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Address: Kaifull Industrial Part, Goabu Industrial Area, Donguan, Guangdong, China, 523287
Contact name:Bruce Niu
Shenzhen Zion Kaifull Automation Technology Co., Ltd. |
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57HS145/185/190 Series Eight Wires 2 Phase Hybrid Stepper Motors
1. Product Overview
Step motor is a motor that converts the electrical pulse signal into the corresponding angle displacement or the line displacement. It can use the quantity and frequency of the pulse to control the rotation (rotation angle, rotation speed) in automation applications. For each of the pulse, the motor rotor rotates a angle or forward, and its output angle shift or line displacement is proportional to the input pulse, and the speed is proportional to the pulse frequency. Therefore, step motor is also called pulse motor.
In the case of non-overload, the speed of the motor and the stop position depends only on the frequency and number of the pulsed input, without being affected by the load change. That is to say, add a pulse signal to the motor, and the motor turns a step distance. The advantage of this linear relationship between pulse and angle rotation, plus that a step motor only has periodic errors without cumulative errors, make step motor widely used in automation speed, position and other control fields easily.
With the development of product research and development of technology, the performance of the step system has been even more improved. If the stepper system is not overloaded, there will be no step loss mostly nowadays, and life time very long, almost no need maintenance, which makes steppers popular and widely used in many kinds of industrial automation motion control applications.
Currently, stepper motors are widely used in the field of motion control. Below is a brief introduction to several issues that need to be noted when use hybrid stepper motors.
The torque of the stepper motor will decrease as the speed increases.
When the stepper motor rotates, the inductance of each phase winding of the motor will form a reverse electromotive force. The higher the speed, the greater the reverse electromotive force. In this case, the phase current of the motor decreases with the increase of frequency (or speed), resulting in a decrease in torque.
The stepper motor can work well at low speeds, but if it exceeds a certain speed, it may not start or there may be strong noise whistling.
The stepper motor has a technical parameter: no-load starting frequency, which is the pulse frequency at which the stepper motor can start normally under no-load conditions. If the pulse frequency is higher than this value, the motor cannot start normally and may experience step loss or rotor blockage. With load, the starting frequency should be lower. If the motor is to achieve high-speed rotation, there should be an acceleration process in the pulse frequency, that is to say the starting frequency should be lower, and then a certain acceleration should be applied to reach the desired high frequency (the motor speed should increase from low speed to high speed).
How to overcome the vibration and noise of two-phase hybrid stepper motors during low-speed operation?
The inherent drawbacks of stepper motors are high vibration and noise during low-speed rotation, which can generally be overcome by the following solutions:
A. If the stepper motor works exactly in the resonance zone, mechanical transmission such as changing the reduction ratio can avoid the resonance zone;
B. The most commonly used and convenient method is to use drivers with subdivision functions;
C. Replace with a stepper motor with a smaller step angle, such as a three-phase or five phase stepper motor.
The Applications of Kaifull PRMCAS Hybrid Stepper Motors
Kaifull hybrid stepper motors are mainly used in digital control systems, with high accuracy and reliable operation. If position detection and speed feedback are used, closed-loop control can also be achieved. Stepper motors have been widely used in digital control systems, such as digital to analog conversion devices, CNC machine tools, computer peripherals, automatic recorders, clocks, etc. In addition, they have also been applied in industrial automation production lines, printing equipment, etc.
The application scenarios of Kaifull stepper motors are very wide, and the following are some application examples:
Industrial field: Stepper motors are used in automotive instrumentation, machine tool automation production equipment, robot manufacturing, inspection, and process flow.
Security field: Used for monitoring products, such as PAN/ZOOM/TILT for security cameras.
Medical field; Hydraulic pumps, ventilators, and blood analyzers used in medical scanners, samplers, digital oral photography.
In the field of consumer electronics, it is used in various stages of electronic product production, such as solder paste printing, SMT placement, reflow soldering, visual inspection, production of cables with terminals, dispensing machines, screen laminating machines, 3D printers, etc.
Precision equipment and instruments: used in ATM machines, inkjet printers, engraving machines, photo machines, spray painting equipment, computer peripherals and massive data storage devices, precision instruments, industrial control information systems, office automation, robots and other fields, especially suitable for applications with smooth operation, low noise, fast response, long service life, and high output torque.
Textile machinery: It is widely used in textile machinery equipment such as computerized embroidery machines. These stepper motors have the characteristics of low torque retention, fast response speed, low operating noise, stable operation, good control performance, and low overall cost.
Flat mobile devices: such as laser cutting machines, printers, scanners, etc.
Measurement instruments: such as high-precision 3D scanners, optical measurement equipment, etc.
Medical equipment: used for medical and surgical instruments, etc.
Camera lens. Used for focusing and moving optical devices, etc.
These application scenarios typically require stepper motors to have characteristics such as high precision, low noise, fast response, and long lifespan to meet the positioning, control, and performance requirements of different industries.
2. Hybrid Stepper Motor General Technical Specifications
| Step Angle | 1.8° (2 Phase) |
| Step Angle Accuracy | 0.09° |
| Shaft Type | Single, Dia. 6.35mm (Customizable) |
| Max. Temperature Rise | Less than 80 °C (Rated Current) |
| Max. Surface Temperatures | Max Allowed 100℃ |
| Ambient Temperature | -20 °C ~ +50 °C |
| Insulation Grade | 100 MΩ Min. , Class B |
| Dielectric Strengt | 500 VAC for 1 Minute |
| Max. Axial Load | 15N |
| Max. Radial Load | 90N (10mm from mounting Surface) |
| Certificates | Rohs, CE, CCC (As per Customer Need) |
3. Hybrid Stepper motor Performance Datasheet
| Model | Current | Resistance | Inductance | Holding Torque | Matching Driver | Rotor Inertia | Bi/Unipolar | Weight | Length |
| A/Ø | Ω/Ø | mH/Ø | N.m | g.cm2 | # of Leads | kg | mm | ||
57HS145/180/190 | 4.24 | 1.0 | 1.7 | 14.5 | Y2SD2 | 450 | Uni(8) |
1.05 |
76.6 |
| 2.97 | 2.0 | 6.62 | 18.5 | Y2SD2 | 450 | Bi-serial (8) | |||
| 5.94 | 0.5 | 1.7 | 19.0 | Y2SD3 | 450 | Bi-paral (8) |
4. Mechanical Dimensions (in mm)
5. Wiring Diagram
