HMEJ(DC) 100L2 1.1 680 2.39 73 0.69 30 0.2 65 5 1.8 2 38
HMEJ(DC) 112M 1.5 690 4.5 75 0.69 40 0.25 90 5 1.8 2 50
HMEJ(DC) 132S 2.2 705 6 78 0.71 75 0.25 90 6 1.8 2 63
HMEJ(DC) 132M 3 705 7.9 79 0.73 75 0.25 90 6 1.8 2 79
HMEJ(DC) 160M1 4 720 10.3 81 0.73 150 0.35 150 6 1.9 2 118
HMEJ(DC) 160M2 5.5 720 13.6 83 0.74 150 0.35 150 6 2 2 119
HMEJ(DC) 160L 7.5 720 17.8 85.5 0.75 150 0.35 150 6 2 2 145
HMEJ(DC) 180L 11 730 25.1 87.8 0.76 300 0.35 150 6.6 2 2 193
HMEJ(DC) 200L 15 730 34 88.3 0.76 300 0.45 200 6.6 2 2 250
HMEJ(DC) 225S 18.5 730 40.9 90.4 0.76 300 0.45 200 6.6 1.9 2 261
HMEJ(DC) 225M 22 740 47.1 91 0.78 150 0.45 200 6.6 1.9 2 283

Features and Benefits: 
Efficiency Class:EFF2
Frame Size: H63-225
Poles:2,4,6,8 poles
Rated Power: 0.18-45KW
Rated Voltage: 220/380V,380/660V,230/400V,400V/690V
Frequency: 50HZ,60HZ
Protection Class: IP44,IP54,IP55
Insulation Class: B,F,H
Mounting Type:B3,B5,B14,B35multi and pad mounting
Ambient Temperature: -20~+40 °C
Altitude: ≤1000M

/* 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
Operating Speed: Adjust Speed
Function: Control
Casing Protection: Protection Type
Number of Poles: 2.4.6.8
Type: Y2ej
Customization:
Available

|

brake motor

How do brake motors impact the overall productivity of manufacturing processes?

Brake motors have a significant impact on the overall productivity of manufacturing processes by enhancing operational efficiency, improving safety, and enabling precise control over motion. They play a crucial role in ensuring smooth and controlled movement, which is vital for the seamless operation of machinery and equipment. Here’s a detailed explanation of how brake motors impact the overall productivity of manufacturing processes:

  • Precise Control and Positioning: Brake motors enable precise control over the speed, acceleration, and deceleration of machinery and equipment. This precise control allows for accurate positioning, alignment, and synchronization of various components, resulting in improved product quality and reduced errors. The ability to precisely control the motion enhances the overall productivity of manufacturing processes by minimizing waste, rework, and downtime.
  • Quick Deceleration and Stopping: Brake motors provide fast and controlled deceleration and stopping capabilities. This is particularly important in manufacturing processes that require frequent changes in speed or direction. The ability to rapidly decelerate and stop equipment allows for efficient handling of workpieces, quick tool changes, and seamless transitions between manufacturing steps. It reduces cycle times and improves overall productivity by minimizing unnecessary delays and optimizing throughput.
  • Improved Safety: Brake motors enhance safety in manufacturing processes by providing reliable braking functionality. They help prevent coasting or unintended movement of equipment when power is cut off or during emergency situations. The braking capability of brake motors contributes to the safe operation of machinery, protects personnel, and prevents damage to equipment or workpieces. By ensuring a safe working environment, brake motors help maintain uninterrupted production and minimize the risk of accidents or injuries.
  • Enhanced Equipment Performance: The integration of brake motors into manufacturing equipment improves overall performance. Brake motors work in conjunction with motor control devices, such as variable frequency drives (VFDs) or servo systems, to optimize motor operation. This integration allows for efficient power utilization, reduced energy consumption, and improved responsiveness. By maximizing equipment performance, brake motors contribute to higher productivity, lower operational costs, and increased output.
  • Reduced Downtime and Maintenance: Brake motors are designed for durability and reliability, reducing the need for frequent maintenance and minimizing downtime. The robust construction and high-quality components of brake motors ensure long service life and consistent performance. This reliability translates into fewer unplanned shutdowns, reduced maintenance requirements, and improved overall equipment availability. By minimizing downtime and maintenance-related interruptions, brake motors contribute to increased productivity and manufacturing efficiency.
  • Flexibility and Adaptability: Brake motors offer flexibility and adaptability in manufacturing processes. They can be integrated into various types of machinery and equipment, spanning different industries and applications. Brake motors can be customized to meet specific requirements, such as adjusting brake torque or incorporating specific control algorithms. This adaptability allows manufacturers to optimize their processes, accommodate changing production needs, and increase overall productivity.

