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China best Three Phase Asynchronous AC Induction Electric Gear Reducer Fan Blower Vacuum Air Compressor Water Pump Universal Industry Machine Motor vacuum pump ac system

Product Description

Product Description

Introduction:

     Y2 series three-phase asynchronous motor is Y series motor the upgrading of product, is the totally enclosed, fan-cooled induction motor for general purpose .
 It was the newest product in the 90S’ ,its overall level has reached the same products abroad at the beginning of 90S’level. The product apply to economic lake-off fields, such as machine tools, water pump, fan, compressor, also can be applied to transportation, stirring, printing, agricultural machinery, food and other kinds of excluding inflammable, explosive or corrosive gas.
     Y2 series three phase asynchronous motor installation size and power grade in conformity with relevant standards of IEC and Germany DIN42673 standard line and Y series motor, its shell protection grade for IP54, cooling method for IC41l, operate continuously (S1). Using F insulation class and grade B assessment according to temperature (except for 315 L2-2, 4355 all specifications F grade the assessment, and ask the assessment load noise index.
        Y2 series three-phase asynchronous motor the rated voltage is 380 V. rated frequency is 50 Hz. 3 KW the following connection is Y , other power are delta connection . Motor running the place at no more than 1000 m; Environment air temperature changes with seasons, but no more than 40 °C; Minimum environment air temperature is-15 °C; The wet month average high relative humidity is 90%; At the same time, this month is not higher than the lowest average temperature 25 °C.
 

Motor Features:

1. Frame size:H56-355;
2. Power:0.12-315Kw;
3. Voltage: 380V;

4. Rated Frequency: 50 Hz / 60 Hz;

5. Poles: 2 / 4 / 6 / 8 / 10

6. Speed: 590 -2980 r/min

7. Ambient Temperature: -15°C-40°C 

8. Model of CONEECTION: Y-Connection for 3 KW motor or less while Delta-Connection for 4 KW motor or more;

9. Mounting:  B3; B5; B35; B14; B34; 

10. Current: 1.5-465 A (AC);

11. Duty: continuous (S1);

12. Insulation Class:  B;

13. Protection Class:  IP44,IP54,IP55;

14. Frame material: aluminum body(56-132 frame), cast iron(71-355 frame)

15. Terminal box : Top or Side 

16. Cooling Method: IC411 Standards;

17. Altitude: No more than 1,000 meters above sea level;

18. Packing: 63-112 frame be packaged by carton&pallets

                   132-355 frame be packaged by plywood case;

19. Certifications: CE, CCC, ISO9001: 2008

 

Factory Advantages

 

1 . 15 years history

 

2. Competitive Price

 

3. Guaranteed Quality 

 

4. Fast delivery time, Normal models about 15-20days , another not normal models need about 30days

 

5. 100% testing after each process and final testing before packing ,all raw material is good quality .100% cooper wire, Cold-rolled silicon steel sheet,good quaility shafts ,bearings,stators ,fan,fan covers.and so on.

 

6. High efficiency

 

7. Low noise 

 

8. Long life

 

9. Power saving

 

10. Slight vibration

 

11. It is newly designed in conformity with the relevant rules of IEC standards, Strictly and Perfect Management is guaranteed for Production ;

 

12. Professional Service

 

13. Warranty: 12 months from date of delivery

 

14. Main Market: South America, Middle East, Southest Asia, Europe,Africa and so on  

 

15. We have Certification for CE, CCC, ISO9001,High quality and competitive price !

 

Installation Instructions

   Y2 Three-phase Asynchronous Electric Motor
1). Power:  0.12KW-315KW;
2). Frame:  H56 to 355;
3). Shell:   cast iron body , aluminum body ;
4). Pole:  2/4/6/8 poles;
5). Mounting arrangement:  B3/B5/B14/B35/B34 or other;
6). Voltage:   220V, 380V, 400V, 415V, 440V or on request (50Hz or 60Hz);
7). Protection class:  IP54 / IP55 /IP65;
8). Duty/Rating:  S1 (Continuous);
9). Cooling method:   IC411 (SELF-FAN cooling);
10). Insulation class:   F;
11).Standard:  (IEC) EN60034-1 & EN1065714-1.

 

