Product Description

Nema Geared Stepper Motor mm Hybrid Step Motor 17HS4401 12V 24V Stepping Motor with Planetary Gearbox / Brake / Encoder for 3d printer

Product Description

GenHangZhou Specification
Item Specifications
Step Angle 1.8° or 0.9°
Temperature Rise 80ºCmax
Ambient Temperature -20ºC~+50ºC
Insulation Resistance 100 MΩ Min. ,500VDC
Dielectric Strength 500VAC for 1minute
Shaft Radial Play 0.02Max. (450g-load)
Shaft Axial Play 0.08Max. (450g-load)
Max. radial force 28N (20mm from the flange)
Max. axial force 10N

1. The magnetic steel is high grade,we usually use the SH level type.
2. The rotor is be coated,reduce burrs,working smoothly,less noise. We test the stepper motor parts step by step.
3. Stator is be test and rotor is be test before assemble.
4. After we assemble the stepper motor, we will do 1 more test for it, to make sure the quality is good.

JKONGMOTOR stepping motor is a motor that converts electrical pulse signals into corresponding angular displacements or linear displacements. This small stepper motor can be widely used in various fields, such as a 3D printer, stage lighting, laser engraving, textile machinery, medical equipment, automation equipment, etc.

1.8 Degree Stepper Motor Parameters:

Model No. Step Angle Motor Length Current Resistance Inductance Holding Torque # of Leads Detent Torque Rotor Inertia Mass
( °) (L)mm A Ω mH kg.cm No. g.cm g.cm2 Kg
JK42HS25-0404 1.8 25 0.4 24 36 1.8 4 75 20 0.15
JK42HS28-0504 1.8 28 0.5 20 21 1.5 4 85 24 0.22
JK42HS34-1334 1.8 34 1.33 2.1 2.5 2.2 4 120 34 0.22
JK42HS34-0406 1.8 34 0.4 24 15 1.6 6 120 34 0.22
JK42HS34-0956 1.8 34 0.95 4.2 2.5 1.6 6 120 34 0.22
JK42HS40-0406 1.8 40 0.4 30 30 2.6 6 150 54 0.28
JK42HS40-1684 1.8 40 1.68 1.65 3.2 3.6 4 150 54 0.28
JK42HS40-1206 1.8 40 1.2 3 2.7 2.9 6 150 54 0.28
JK42HS48-0406 1.8 48 0.4 30 25 3.1 6 260 68 0.35
JK42HS48-1684 1.8 48 1.68 1.65 2.8 4.4 4 260 68 0.35
JK42HS48-1206 1.8 48 1.2 3.3 2.8 3.17 6 260 68 0.35
JK42HS60-0406 1.8 60 0.4 30 39 6.5 6 280 102 0.5
JK42HS60-1704 1.8 60 1.7 3 6.2 7.3 4 280 102 0.5
JK42HS60-1206 1.8 60 1.2 6 7 5.6 6 280 102 0.5

0.9 Degree Stepper Motor Parameters:

Model No. Step Angle Motor Length Current Resistance Inductance Holding Torque # of Leads Detent Torque Rotor Inertia Motor
( °) (L)mm A Ω mH kg.cm No. g.cm g.cm2 Kg
JK42HM34-1334 0.9 34 1.33 2.1 4.2 2.2 4 200 35 0.22
JK42HM34- 0571 0.9 34 0.31 38.5 33 1.58 6 200 35 0.22
JK42HM34-0956 0.9 34 0.95 4.2 4 1.58 6 200 35 0.22
JK42HM40-1684 0.9 40 1.68 1.65 3.2 3.3 4 220 54 0.28
JK42HM40-0406 0.9 40 0.4 30 30 2.59 6 220 54 0.28
JK42HM40-1206 0.9 40 1.2 3.3 3.4 2.59 6 220 54 0.28
JK42HM48-1684 0.9 48 1.68 1.65 4.1 4.4 4 250 68 0.35
JK42HM48-1206 0.9 48 1.2 3.3 4 3.17 6 250 68 0.35
JK42HM48-0406 0.9 48 0.4 30 38 3.17 6 250 68 0.35
JK42HM60-1684 0.9 60 1.68 1.65 5 5.5 4 270 106 0.55