In summary, brake motors impact the overall productivity of manufacturing processes by providing precise control and positioning, enabling quick deceleration and stopping, improving safety, enhancing equipment performance, reducing downtime and maintenance, and offering flexibility and adaptability. Their role in ensuring smooth and controlled movement, combined with their reliable braking functionality, contributes to efficient and seamless manufacturing operations, ultimately leading to increased productivity, improved product quality, and cost savings.

brake motor

How do manufacturers ensure the quality and reliability of brake motors?

Manufacturers employ various processes and measures to ensure the quality and reliability of brake motors. These processes involve rigorous testing, adherence to industry standards, quality control procedures, and continuous improvement initiatives. Here’s a detailed explanation of how manufacturers ensure the quality and reliability of brake motors:

  • Design and Engineering: Manufacturers invest considerable effort in the design and engineering phase of brake motors. They employ experienced engineers and designers who follow industry best practices and utilize advanced design tools to develop motors with robust and reliable braking systems. Thorough analysis, simulations, and prototyping are conducted to optimize the motor’s performance, efficiency, and safety features.
  • Material Selection: High-quality materials are chosen for the construction of brake motors. Manufacturers carefully select components such as motor windings, brake discs, brake pads, and housing materials to ensure durability, heat resistance, and optimal friction characteristics. The use of quality materials enhances the motor’s reliability and contributes to its long-term performance.
  • Manufacturing Processes: Stringent manufacturing processes are implemented to ensure consistent quality and reliability. Manufacturers employ advanced machinery and automation techniques for precision assembly and production. Strict quality control measures are applied at each stage of manufacturing to detect and rectify any defects or deviations from specifications.
  • Testing and Quality Assurance: Brake motors undergo comprehensive testing and quality assurance procedures before they are released to the market. These tests include performance testing, load testing, endurance testing, and environmental testing. Manufacturers verify that the motors meet or exceed industry standards and performance specifications. Additionally, they conduct safety tests to ensure compliance with applicable safety regulations and standards.
  • Certifications and Compliance: Manufacturers seek certifications and compliance with relevant industry standards and regulations. This may include certifications such as ISO 9001 for quality management systems or certifications specific to the motor industry, such as IEC (International Electrotechnical Commission) standards. Compliance with these standards demonstrates the manufacturer’s commitment to producing high-quality and reliable brake motors.
  • Quality Control and Inspection: Manufacturers implement robust quality control processes throughout the production cycle. This includes inspection of raw materials, in-process inspections during manufacturing, and final inspections before shipment. Quality control personnel conduct visual inspections, dimensional checks, and performance evaluations to ensure that each brake motor meets the specified quality criteria.
  • Continuous Improvement: Manufacturers prioritize continuous improvement initiatives to enhance the quality and reliability of brake motors. They actively seek customer feedback, monitor field performance, and conduct post-production evaluations to identify areas for improvement. This feedback loop helps manufacturers refine their designs, manufacturing processes, and quality control procedures, leading to increased reliability and customer satisfaction.
  • Customer Support and Warranty: Manufacturers provide comprehensive customer support and warranty programs for their brake motors. They offer technical assistance, troubleshooting guides, and maintenance recommendations to customers. Warranty coverage ensures that any manufacturing defects or malfunctions are addressed promptly, bolstering customer confidence in the quality and reliability of the brake motors.

By employing robust design and engineering processes, meticulous material selection, stringent manufacturing processes, comprehensive testing and quality assurance procedures, certifications and compliance with industry standards, rigorous quality control and inspection measures, continuous improvement initiatives, and dedicated customer support and warranty programs, manufacturers ensure the quality and reliability of brake motors. These measures contribute to the production of high-performance motors that meet the safety, durability, and performance requirements of industrial and manufacturing applications.

brake motor

How do brake motors ensure controlled and rapid stopping of rotating equipment?