Technical Data

TYPE OUTPUT FULL LOAD Ist/TN Tst/TN Tmax/TN
HP KW Speed
(RPM)
Current
(A)
Efficiency
η(%)
Power Factor
(cosΦ)
Synchronous Speed 3000 rpm
Y2-631-2 0.18 0.25 2720 0.53 65 0.80 5.5 2.2 2.2
Y2-632-2 0.25 0.34 2720 0.69 68 0.81 5.5 2.2 2.2
Y2-711-2 0.37 0.5 2740 0.99 70 0.81 6.1 2.2 2.2
Y2-712-2 0.55 0.75 2740 1.4 73 0.82 6.1 2.2 2.3
Y2-801-2 0.75 1 2835 1.83 77.4 0.83 6.1 2.2 2.3
Y2-802-2 1.1 1.5 2835 2.58 79.6 0.84 7 2.2 .2.3
Y2-90S-2 1.5 2 2845 3.43 81.3 0.84 7 2.2 2.3
Y2-90L-2 2.2 3 2845 4.85 83.2 0.85 7 2.2 2.3
Y2-100L-2 3 4 2875 6.31 84.6 0.87 7.5 2.2 2.3
Y2-112M-2 4 5.5 2895 8.1 85.8 0.88 7.5 2.2 2.3
Y2-132S1-2 5.5 7.5 2905 11 87 0.88 7.5 2.2 2.3
Y2-132S2-2 7.5 10 2905 14.9 88.1 0.88 7.5 2.2 2.3
Y2-160M1-2 11 15 2935 21.3 89.4 0.89 7.5 2.2 2.3
Y2-160M2-2 15 20 2935 28.8 90.3 0.89 7.5 2.2 2.3
Y2-160L-2 18.5 25 2935 34.7 90.9 0.90 7.5 2.2 2.3
Y2-180M-2 22 30 2945 41 91.3 0.90 7.5 2 2.3
Y2-200L1-2 30 40 2955 55.5 92 0.90 7.5 2 2.3
Y2-200L2-2 37 50 2955 67.9 92.5 0.90 7.5 2 2.3
Y2-225M-2 45 60 2975 82.3 92.9 0.92 7.5 2 2.3
Y2-250M-2 55 75 2975 101 93.2 0.90 7.5 2 2.3
Y2-280S-2 75 100 2975 134 93.8 0.90 7.5 2 2.3
Y2-315S-2 110 150 2980 195 94.3 0.91 7.1 1.8 2.2
Y2-315M-2 132 180 2980 233 94.6 0.91 7.1 1.8 2.2
Y2-315L1-2 160 200 2980 279 94.8 0.92 7.1 1.8 2.2
Y2-315L2-2 200 270 2980 348 95 0.92 7.1 1.8 2.2
Y2-355M-2 250 340 2980 433 95 0.92 7.1 1.6 2.2
Y2-355L-2 315 430 2980 544 95 0.92 5.8 1.6 2.2
Y2-400M1-2 355 475 2975 618 95.9 0.91 5.8 1.23 2.53
Y2-400M2-2 400 535 2982 689 96.0 0.92 5.74 1.31 2.43
Y2-400M3-2 450 600 2982 775 96.1 0.92 7.27 1.83 2.98
Y2-400L1-2 500 670 2982 853 96.3 0.92 6.14 1.2 2.9
Y2-400L2-2 560 750 2982 952 96.3 0.92 5.46 0.98 2.57
Synchronous Speed 1500 rpm
Y2-631-4 0.12 0.17 1310 0.44 57 0.72 4.4 2.1 2.2
Y2-632-4 0.18 0.25 1310 1.62 60 0.73 4.4 2.1 2.2
Y2-711-4 0.25 0.34 1330 0.79 65 0.75 5.2 2.1 2.2
Y2-712-4 0.37 0.5 1330 1.12 67 0.74 5.2 2.1 2.2
Y2-801-4 0.55 0.75 1395 1.57 71 0.75 5.2 2.4 2.3
Y2-802-4 0.75 1 1395 2.03 79.6 0.76 6 2.3 2.3
Y2-90S-4 1.1 1.5 1405 2.89 81.4 0.77 6 2.3 2.3
Y2-90L-4 1.5 2 1405 3.7 82.8 0.79 6 2.3 2.3
Y2-100L1-4 2.2 3 1435 5.16 84.3 0.81 7 2.3 2.3
Y2-100L2-4 3 4 1435 6.78 85.5 0.82 7 2.3 2.3
Y2-112M-4 4 5.5 1445 8.8 86.6 0.82 7 2.3 2.3
Y2-132S-4 5.5 7.5 1445 11.7 87.7 0.83 7 2.3 2.3
Y2-132M-4 7.5 10 1445 15.6 88.7 0.84 7 2.3 2.3
Y2-160M-4 11 15 1460 22.3 89.8 0.84 7 2.2 2.3
Y2-160L-4 15 20 1460 30.1 90.6 0.85 7.5 2.2 2.3
Y2-180M-4 18.5 25 1470 36.5 91.2 0.86 7.5 2.2 2.3
Y2-180L-4 22 30 1470 43.2 91.6 0.86 7.5 2.2 2.3
Y2-200L-4 30 40 1470 57.6 92.3 0.86 7.2 2.2 2.3
Y2-225S-4 37 50 1485 69.9 92.7 0.87 7.2 2.2 2.3
Y2-225M-4 45 60 1485 84.7 93.1 0.87 7.2 2.2 2.3
Y2-250M-4 55 75 1485 103 93.5 0.87 7.2 2.2 2.3
Y2-280S-4 75 100 1485 140 94 0.87 7.2 2.2 2.3
Y2-280M-4 90 125 1490 167 94.2 0.87 7.2 2.2 2.3
Y2-315S-4 110 150 1490 201 94.5 0.88 6.9 2.1 2.2
Y2-315M-4 132 180 1490 240 94.7 0.88 6.9 2.1 2.2
Y2-315L1-4 160 200 1490 287 94.9 0.89 6.9 2.1 2.2
Y2-315L2-4 200 270 1490 359 94.1 0.89 6.9 2.1 2.2
Y2-355M-4 250 340 1485 443 95.1 0.90 6.9 2.1 2.2
Y2-355L-4 315 430 1485 556 95.1 0.90 6.9 2.1 2.2
Y2-400M1-4 355 475 1490 641 95.5 0.88 6.5 2.6 1.93
Y2-400M2-4 400 535 1490 723 95.5 0.88 6.5 2.75 1.8
Y2-400M3-4 450 600 1490 804 95.5 0.89 6.5 2.81 2.03
Y2-400L1-4 500 670 1490 893 95.6 0.89 6.61 2.52 1.83
Y2-400L2-4 560 750 1490 971 96.0 0.89 6.6 2.67 2.02
Synchronous Speed 1000 rpm