Nema 17 HSP Planetary Gearbox Stepper Motor Parameters:

General Specification
Housing Material Metal
Bearing at Output Ball Bearings
Max.Radial Load(12mm from flange) ≤80N
Max.Shaft Axial Load ≤30N
Radial Play of Shaft (near to Flange) ≤0.06mm
Axial Play of Shaft ≤0.3mm
Backlash at No-load 1.5°

 

42HSP Planetary Gearbox Parameters
Reduction ratio 3.71 5.18 13.76 19.2 26.8 51 71 99.5 139
Number of gear trains 1 2 3
Length(L2): mm 27.3 35 42.7
Max.rated torque: kg.cm 20 30 40
Short time permissible torque: kg.cm 40 60 80
Weight: g 350 450 550

Nema 17 HSG Planetary Gearbox Stepper Motor Parameters:

General Specification
Housing Material Metal
Bearing at Output Ball Bearings
Max.Radial Load(12mm from flange) ≤20N
Max.Shaft Axial Load ≤15N
Radial Play of Shaft (near to Flange) ≤0.06mm
Axial Play of Shaft ≤0.3mm
Backlash at No-load 1.5°

 

42HSG Planetary Gearbox Parameters
Reduction ratio 5 10 15 20
Number of gear trains 1 2
(L2)Length: (mm) 28.5
Peak torque: (kg.cm) 10
Backlash at Noload: (°) 4deg 3deg

Nema 17 PLE Planetary Gearbox Stepper Motor Parameters:

PLE42-L1 Electrical Specification:
Specification PLE42-L1
Model PLE42-03 PLE42-04 PLE42-05 PLE42-07 PLE42-571
Reduction Ratio 3:01 4:01 5:01 7:01 10:01
Output Torque 8N.m 9N.m 9N.m 5N.m 5N.m
Fail-stop Torque 16N.m 18N.m 18N.m 10N.m 10N.m
Suitable Motor Φ5-10 / Φ22-2 / F31-M3
Rated Input Speed 3000min-1
Max Input Speed 6000min-1
Average Lifespan 20000h
Backlash ≤15arcmin
Efficiency 0.96
Noise ≤55dB
Work Temperature -10°~+90°
Degree of Protection IP54
Weight 0.25kg

 

PLE42-L2 Electrical Specification:
Specification PLE42-L2
Model PLE42-012 PLE42-015 PLE42-016 PLE42-571 PLE42-571 PLE42-571
Reduction Ratio 12:01 15:01 16:01 20:01 25:01:00 28:01:00
Output Torque 10N.m 10N.m 12N.m 12N.m 10N.m 10N.m
Fail-stop Torque 20N.m 20N.m 24N.m 24N.m 20N.m 20N.m
Model PLE42-035 PLE42-040 PLE42-050 PLE42-070 PLE42-100 /
Reduction Ratio 35:01:00 40:01:00 50:01:00 70:01:00 100:01:00 /
Output Torque 10N.m 10N.m 10N.m 10N.m 10N.m /
Fail-stop Torque 20N.m 20N.m 20N.m 20N.m 20N.m /
Suitable Motor Φ5-10 / Φ22-2 / F31-M3
Rated Input Speed 3000min-1
Max Input Speed 6000min-1
Average Lifespan 20000h
Backlash ≤20arcmin
Efficiency 94%
Noise ≤55dB
Work Temperature -10°~+90°
Degree of Protection IP54
Weight 0.35kg

Jkongmotor Other Hybrid Stepper Motor:

Motor series Phase No. Step angle Motor length Motor size Leads No. Holding torque
Nema 8 2 phase 1.8 degree 30~42mm 20x20mm 4 180~300g.cm
Nema 11 2 phase 1.8 degree 32~51mm 28x28mm 4 or 6 430~1200g.cm
Nema 14 2 phase 0.9 or 1.8 degree 27~42mm 35x35mm 4 1000~2000g.cm
Nema 16 2 phase 1.8 degree 20~44mm 39x39mm 4 or 6 650~2800g.cm
Nema 17 2 phase 0.9 or 1.8 degree 25~60mm 42x42mm 4 or 6 1.5~7.3kg.cm
Nema 23 2 phase 0.9 or 1.8 degree 41~112mm 57x57mm 4 or 6 or 8 0.39~3.1N.m
3 phase 1.2 degree 42~79mm 57x57mm 0.45~1.5N.m
Nema 24 2 phase 1.8 degree 56~111mm 60x60mm 8 1.17~4.5N.m
Nema 34 2 phase 1.8 degree 67~155mm 86x86mm 4 or 8 3.4~12.2N.m
3 phase 1.2 degree 65~150mm 86x86mm 2~7N.m
Nema 42 2 phase 1.8 degree 99~201mm 110x110mm 4 11.2~28N.m
3 phase 1.2 degree 134~285mm 110x110mm 8~25N.m
Nema 52 2 phase 1.8 degree 173~285mm 130x130mm 4 13.3~22.5N.m
3 phase 1.2 degree 173~285mm 130x130mm 13.3~22.5N.m
Above only for representative products, products of special request can be made according to the customer request.

 

Stepping Motor Customized

 

 

Detailed Photos

                                       Brushless Dc Motor Kit                                                                      Stepper Motor with Encoder

                   Linear Stepper Motor                              3 4 Axis Stepper Motor Kits                       Hollow Shaft Stepper Motor

 

                        Bldc Motor                                              Brushed Dc Motor                                      Hybrid Stepper Motor                                   

 

Company Profile

HangZhou CHINAMFG Co., Ltd was a high technology industry zone in HangZhou, china. Our products used in many kinds of machines, such as 3d printer CNC machine, medical equipment, weaving printing equipments and so on.
JKONGMOTOR warmly welcome ‘OEM’ & ‘ODM’ cooperations and other companies to establish long-term cooperation with us.
Company spirit of sincere and good reputation, won the recognition and support of the broad masses of customers, at the same time with the domestic and foreign suppliers close community of interests, the company entered the stage of stage of benign development, laying a CHINAMFG foundation for the strategic goal of realizing only really the sustainable development of the company.

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Application: Printing Equipment
Speed: High Speed
Number of Stator: Two-Phase
Customization:
Available

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Currency: US$
Return&refunds: You can apply for a refund up to 30 days after receipt of the products.

brake motor

How do brake motors handle variations in brake torque and response time?

Brake motors are designed to handle variations in brake torque and response time to ensure reliable and efficient braking performance. These variations can arise due to different operating conditions, load characteristics, or specific application requirements. Here’s a detailed explanation of how brake motors handle variations in brake torque and response time:

  • Brake Design and Construction: The design and construction of brake systems in brake motors play a crucial role in handling variations in brake torque and response time. Brake systems typically consist of brake pads or shoes that press against a brake disc or drum to generate frictional forces and provide braking action. The materials used for the brake components, such as brake linings, can be selected or designed to offer a wide range of torque capacities and response characteristics. By choosing the appropriate materials and optimizing the brake system design, brake motors can accommodate variations in torque requirements and response times.
  • Brake Control Mechanisms: Brake motors employ different control mechanisms to manage brake torque and response time. These mechanisms can be mechanical, electrical, or a combination of both. Mechanical control mechanisms often utilize springs or levers to apply and release the brake, while electrical control mechanisms rely on electromagnets or solenoids to engage or disengage the brake. The control mechanisms can be adjusted or configured to modulate the brake torque and response time based on the specific needs of the application.
  • Brake Torque Adjustments: Brake motors may offer provisions for adjusting the brake torque to accommodate variations in load requirements. This can be achieved through the selection of different brake linings or by adjusting the spring tension or magnetic force within the brake system. By modifying the brake torque, brake motors can provide the necessary braking force to meet the demands of different operating conditions or load characteristics.
  • Response Time Optimization: Brake motors can be engineered to optimize the response time of the braking system. The response time refers to the time it takes for the brake to engage or disengage once the control signal is applied. Several factors can influence the response time, including the design of the control mechanism, the characteristics of the brake linings, and the braking system’s overall dynamics. By fine-tuning these factors, brake motors can achieve faster or slower response times as required by the application, ensuring effective and timely braking action.
  • Electronic Control Systems: In modern brake motors, electronic control systems are often employed to enhance the flexibility and precision of brake torque and response time adjustments. These systems utilize sensors, feedback mechanisms, and advanced control algorithms to monitor and regulate the brake performance. Electronic control allows for real-time adjustments and precise control of the brake torque and response time, making brake motors more adaptable to variations in operating conditions and load requirements.