Brake motors are designed to ensure controlled and rapid stopping of rotating equipment by employing specific braking mechanisms. These mechanisms are integrated into the motor to provide efficient and precise stopping capabilities. Here’s a detailed explanation of how brake motors achieve controlled and rapid stopping:

1. Electromagnetic Brakes: Many brake motors utilize electromagnetic brakes as the primary braking mechanism. These brakes consist of an electromagnetic coil and a brake disc or plate. When the power to the motor is cut off or the motor is de-energized, the electromagnetic coil generates a magnetic field that attracts the brake disc or plate, creating friction and halting the rotation of the motor shaft. The strength of the magnetic field and the design of the brake determine the stopping torque and speed, allowing for controlled and rapid stopping of the rotating equipment.

2. Spring-Loaded Brakes: Some brake motors employ spring-loaded brakes. These brakes consist of a spring that applies pressure on the brake disc or plate to create friction and stop the rotation. When the power is cut off or the motor is de-energized, the spring is released, pressing the brake disc against a stationary surface and generating braking force. The spring-loaded mechanism ensures quick engagement of the brake, resulting in rapid stopping of the rotating equipment.

3. Dynamic Braking: Dynamic braking is another technique used in brake motors to achieve controlled stopping. It involves converting the kinetic energy of the rotating equipment into electrical energy, which is dissipated as heat through a resistor or regenerative braking system. When the power is cut off or the motor is de-energized, the motor acts as a generator, and the electrical energy generated by the rotating equipment is converted into heat through the braking system. This dissipation of energy slows down and stops the rotation of the equipment in a controlled manner.

4. Control Systems: Brake motors are often integrated with control systems that enable precise control over the braking process. These control systems allow for adjustable braking torque, response time, and braking profiles, depending on the specific requirements of the application. By adjusting these parameters, operators can achieve the desired level of control and stopping performance, ensuring both safety and operational efficiency.

5. Coordinated Motor and Brake Design: Brake motors are designed with careful consideration of the motor and brake compatibility. The motor’s characteristics, such as torque, speed, and power rating, are matched with the braking system’s capabilities to ensure optimal performance. This coordinated design ensures that the brake can effectively stop the motor within the desired time frame and with the necessary braking force, achieving controlled and rapid stopping of the rotating equipment.

Overall, brake motors employ electromagnetic brakes, spring-loaded brakes, dynamic braking, and control systems to achieve controlled and rapid stopping of rotating equipment. These braking mechanisms, combined with coordinated motor and brake design, enable precise control over the stopping process, ensuring the safety of operators, protecting equipment from damage, and maintaining operational efficiency.

China Good quality DC Motor/Three Phase Electro-Magnetic Brake Induction Motor with 2pole-0.37kw   vacuum pump oil near me		China Good quality DC Motor/Three Phase Electro-Magnetic Brake Induction Motor with 2pole-0.37kw   vacuum pump oil near me
editor by CX 2024-04-03

China Best Sales Agricultural Machine Brake Motor vacuum pump oil near me

Product Description

Product Description

 

Agricultural machine brake motor

Elephant Fluid Power Provides New piston pumps,brake motors, widely used on agricultural machines 

fast leading time ,professional service .

 

 

 

Company Information:

 

Elephant Fluid Power has been engaged in the hydraulic business since the beginning of the 20th century. It has a history of nearly 20 years and has always been upholding the principles of “quality first”, “credit first” and “zero complaint”, and has become a new leader in the hydraulics industry. CHINAMFG Fluid Power insists on good products, good service, and has been providing customers with better, more comprehensive hydraulic products, and constantly.

 

 

 

If you are interested in our products, please contact me, I will provide the best price support and quality service.

 

I believe we will establish a good and long-term cooperation.

/* 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

Type: Piston Pump Parts
Transport Package: Carton Boxes
Trademark: Elephant Fluid Power
Origin: China

brake motor

Can brake motors be used in conjunction with other motion control methods?