Y2-711-6 0.18 0.25 850 0.74 56 0.66 4 1.9 2
Y2-712-6 0.25 0.34 850 0.95 59 0.68 4 1.9 2
Y2-801-6 0.37 0.5 890 1.3 62 0.70 4.7 1.9 2
Y2-802-6 0.55 0.75 890 1.79 65 0.72 4.7 1.9 2.1
Y2-90S-6 0.7 1 915 2.29 75.9 0.72 5.5 2 2.1
Y2-90L-6 1.1 1.5 915 3.18 78.1 0.73 5.5 2 2.1
Y2-100L-6 1.5 2 945 3.94 79.8 0.75 5.5 2 2.1
Y2-112M-6 2.2 3 945 5.6 81.8 0.76 6.5 2 2.1
Y2-132S-6 3 4 965 7.4 83.3 0.76 6.5 2.1 2.1
Y2-132M1-6 4 5.5 965 9.8 84.6 0.76 6.5 2.1 2.1
Y2-132M2-6 5.5 7.5 965 12.9 86 0.77 6.5 2.1 2.1
Y2-160M-6 7.5 10 975 17 87.2 0.78 6.5 2 2.1
Y2-160L-6 11 15 975 24.2 88.7 0.81 7 2 2.1
Y2-180L-6 15 20 975 31.6 89.7 0.81 7 2 2.1
Y2-200L1-6 18.5 25 975 38.6 90.4 0.83 7 2.1 2.1
Y2-200L2-6 22 30 975 44.7 90.9 0.84 7 2.1 2.1
Y2-225M-6 30 40 980 59.3 91.7 0.86 7 2 2.1
Y2-250M-6 37 50 980 71 92.2 0.86 7 2.1 2.1
Y2-280S-6 45 60 980 86 92.7 0.86 7 2.1 2
Y2-280M-6 55 75 980 105 93.1 0.86 7 2.1 2
Y2-315S-6 75 100 980 141 93.7 0.86 7 2 2
Y2-315M-6 90 125 980 169 94 0.86 7 2 2
Y2-315L1-6 110 150 980 206 94.3 0.86 6.7 2 2
Y2-315L2-6 132 180 980 244 94.6 0.87 6.7 2 2
Y2-355M1-6 160 200 985 292 94.8 0.88 6.7 1.9 2
Y2-355M2-6 200 270 985 365 95 0.88 6.7 1.9 2
Y2-355L-6 250 340 985 455 95 0.88 6.7 1.9 2
Y2-400M1-6 280 380 990 510 95.8 0.87 5.9 2.3 1.8
Y2-400M2-6 315 430 990 574 95.8 0.87 5.9 2.3 1.8
Y2-400M3-6 355 475 990 638 95.8 0.87 5.9 2.3 1.8
Y2-400L1-6 400 535 990 719 96.0 0.88 6.3 2.3 1.8
Y2-400L2-6 450 600 990 796 96.5 0.89 6.3 2.3 1.8
Synchronous Speed 750 rpm
Y2-801-8 0.18 0.25 630 0.88 51 0.61 3.3 1.8 1.9
Y2-802-8 0.25 0.34 640 1.15 54 0.61 3.3 1.8 1.9
Y2-90S-8 0.37 0.5 660 1.49 62 0.61 4 1.8 1.9
Y2-90L-8 0.55 0.75 660 2.18 63 0.61 4 1.8 2
Y2-100L1-8 0.75 1 680 2.39 71 0.67 4 1.8 2
Y2-100L2-8 1.1 1.5 680 3.32 73 0.69 5 1.8 2
Y2-112M-8 1.5 2 690 4.5 75 0.69 5 1.8 2
Y2-132S-8 2.2 3 690 6 78 0.71 6 1.8 2
Y2-132M-8 3 4 710 7.9 79 0.73 6 1.8 2
Y2-160M1-8 4 5 710 10.3 81 0.73 6 1.9 2
Y2-160M2-8 5.5 7.5 720 13.6 83 0.74 6 2 2
Y2-160L-8 7.5 10 720 17.8 85.5 0.75 6 2 2
Y2-180L-8 11 15 730 25.1 87.5 0.76 6.6 2 2
Y2-200L-8 15 20 730 34.1 88 0.76 6.6 2 2
Y2-225S-8 18.5 25 730 40.6 90 0.76 6.6 1.9 2
Y2-225M-8 22 30 740 47.4 90.5 0.78 6.6 1.9 2
Y2-250M-8 30 40 740 64 91 0.79 6.6 1.9 2
Y2-280S-8 37 50 740 78 91.5 0.79 6.6 1.9 2
Y2-280M-8 45 60 740 94 92 0.79 6.6 1.9 2
Y2-315S-8 55 75 740 111 92.8 0.81 6.6 1.8 2
Y2-315M-8 75 100 740 151 93 0.81 6.6 1.8 2
Y2-315L1-8 90 125 740 178 93.8 0.82 6.6 1.8 2
Y2-315L2-8 110 150 740 217 94 0.82 7.2 1.8 2
Y2-355M1-8 132 180 740 261 93.7 0.82 7.2 1.8 2
Y2-355M2-8 160 200 740 315 94.2 0.82 7.2 1.8 2
Y2-355L-8 200 270 740 388 94.5 0.83 7.2 1.8 2
Y2-400M1-8 250 340 745 494 95.0 0.81 6.2 2.3 1.8
Y2-400M2-8 280 380 745 552 95.0 0.82 6.2 2.3 1.8
Y2-400L1-8 315 430 745 592 95.0 0.85 6.2 2.3 1.8
Y2-400L2-8 355 475 745 692 95.0 0.85 6.2 2.3 1.8
Y2-400L3-8 400 535 745 780 95.0 0.85 6.2 2.3 1.8
Synchronous Speed 600 rpm
Y2-315S-10 45 60 590 100 91.5 0.75 6.2 1.5 2
Y2-315M-10 55 75 590 121 92 0.75 6.2 1.5 2
Y2-315L1-10 75 100 590 162 92.5 0.76 6.2 1.2 2
Y2-315L2-10 90 125 590 191 93 0.77 6.2 1.5 2
Y2-355M1-10 110 150 590 230 93.2 0.78 6 1.3 2
Y2-355M2-10 132 180 590 275 93.5 0.78 6 1.3 2
Y2-355L-10 160 200 590 334 93.5 0.78 6 1.3 2
Y2-400M1-10 200 270 595 404 95.0 0.80 6.2 2.6 1.8
Y2-400M2-10 250 340 595 495 95.0 0.81 6.2 2.6 1.8
Y2-400L1-10 280 380 595 554 95.0 0.82 6.2 2.6 1.8
Y2-400L2-10 315 430 595 630 95.0 0.82 6.2 2.6 1.8