By combining appropriate brake design and construction, control mechanisms, torque adjustments, response time optimization, and electronic control systems, brake motors can effectively handle variations in brake torque and response time. This enables them to provide reliable and efficient braking performance across a wide range of operating conditions, load characteristics, and application requirements.

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

How do brake motors handle variations in load and stopping requirements?

Brake motors are designed to handle variations in load and stopping requirements by incorporating specific features and mechanisms that allow for flexibility and adaptability. These features enable brake motors to effectively respond to changes in load conditions and meet the diverse stopping requirements of different applications. Here’s a detailed explanation of how brake motors handle variations in load and stopping requirements:

1. Adjustable Braking Torque: Brake motors often have adjustable braking torque, allowing operators to modify the stopping force according to the specific load requirements. By adjusting the braking torque, brake motors can accommodate variations in load size, weight, and inertia. Higher braking torque can be set for heavier loads, while lower braking torque can be selected for lighter loads, ensuring optimal stopping performance and preventing excessive wear or damage to the braking system.

2. Controlled Response Time: Brake motors provide controlled response times, allowing for precise and efficient stopping according to the application requirements. The response time refers to the duration between the command to stop and the actual cessation of rotation. Brake motors can be designed with adjustable response times, enabling operators to set the desired stopping speed based on the load characteristics and safety considerations. This flexibility ensures that the braking action is appropriately matched to the load and stopping requirements.

3. Dynamic Braking: Dynamic braking is a feature found in some brake motors that helps handle variations in load and stopping requirements. When the motor is de-energized, dynamic braking converts the kinetic energy of the rotating load into electrical energy, which is dissipated as heat through a resistor or regenerative braking system. This braking mechanism allows brake motors to handle different load conditions and varying stopping requirements, dissipating excess energy and bringing the rotating equipment to a controlled stop.

4. Integrated Control Systems: Brake motors often come equipped with integrated control systems that allow for customized programming and adjustment of the braking parameters. These control systems enable operators to adapt the braking performance based on the load characteristics and stopping requirements. By adjusting parameters such as braking torque, response time, and braking profiles, brake motors can handle variations in load and achieve the desired stopping performance for different applications.

5. Monitoring and Feedback: Some brake motor systems incorporate monitoring and feedback mechanisms to provide real-time information about the load conditions and stopping performance. This feedback can include data on motor temperature, current consumption, or position feedback from encoders or sensors. By continuously monitoring these parameters, brake motors can dynamically adjust their braking action to accommodate variations in load and ensure optimal stopping performance.

6. Adaptable Brake Design: Brake motors are designed with consideration for load variations and stopping requirements. The brake design takes into account factors such as braking surface area, material composition, and cooling methods. These design features allow brake motors to handle different load conditions effectively and provide consistent and reliable stopping performance under varying circumstances.

By incorporating adjustable braking torque, controlled response time, dynamic braking, integrated control systems, monitoring and feedback mechanisms, and adaptable brake designs, brake motors can handle variations in load and stopping requirements. These features enhance the versatility and performance of brake motors, making them suitable for a wide range of applications across different industries.

China Standard NEMA 11 17 23 34 Geared Stepper Motor 42 57 86mm Hybrid Step Motor 17HS4401 12V 24V Stepping Motor with Planetary Gearbox / Brake / Encoder for 3D Printer   vacuum pump distributorsChina Standard NEMA 11 17 23 34 Geared Stepper Motor 42 57 86mm Hybrid Step Motor 17HS4401 12V 24V Stepping Motor with Planetary Gearbox / Brake / Encoder for 3D Printer   vacuum pump distributors
editor by CX 2023-10-20