Yes, brake motors can be used in conjunction with other motion control methods to achieve precise and efficient control over mechanical systems. Brake motors provide braking functionality, while other motion control methods offer various means of controlling the speed, position, and acceleration of the system. Combining brake motors with other motion control methods allows for enhanced overall system performance and versatility. Here’s a detailed explanation of how brake motors can be used in conjunction with other motion control methods:

  • Variable Frequency Drives (VFDs): Brake motors can be used in conjunction with VFDs, which are electronic devices that control the speed and torque of an electric motor. VFDs enable precise speed control, acceleration, and deceleration of the motor by adjusting the frequency and voltage supplied to the motor. By incorporating a brake motor with a VFD, the system benefits from both the braking capability of the motor and the advanced speed control provided by the VFD.
  • Servo Systems: Servo systems are motion control systems that utilize servo motors and feedback mechanisms to achieve highly accurate control over position, velocity, and torque. In certain applications where rapid and precise positioning is required, brake motors can be used in conjunction with servo systems. The brake motor provides the braking function when the system needs to hold position or decelerate rapidly, while the servo system controls the dynamic motion and positioning tasks.
  • Stepper Motor Control: Stepper motors are widely used in applications that require precise control over position and speed. Brake motors can be utilized alongside stepper motor control systems to provide braking functionality when the motor needs to hold position or prevent undesired movement. This combination allows for improved stability and control over the stepper motor system, especially in applications where holding torque and quick deceleration are important.
  • Hydraulic or Pneumatic Systems: In some industrial applications, hydraulic or pneumatic systems are used for motion control. Brake motors can be integrated into these systems to provide additional braking capability when needed. For example, a brake motor can be employed to hold a specific position or provide emergency braking in a hydraulic or pneumatic actuator system, enhancing safety and control.
  • Control Algorithms and Systems: Brake motors can also be utilized in conjunction with various control algorithms and systems to achieve specific motion control objectives. These control algorithms can include closed-loop feedback control, PID (Proportional-Integral-Derivative) control, or advanced motion control algorithms. By incorporating a brake motor into the system, the control algorithms can utilize the braking functionality to enhance overall system performance and stability.

The combination of brake motors with other motion control methods offers a wide range of possibilities for achieving precise, efficient, and safe control over mechanical systems. Whether it is in conjunction with VFDs, servo systems, stepper motor control, hydraulic or pneumatic systems, or specific control algorithms, brake motors can complement and enhance the functionality of other motion control methods. This integration allows for customized and optimized control solutions to meet the specific requirements of diverse applications.

brake motor

How does a brake motor enhance safety in industrial and manufacturing settings?

In industrial and manufacturing settings, brake motors play a crucial role in enhancing safety by providing reliable braking and control mechanisms. These motors are specifically designed to address safety concerns and mitigate potential risks associated with rotating machinery and equipment. Here’s a detailed explanation of how brake motors enhance safety in industrial and manufacturing settings:

1. Controlled Stopping: Brake motors offer controlled stopping capabilities, allowing for precise and predictable deceleration of rotating machinery. This controlled stopping helps prevent abrupt stops or sudden changes in motion, reducing the risk of accidents, equipment damage, and injury to personnel. By providing smooth and controlled stopping, brake motors enhance safety during machine shutdowns, emergency stops, or power loss situations.

2. Emergency Stop Functionality: Brake motors often incorporate emergency stop functionality as a safety feature. In case of an emergency or hazardous situation, operators can activate the emergency stop function to immediately halt the motor and associated machinery. This rapid and reliable stopping capability helps prevent accidents, injuries, and damage to equipment, providing an essential safety measure in industrial environments.

3. Load Holding Capability: Brake motors have the ability to hold loads in position when the motor is not actively rotating. This load holding capability is particularly important for applications where the load needs to be securely held in place, such as vertical lifting mechanisms or inclined conveyors. By preventing unintended movement or drift of the load, brake motors ensure safe operation and minimize the risk of uncontrolled motion that could lead to accidents or damage.

4. Overload Protection: Brake motors often incorporate overload protection mechanisms to safeguard against excessive loads. These protection features can include thermal overload protection, current limiters, or torque limiters. By detecting and responding to overload conditions, brake motors help prevent motor overheating, component failure, and potential hazards caused by overburdened machinery. This protection enhances the safety of personnel and prevents damage to equipment.