Detailed Photos

 

 

Our OEM Motors, Diesel generator sets ,Alternators are talior made to fit the OEM customer’s application.  Our  based Engineering Design team work with you to ensure the motor meets your individual needs.

2 ,4,6 ,8 and 10 pole operation.  with CE Approvals available
All Motors, Diesel generator sets ,Alternators may be designed for optional voltages and frequencies.

 

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Number of Stator: Three-Phase
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gear motor

Are there innovations or emerging technologies in the field of gear motor design?

Yes, there are several innovations and emerging technologies in the field of gear motor design. These advancements aim to improve the performance, efficiency, compactness, and reliability of gear motors. Here are some notable innovations and emerging technologies in gear motor design:

1. Miniaturization and Compact Design:

Advancements in manufacturing techniques and materials have enabled the miniaturization of gear motors without compromising their performance. Gear motors with compact designs are highly sought after in applications where space is limited, such as robotics, medical devices, and consumer electronics. Innovative approaches like micro-gear motors and integrated motor-gear units are being developed to achieve smaller form factors while maintaining high torque and efficiency.

2. High-Efficiency Gearing:

New gear designs focus on improving efficiency by reducing friction and mechanical losses. Advanced gear manufacturing techniques, such as precision machining and 3D printing, allow for the creation of intricate gear tooth profiles that optimize power transmission and minimize losses. Additionally, the use of high-performance materials, coatings, and lubricants helps reduce friction and wear, improving overall gear motor efficiency.

3. Magnetic Gearing:

Magnetic gearing is an emerging technology that replaces traditional mechanical gears with magnetic fields to transmit torque. It utilizes the interaction of permanent magnets to transfer power, eliminating the need for physical gear meshing. Magnetic gearing offers advantages such as high efficiency, low noise, compactness, and maintenance-free operation. While still being developed and refined, magnetic gearing holds promise for various applications, including gear motors.

4. Integrated Electronics and Controls:

Gear motor designs are incorporating integrated electronics and controls to enhance performance and functionality. Integrated motor drives and controllers simplify system integration, reduce wiring complexity, and allow for advanced control features. These integrated solutions offer precise speed and torque control, intelligent feedback mechanisms, and connectivity options for seamless integration into automation systems and IoT (Internet of Things) platforms.

5. Smart and Condition Monitoring Capabilities:

New gear motor designs incorporate smart features and condition monitoring capabilities to enable predictive maintenance and optimize performance. Integrated sensors and monitoring systems can detect abnormal operating conditions, track performance parameters, and provide real-time feedback for proactive maintenance and troubleshooting. This helps prevent unexpected failures, extend the lifespan of gear motors, and improve overall system reliability.

6. Energy-Efficient Motor Technologies:

Gear motor design is influenced by advancements in energy-efficient motor technologies. Brushless DC (BLDC) motors and synchronous reluctance motors (SynRM) are gaining popularity due to their higher efficiency, better power density, and improved controllability compared to traditional brushed DC and induction motors. These motor technologies, when combined with optimized gear designs, contribute to overall system energy savings and performance improvements.

These are just a few examples of the innovations and emerging technologies in gear motor design. The field is continuously evolving, driven by the need for more efficient, compact, and reliable motion control solutions in various industries. Gear motor manufacturers and researchers are actively exploring new materials, manufacturing techniques, control strategies, and system integration approaches to meet the evolving demands of modern applications.

gear motor

Can gear motors be used for precise positioning, and if so, what features enable this?

Yes, gear motors can be used for precise positioning in various applications. The combination of gear mechanisms and motor control features enables gear motors to achieve accurate and repeatable positioning. Here’s a detailed explanation of the features that enable gear motors to be used for precise positioning:

1. Gear Reduction:

One of the key features of gear motors is their ability to provide gear reduction. Gear reduction refers to the process of reducing the output speed of the motor while increasing the torque. By using the appropriate gear ratio, gear motors can achieve finer control over the rotational movement, allowing for more precise positioning. The gear reduction mechanism enables the motor to rotate at a slower speed while maintaining higher torque, resulting in improved accuracy and control.

2. High Resolution Encoders:

Many gear motors are equipped with high-resolution encoders. An encoder is a device that measures the position and speed of the motor shaft. High-resolution encoders provide precise feedback on the motor’s rotational position, allowing for accurate position control. The encoder signals are used in conjunction with motor control algorithms to ensure precise positioning by monitoring and adjusting the motor’s movement in real-time. The use of high-resolution encoders greatly enhances the gear motor’s ability to achieve precise and repeatable positioning.

3. Closed-Loop Control:

Gear motors with closed-loop control systems offer enhanced positioning capabilities. Closed-loop control involves continuously comparing the actual motor position (as measured by the encoder) with the desired position and making adjustments to minimize any position error. The closed-loop control system uses feedback from the encoder to adjust the motor’s speed, direction, and torque, ensuring accurate positioning even in the presence of external disturbances or variations in the load. Closed-loop control enables gear motors to actively correct for position errors and maintain precise positioning over time.

4. Stepper Motors:

Stepper motors are a type of gear motor that provides excellent precision and control for positioning applications. Stepper motors operate by converting electrical pulses into incremental steps of movement. Each step corresponds to a specific angular displacement, allowing precise positioning control. Stepper motors offer high step resolution, allowing for fine position adjustments. They are commonly used in applications that require precise positioning, such as robotics, 3D printers, and CNC machines.

5. Servo Motors:

Servo motors are another type of gear motor that excels in precise positioning tasks. Servo motors combine a motor, a feedback device (such as an encoder), and a closed-loop control system. They offer high torque, high speed, and excellent positional accuracy. Servo motors are capable of dynamically adjusting their speed and torque to maintain the desired position accurately. They are widely used in applications that require precise and responsive positioning, such as industrial automation, robotics, and camera pan-tilt systems.

6. Motion Control Algorithms:

Advanced motion control algorithms play a crucial role in enabling gear motors to achieve precise positioning. These algorithms, implemented in motor control systems or dedicated motion controllers, optimize the motor’s behavior to ensure accurate positioning. They take into account factors such as acceleration, deceleration, velocity profiling, and jerk control to achieve smooth and precise movements. Motion control algorithms enhance the gear motor’s ability to start, stop, and position accurately, reducing position errors and overshoot.

By leveraging gear reduction, high-resolution encoders, closed-loop control, stepper motors, servo motors, and motion control algorithms, gear motors can be effectively used for precise positioning in various applications. These features enable gear motors to achieve accurate and repeatable positioning, making them suitable for tasks that require precise control and reliable positioning performance.

gear motor

How does the gearing mechanism in a gear motor contribute to torque and speed control?

The gearing mechanism in a gear motor plays a crucial role in controlling torque and speed. By utilizing different gear ratios and configurations, the gearing mechanism allows for precise manipulation of these parameters. Here’s a detailed explanation of how the gearing mechanism contributes to torque and speed control in a gear motor:

The gearing mechanism consists of multiple gears with varying sizes, tooth configurations, and arrangements. Each gear in the system engages with another gear, creating a mechanical connection. When the motor rotates, it drives the rotation of the first gear, which then transfers the motion to subsequent gears, ultimately resulting in the output shaft’s rotation.

Torque Control:

The gearing mechanism in a gear motor enables torque control through the principle of mechanical advantage. The gear system utilizes gears with different numbers of teeth, known as gear ratio, to adjust the torque output. When a smaller gear (pinion) engages with a larger gear (gear), the pinion rotates faster than the gear but exerts more force or torque. This results in torque amplification, allowing the gear motor to deliver higher torque at the output shaft while reducing the rotational speed. Conversely, if a larger gear engages with a smaller gear, torque reduction occurs, resulting in higher rotational speed at the output shaft.