5. Failsafe Braking: Brake motors are designed with failsafe braking systems that ensure reliable braking even in the event of power loss or motor failure. These systems can use spring-loaded brakes or electromagnetic brakes that engage automatically when power is cut off or when a fault is detected. Failsafe braking prevents uncontrolled motion and maintains the position of rotating machinery, reducing the risk of accidents, injury, or damage during power interruptions or motor failures.

6. Integration with Safety Systems: Brake motors can be integrated into safety systems and control architectures to enhance overall safety in industrial settings. They can be connected to safety relays, programmable logic controllers (PLCs), or safety-rated drives to enable advanced safety functionalities such as safe torque off (STO) or safe braking control. This integration ensures that the brake motor operates in compliance with safety standards and facilitates coordinated safety measures across the machinery or production line.

7. Compliance with Safety Standards: Brake motors are designed and manufactured in compliance with industry-specific safety standards and regulations. These standards, such as ISO standards or Machinery Directive requirements, define the safety criteria and performance expectations for rotating machinery. By using brake motors that meet these safety standards, industrial and manufacturing settings can ensure a higher level of safety, regulatory compliance, and risk mitigation.

8. Operator Safety: Brake motors also contribute to operator safety by reducing the risk of unintended movement or hazardous conditions. The controlled stopping and load holding capabilities of brake motors minimize the likelihood of unexpected machine behavior that could endanger operators. Additionally, the incorporation of safety features like emergency stop buttons or remote control options provides operators with convenient means to stop or control the machinery from a safe distance, reducing their exposure to potential hazards.

By providing controlled stopping, emergency stop functionality, load holding capability, overload protection, failsafe braking, integration with safety systems, compliance with safety standards, and operator safety enhancements, brake motors significantly enhance safety in industrial and manufacturing settings. These motors play a critical role in preventing accidents, injuries, and equipment damage, contributing to a safer working environment and ensuring the well-being of personnel.

brake motor

What is a brake motor and how does it operate?

A brake motor is a type of electric motor that incorporates a mechanical braking system. It is designed to provide both motor power and braking functionality in a single unit. The brake motor is commonly used in applications where rapid and precise stopping or holding of loads is required. Here’s a detailed explanation of what a brake motor is and how it operates:

A brake motor consists of two main components: the electric motor itself and a braking mechanism. The electric motor converts electrical energy into mechanical energy to drive a load. The braking mechanism, usually located at the non-drive end of the motor, provides the necessary braking force to stop or hold the load when the motor is turned off or power is cut off.

The braking mechanism in a brake motor typically employs one of the following types of brakes:

  1. Electromagnetic Brake: An electromagnetic brake is the most common type used in brake motors. It consists of an electromagnetic coil and a brake shoe or armature. When the motor is powered, the electromagnetic coil is energized, creating a magnetic field that attracts the brake shoe or armature. This releases the brake and allows the motor to rotate and drive the load. When the power is cut off or the motor is turned off, the electromagnetic coil is de-energized, and the brake shoe or armature is pressed against a stationary surface, creating friction and stopping the motor’s rotation.
  2. Mechanical Brake: Some brake motors use mechanical brakes, such as disc brakes or drum brakes. These brakes employ friction surfaces, such as brake pads or brake shoes, which are pressed against a rotating disc or drum attached to the motor shaft. When the motor is powered, the brake is disengaged, allowing the motor to rotate. When the power is cut off or the motor is turned off, a mechanical mechanism, such as a spring or a cam, engages the brake, creating friction and stopping the motor’s rotation.

The operation of a brake motor involves the following steps:

  1. Motor Operation: When power is supplied to the brake motor, the electric motor converts electrical energy into mechanical energy, which is used to drive the load. The brake is disengaged, allowing the motor shaft to rotate freely.
  2. Stopping or Holding: When the power is cut off or the motor is turned off, the braking mechanism is engaged. In the case of an electromagnetic brake, the electromagnetic coil is de-energized, and the brake shoe or armature is pressed against a stationary surface, creating friction and stopping the motor’s rotation. In the case of a mechanical brake, a mechanical mechanism engages the brake pads or shoes against a rotating disc or drum, creating friction and stopping the motor’s rotation.
  3. Release and Restart: To restart the motor, power is supplied again, and the braking mechanism is disengaged. In the case of an electromagnetic brake, the electromagnetic coil is energized, releasing the brake shoe or armature. In the case of a mechanical brake, the mechanical mechanism disengages the brake pads or shoes from the rotating disc or drum.