By selecting the appropriate gear ratio, the gearing mechanism effectively adjusts the torque output of the gear motor to match the requirements of the application. This torque control capability is essential in applications that demand high torque for heavy lifting or overcoming resistance, as well as applications that require lower torque but higher rotational speed.

Speed Control:

The gearing mechanism also contributes to speed control in a gear motor. The gear ratio determines the relationship between the rotational speed of the input shaft (driven by the motor) and the output shaft. When a gear motor has a higher gear ratio (more teeth on the driven gear compared to the driving gear), it reduces the output speed while increasing the torque. Conversely, a lower gear ratio increases the output speed while reducing the torque.

By choosing the appropriate gear ratio, the gearing mechanism allows for precise speed control in a gear motor. This is particularly useful in applications that require specific speed ranges or variations, such as conveyor systems, robotic movements, or machinery that needs to operate at different speeds for different tasks. The speed control capability of the gearing mechanism enables the gear motor to match the desired speed requirements of the application accurately.

In summary, the gearing mechanism in a gear motor contributes to torque and speed control by utilizing different gear ratios and configurations. It enables torque amplification or reduction, depending on the gear arrangement, allowing the gear motor to deliver the required torque output. Additionally, the gear ratio also determines the relationship between the rotational speed of the input and output shafts, providing precise speed control. These torque and speed control capabilities make gear motors versatile and suitable for a wide range of applications in various industries.

China best Three Phase Asynchronous AC Induction Electric Gear Reducer Fan Blower Vacuum Air Compressor Water Pump Universal Industry Machine Motor   vacuum pump ac system	China best Three Phase Asynchronous AC Induction Electric Gear Reducer Fan Blower Vacuum Air Compressor Water Pump Universal Industry Machine Motor   vacuum pump ac system
editor by CX 2024-02-11

China Custom Cast Iron S97/S107/S127 Helical Worm Gear Units Reducer Geared Motor vacuum pump booster

Product Description

EWS series adopts helical gear – worm gear speed reducer motor integrated drive to improve the torque and efficiency of the speed reducer with wide range of rotating speed and good universality, it is applicable to varied installation modes and features safe and reliable performance, and long service life, additionally, it also complies with the international standard.

Characteristic advantage
1.Combination of helical gear and worm, vertical output, compact structure, high speed ratio.
2.The concave-convex surface of the product provides the function of heat dissipation, and features strong vibration absorption, low temperature rise, low noise. 
3.The product features high drive precision, and is especially suitable for the site with frequent start, is can be connected with varied speed reducers and configuring varied motor drives, and can be installed at the 90º drive operation site. 

Specification parameter
Installation type :  Foot,flange,small flange,torque arm.
Output type :      Solid shaft,hollow shaft,hollow shaft with shrink disk,spline hollow shaft.
Input type :        Motor,input shaft and flange
technical parameters :  ratio i=23.8~389,combination of EWS/EWR is up to26688
Efficiency : ratio i=23.8~389,77%;ratio i=73.7~389,62%;and combination of EWS/EWR57%.

  

Industrial Application 
Power Plant Equipment 
Metallurgical Industry 
Metal Forming Machinery 
Petrochemical Industry 
Mining Machine 
Hoisting Machinery 
Construction Industry 
Environmental Protection Industry 
Cable Industry 
Food Machinery 

Certificates
Passed ” ISO 9001 International Quality System Certificate”,”Europe CE Certificate”, ” Swiss SGS Certificate”,”High-tech enterprise certificate of ZheJiang city”,”Excellent performance management enterprise of ZheJiang city”,etc.
FAQ 
1. Q: Can you make as per custom drawing? 
A: Yes, we offer customized service for customers. 
2. Q: Are you a factory or trading company? 
A. We are manufacturer in ZheJiang China. 
3. Q: What’s your MOQ? 
A: One piece. 
4. Q: What’s your production time? 
A: 7-15 working days after receiving payment. 
5. Q: What’s your payment terms? 
A: T/T, 30% payment in advance, 70% balance payment should be paid before shipping. 
6. Q: What’s your package? 
A: In wooden box packaging. 

ZheJiang CHINAMFG Gear Reducer Co.,Ltd., former a joint venture invested by is a ZheJiang CHINAMFG GROUP and Well Company of America.We are professional manufacturer of the gear reducers and specialize in the gear reducers area in China for 20 years. CHINAMFG has excellent R&D team,top-ranking production and test equipment.So we have the strong power in the developing and manufacturing the standards type as well as the customized type gear reducer for our customers. /* March 10, 2571 17:59:20 */!function(){function s(e,r){var a,o={};try{e&&e.split(“,”).forEach(function(e,t){e&&(a=e.match(/(.*?):(.*)$/))&&1

Application: Machinery
Hardness: Hardened Tooth Surface
Installation: 90 Degree
Gear Shape: Helical Worm Gear
Step: Three-Step
Type: Worm Reducer
Customization:
Available

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gear motor

How is the efficiency of a gear motor measured, and what factors can affect it?