Brake motors are commonly used in applications that require precise stopping or holding of loads, such as cranes, hoists, conveyors, machine tools, and elevators. The incorporation of a braking system within the motor eliminates the need for external braking devices or additional components, simplifying the design and installation process. Brake motors enhance safety, efficiency, and control in industrial applications by providing reliable and rapid braking capabilities.

China Best Sales Agricultural Machine Brake Motor   vacuum pump oil near me		China Best Sales Agricultural Machine Brake Motor   vacuum pump oil near me
editor by CX 2024-04-03

China high quality 52zyt Variable Speed Permanent Magnet DC Brake Motor High Power Electric Motor for Air Compressors vacuum pump oil near me

Product Description

52ZYT Variable Speed Permanent Magnet DC Brake Motor high power electric motor for Air Compressors

Quiet, stable and reliable for long life operation
1.Diameters: 52mm
2.Lengths:  90mm;105mm;120mm
3.Continuous torques: 0.05Nm;0.09Nm;0.14Nm
4.Power: 18W;32W;50W
5.Speeds up to 3400rpm;3400rpm;3400rpm
6.Environmental conditions: -10~+40°C
7.Number of poles:2
8.Mangnet material:Hard Ferrit
9.Insulation class:B
10.Optional: electronic drivers, encoders and gearheads, as well as Hall effect resolver and sensorless feedback
11.We can design the special voltage and shaft, and so on

Model 52ZYT01 52ZYT02 52ZYT03
Voltage V 24
No load speed rpm 4000
Rated torque Nm 50 90 140
Rated speed rpm 3400 3400 3400
Rated current A 1.10  1.92  2.90 
Stall torque Nm 330 610 930
Stall current A 6.3 11.5 17.2
Rotor inertia Kgmm² 25.0  40.0  55.0 
Back-EMF constant V/krpm 5.80  5.83 5.86
Torque Constant Nm/A 55.4 55.7 56.0 
Resistance(20ºC) ohm 3.80  2.10  1.40 
Weight Kg 0.70  0.95  1.20 
L1 mm 90 105 120
Rotor:La mm 20 35 50

Normal type of shaft

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Application: Universal, Industrial, Household Appliances, Car, Power Tools, Medical Equpiments
Operating Speed: Constant Speed
Excitation Mode: Compound
Function: Driving
Number of Poles: 2
Structure and Working Principle: Brush
Samples:
US$ 11/Piece
1 Piece(Min.Order)

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Customization:
Available

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brake motor

What advancements in brake motor technology have improved energy efficiency?

Advancements in brake motor technology have led to significant improvements in energy efficiency, resulting in reduced power consumption and operational costs. These advancements encompass various aspects of brake motor design, construction, and control systems. Here’s a detailed explanation of the advancements in brake motor technology that have improved energy efficiency:

  • High-Efficiency Motor Designs: Brake motors now incorporate high-efficiency motor designs that minimize energy losses during operation. These designs often involve the use of advanced materials, improved winding techniques, and optimized magnetic circuits. High-efficiency motors reduce the amount of energy wasted as heat and maximize the conversion of electrical energy into mechanical power, leading to improved overall energy efficiency.
  • Efficient Brake Systems: Brake systems in modern brake motors are designed to minimize energy consumption during braking and holding periods. Energy-efficient brake systems utilize materials with low friction coefficients, reducing the energy dissipated as heat during braking. Additionally, advanced control mechanisms and algorithms optimize the engagement and disengagement of the brake, minimizing power consumption while maintaining reliable braking performance.
  • Regenerative Braking: Some advanced brake motors incorporate regenerative braking technology, which allows the recovery and reuse of energy that would otherwise be dissipated as heat during braking. Regenerative braking systems convert the kinetic energy of the moving equipment into electrical energy, which is fed back into the power supply or stored in energy storage devices. By harnessing and reusing this energy, brake motors improve energy efficiency and reduce the overall power consumption of the system.
  • Variable Speed Control: Brake motors equipped with variable frequency drives (VFDs) or other speed control mechanisms offer improved energy efficiency. By adjusting the motor’s speed and torque to match the specific requirements of the application, variable speed control reduces energy wastage associated with operating at fixed speeds. The ability to match the motor’s output to the load demand allows for precise control and significant energy savings.
  • Advanced Control Systems: Brake motors benefit from advanced control systems that optimize energy usage. These control systems employ sophisticated algorithms and feedback mechanisms to continuously monitor and adjust motor performance based on the load conditions. By dynamically adapting the motor operation to the changing requirements, these control systems minimize energy losses and improve overall energy efficiency.
  • Improved Thermal Management: Efficient thermal management techniques have been developed to enhance brake motor performance and energy efficiency. These techniques involve the use of improved cooling systems, such as advanced fan designs or liquid cooling methods, to maintain optimal operating temperatures. By effectively dissipating heat generated during motor operation, thermal management systems reduce energy losses associated with excessive heat and improve overall energy efficiency.

These advancements in brake motor technology, including high-efficiency motor designs, efficient brake systems, regenerative braking, variable speed control, advanced control systems, and improved thermal management, have collectively contributed to improved energy efficiency. By reducing energy losses, optimizing braking mechanisms, and implementing intelligent control strategies, modern brake motors offer significant energy savings and contribute to a more sustainable and cost-effective operation of equipment.

brake motor

How do brake motors contribute to the efficiency of conveyor systems and material handling?

Brake motors play a crucial role in enhancing the efficiency of conveyor systems and material handling operations. They provide several advantages that improve the overall performance and productivity of these systems. Here’s a detailed explanation of how brake motors contribute to the efficiency of conveyor systems and material handling:

  • Precise Control: Brake motors offer precise control over the movement of conveyor systems. The braking mechanism allows for quick and accurate stopping, starting, and positioning of the conveyor belt or other material handling components. This precise control ensures efficient operation, minimizing the time and effort required to handle materials and reducing the risk of damage or accidents.
  • Speed Regulation: Brake motors can regulate the speed of conveyor systems, allowing operators to adjust the conveying speed according to the specific requirements of the materials being handled. This speed control capability enables efficient material flow, optimizing production processes and preventing bottlenecks or congestion. It also contributes to better synchronization with upstream or downstream processes, improving overall system efficiency.
  • Load Handling: Brake motors are designed to handle varying loads encountered in material handling applications. They provide the necessary power and torque to move heavy loads along the conveyor system smoothly and efficiently. The braking mechanism ensures safe and controlled stopping even with substantial loads, preventing excessive wear or damage to the system and facilitating efficient material transfer.
  • Energy Efficiency: Brake motors are engineered for energy efficiency, contributing to cost savings and sustainability in material handling operations. They are designed to minimize energy consumption during operation by optimizing motor efficiency, reducing heat losses, and utilizing regenerative braking techniques. Energy-efficient brake motors help lower electricity consumption, resulting in reduced operating costs and a smaller environmental footprint.
  • Safety Enhancements: Brake motors incorporate safety features that enhance the efficiency of conveyor systems and material handling by safeguarding personnel and equipment. They are equipped with braking systems that provide reliable stopping power, preventing unintended motion or runaway loads. Emergency stop functionality adds an extra layer of safety, allowing immediate halting of the system in case of emergencies or hazards, thereby minimizing the potential for accidents and improving overall operational efficiency.
  • Reliability and Durability: Brake motors are constructed to withstand the demanding conditions of material handling environments. They are designed with robust components and built-in protection features to ensure reliable operation even in harsh or challenging conditions. The durability of brake motors reduces downtime due to motor failures or maintenance issues, resulting in improved system efficiency and increased productivity.
  • Integration and Automation: Brake motors can be seamlessly integrated into automated material handling systems, enabling efficient and streamlined operations. They can be synchronized with control systems and sensors to optimize material flow, automate processes, and enable efficient sorting, routing, or accumulation of items. This integration and automation capability enhances system efficiency, reduces manual intervention, and enables real-time monitoring and control of the material handling process.
  • Maintenance and Serviceability: Brake motors are designed for ease of maintenance and serviceability, which contributes to the overall efficiency of conveyor systems and material handling operations. They often feature modular designs that allow quick and easy replacement of components, minimizing downtime during maintenance or repairs. Accessible lubrication points, inspection ports, and diagnostic features simplify routine maintenance tasks, ensuring that the motors remain in optimal working condition and maximizing system uptime.