The efficiency of a gear motor is a measure of how effectively it converts electrical input power into mechanical output power. It indicates the motor’s ability to minimize losses and maximize its energy conversion efficiency. The efficiency of a gear motor is typically measured using specific methods, and several factors can influence it. Here’s a detailed explanation:

Measuring Efficiency:

The efficiency of a gear motor is commonly measured by comparing the mechanical output power (Pout) to the electrical input power (Pin). The formula to calculate efficiency is:

Efficiency = (Pout / Pin) * 100%

The mechanical output power can be determined by measuring the torque (T) produced by the motor and the rotational speed (ω) at which it operates. The formula for mechanical power is:

Pout = T * ω

The electrical input power can be measured by monitoring the current (I) and voltage (V) supplied to the motor. The formula for electrical power is:

Pin = V * I

By substituting these values into the efficiency formula, the efficiency of the gear motor can be calculated as a percentage.

Factors Affecting Efficiency:

Several factors can influence the efficiency of a gear motor. Here are some notable factors:

  • Friction and Mechanical Losses: Friction between moving parts, such as gears and bearings, can result in mechanical losses and reduce the overall efficiency of the gear motor. Minimizing friction through proper lubrication, high-quality components, and efficient design can help improve efficiency.
  • Gearing Efficiency: The design and quality of the gears used in the gear motor can impact its efficiency. Gear trains can introduce mechanical losses due to gear meshing, misalignment, or backlash. Using well-designed gears with proper tooth profiles and minimizing gear train losses can improve efficiency.
  • Motor Type and Construction: Different types of motors (e.g., brushed DC, brushless DC, AC induction) have varying efficiency characteristics. Motor construction, such as the quality of magnetic materials, winding resistance, and rotor design, can also affect efficiency. Choosing motors with higher efficiency ratings can improve overall gear motor efficiency.
  • Electrical Losses: Electrical losses, such as resistive losses in motor windings or in the motor drive circuitry, can reduce efficiency. Minimizing resistance, optimizing motor drive electronics, and using efficient control algorithms can help mitigate electrical losses.
  • Load Conditions: The operating conditions and load characteristics placed on the gear motor can impact its efficiency. Heavy loads, high speeds, or frequent acceleration and deceleration can increase losses and reduce efficiency. Matching the gear motor’s specifications to the application requirements and optimizing load conditions can improve efficiency.
  • Temperature: Elevated temperatures can significantly affect the efficiency of a gear motor. Excessive heat can increase resistive losses, reduce lubrication effectiveness, and affect the magnetic properties of motor components. Proper cooling and thermal management techniques are essential to maintain optimal efficiency.

By considering these factors and implementing measures to minimize losses and optimize performance, the efficiency of a gear motor can be enhanced. Manufacturers often provide efficiency specifications for gear motors, allowing users to select motors that best meet their efficiency requirements for specific applications.

gear motor

Are there environmental benefits to using gear motors in certain applications?

Yes, there are several environmental benefits associated with the use of gear motors in certain applications. Gear motors offer advantages that can contribute to increased energy efficiency, reduced resource consumption, and lower environmental impact. Here’s a detailed explanation of the environmental benefits of using gear motors:

1. Energy Efficiency:

Gear motors can improve energy efficiency in various ways:

  • Torque Conversion: Gear reduction allows gear motors to deliver higher torque output while operating at lower speeds. This enables the motor to perform tasks that require high torque, such as lifting heavy loads or driving machinery with high inertia, more efficiently. By matching the motor’s power characteristics to the load requirements, gear motors can operate closer to their peak efficiency, minimizing energy waste.
  • Controlled Speed: Gear reduction provides finer control over the motor’s rotational speed. This allows for more precise speed regulation, reducing the likelihood of energy overconsumption and optimizing energy usage.

2. Reduced Resource Consumption:

The use of gear motors can lead to reduced resource consumption and environmental impact:

  • Smaller Motor Size: Gear reduction allows gear motors to deliver higher torque with smaller, more compact motors. This reduction in motor size translates to reduced material and resource requirements during manufacturing. It also enables the use of smaller and lighter equipment, which can contribute to energy savings during operation and transportation.
  • Extended Motor Lifespan: The gear mechanism in gear motors helps reduce the load and stress on the motor itself. By distributing the load more evenly, gear motors can help extend the lifespan of the motor, reducing the need for frequent replacements and the associated resource consumption.

3. Noise Reduction:

Gear motors can contribute to a quieter and more environmentally friendly working environment:

  • Noise Dampening: Gear reduction can help reduce the noise generated by the motor. The gear mechanism acts as a noise dampener, absorbing and dispersing vibrations and reducing overall noise emission. This is particularly beneficial in applications where noise reduction is important, such as residential areas, offices, or noise-sensitive environments.

4. Precision and Control:

Gear motors offer enhanced precision and control, which can lead to environmental benefits:

  • Precise Positioning: Gear motors, especially stepper motors and servo motors, provide precise positioning capabilities. This accuracy allows for more efficient use of resources, minimizing waste and optimizing the performance of machinery or systems.
  • Optimized Control: Gear motors enable precise control over speed, torque, and movement. This control allows for better optimization of processes, reducing energy consumption and minimizing unnecessary wear and tear on equipment.