By providing precise control, speed regulation, reliable load handling, energy efficiency, safety enhancements, durability, integration with automation systems, and ease of maintenance, brake motors significantly contribute to the efficiency of conveyor systems and material handling operations. Their performance and features optimize material flow, reduce downtime, enhance safety, lower operating costs, and improve overall productivity in a wide range of industries and applications.

brake motor

What is a brake motor and how does it operate?

A brake motor is a type of electric motor that incorporates a mechanical braking system. It is designed to provide both motor power and braking functionality in a single unit. The brake motor is commonly used in applications where rapid and precise stopping or holding of loads is required. Here’s a detailed explanation of what a brake motor is and how it operates:

A brake motor consists of two main components: the electric motor itself and a braking mechanism. The electric motor converts electrical energy into mechanical energy to drive a load. The braking mechanism, usually located at the non-drive end of the motor, provides the necessary braking force to stop or hold the load when the motor is turned off or power is cut off.

The braking mechanism in a brake motor typically employs one of the following types of brakes:

  1. Electromagnetic Brake: An electromagnetic brake is the most common type used in brake motors. It consists of an electromagnetic coil and a brake shoe or armature. When the motor is powered, the electromagnetic coil is energized, creating a magnetic field that attracts the brake shoe or armature. This releases the brake and allows the motor to rotate and drive the load. When the power is cut off or the motor is turned off, the electromagnetic coil is de-energized, and the brake shoe or armature is pressed against a stationary surface, creating friction and stopping the motor’s rotation.
  2. Mechanical Brake: Some brake motors use mechanical brakes, such as disc brakes or drum brakes. These brakes employ friction surfaces, such as brake pads or brake shoes, which are pressed against a rotating disc or drum attached to the motor shaft. When the motor is powered, the brake is disengaged, allowing the motor to rotate. When the power is cut off or the motor is turned off, a mechanical mechanism, such as a spring or a cam, engages the brake, creating friction and stopping the motor’s rotation.

The operation of a brake motor involves the following steps:

  1. Motor Operation: When power is supplied to the brake motor, the electric motor converts electrical energy into mechanical energy, which is used to drive the load. The brake is disengaged, allowing the motor shaft to rotate freely.
  2. Stopping or Holding: When the power is cut off or the motor is turned off, the braking mechanism is engaged. In the case of an electromagnetic brake, the electromagnetic coil is de-energized, and the brake shoe or armature is pressed against a stationary surface, creating friction and stopping the motor’s rotation. In the case of a mechanical brake, a mechanical mechanism engages the brake pads or shoes against a rotating disc or drum, creating friction and stopping the motor’s rotation.
  3. Release and Restart: To restart the motor, power is supplied again, and the braking mechanism is disengaged. In the case of an electromagnetic brake, the electromagnetic coil is energized, releasing the brake shoe or armature. In the case of a mechanical brake, the mechanical mechanism disengages the brake pads or shoes from the rotating disc or drum.

Brake motors are commonly used in applications that require precise stopping or holding of loads, such as cranes, hoists, conveyors, machine tools, and elevators. The incorporation of a braking system within the motor eliminates the need for external braking devices or additional components, simplifying the design and installation process. Brake motors enhance safety, efficiency, and control in industrial applications by providing reliable and rapid braking capabilities.

China high quality 52zyt Variable Speed Permanent Magnet DC Brake Motor High Power Electric Motor for Air Compressors   vacuum pump oil near me		China high quality 52zyt Variable Speed Permanent Magnet DC Brake Motor High Power Electric Motor for Air Compressors   vacuum pump oil near me
editor by CX 2024-04-02