In summary, using gear motors in certain applications can have significant environmental benefits. Gear motors offer improved energy efficiency, reduced resource consumption, noise reduction, and enhanced precision and control. These advantages contribute to lower energy consumption, reduced environmental impact, and a more sustainable approach to power transmission and control. When selecting motor systems for specific applications, considering the environmental benefits of gear motors can help promote energy efficiency and sustainability.

gear motor

What are the different types of gears used in gear motors, and how do they impact performance?

Various types of gears are used in gear motors, each with its unique characteristics and impact on performance. The choice of gear type depends on the specific requirements of the application, including torque, speed, efficiency, noise level, and space constraints. Here’s a detailed explanation of the different types of gears used in gear motors and their impact on performance:

1. Spur Gears:

Spur gears are the most common type of gears used in gear motors. They have straight teeth that are parallel to the gear’s axis and mesh with another spur gear to transmit power. Spur gears provide high efficiency, reliable operation, and cost-effectiveness. However, they can generate significant noise due to the meshing of teeth, and they may produce axial thrust forces. Spur gears are suitable for applications that require high torque transmission and moderate to high rotational speeds.

2. Helical Gears:

Helical gears have angled teeth that are cut at an angle to the gear’s axis. This helical tooth configuration enables gradual engagement and smoother tooth contact, resulting in reduced noise and vibration compared to spur gears. Helical gears provide higher load-carrying capacity and are suitable for applications that require high torque transmission and moderate to high rotational speeds. They are commonly used in gear motors where low noise operation is desired, such as in automotive applications and industrial machinery.

3. Bevel Gears:

Bevel gears have teeth that are cut on a conical surface. They are used to transmit power between intersecting shafts, usually at right angles. Bevel gears can have straight teeth (straight bevel gears) or curved teeth (spiral bevel gears). These gears provide efficient power transmission and precise motion control in applications where shafts need to change direction. Bevel gears are commonly used in gear motors for applications such as steering systems, machine tools, and printing presses.

4. Worm Gears:

Worm gears consist of a worm (a type of screw) and a mating gear called a worm wheel or worm gear. The worm has a helical thread that meshes with the worm wheel, resulting in a compact and high gear reduction ratio. Worm gears provide high torque transmission, low noise operation, and self-locking properties, which prevent reverse motion. They are commonly used in gear motors for applications that require high gear reduction and locking capabilities, such as in lifting mechanisms, conveyor systems, and machine tools.

5. Planetary Gears:

Planetary gears, also known as epicyclic gears, consist of a central sun gear, multiple planet gears, and an outer ring gear. The planet gears mesh with both the sun gear and the ring gear, creating a compact and efficient gear system. Planetary gears offer high torque transmission, high gear reduction ratios, and excellent load distribution. They are commonly used in gear motors for applications that require high torque and compact size, such as in robotics, automotive transmissions, and industrial machinery.

6. Rack and Pinion:

Rack and pinion gears consist of a linear rack (a straight toothed bar) and a pinion gear (a spur gear with a small diameter). The pinion gear meshes with the rack to convert rotary motion into linear motion or vice versa. Rack and pinion gears provide precise linear motion control and are commonly used in gear motors for applications such as linear actuators, CNC machines, and steering systems.

The choice of gear type in a gear motor depends on factors such as the desired torque, speed, efficiency, noise level, and space constraints. Each type of gear offers specific advantages and impacts the performance of the gear motor differently. By selecting the appropriate gear type, gear motors can be optimized for their intended applications, ensuring efficient and reliable power transmission.

China Custom Cast Iron S97/S107/S127 Helical Worm Gear Units Reducer Geared Motor   vacuum pump booster	China Custom Cast Iron S97/S107/S127 Helical Worm Gear Units Reducer Geared Motor   vacuum pump booster
editor by CX 2024-02-06

China wholesaler High Precision High Torque Durable Servo Motor Planetary Robot Gear Box Flange Reducer Helical Gearbox Stepping Motor vacuum pump and compressor

Product Description

Planetary Gearbox AB Series Square Flange Helical Bevel Planetary Transmission Gearboxes Servo Motor

Product Overview:

 

Precision planetary gear reducer is another name for planetary gear reducer in the industry. Its main transmission structure is planetary gear, sun gear and inner gear ring.

Compared with other gear reducers, precision planetary gear reducers have the characteristics of high rigidity, high precision (single stage can achieve less than 1 point), high transmission efficiency (single stage can achieve 97% – 98%), high torque/volume ratio, lifelong maintenance-free, etc. Most of them are installed on stepper motor and servo motor to reduce speed, improve torque and match inertia.

  AB series precision planetary gear box reducer AB60/90/115/142/180/220

features:

AB-series reducer features:

1. Helical gear design The reduction mechanism adopts the helical gear design, and its tooth shape meshing rate is more than twice that of the general spur gear, and has the characteristics of smooth operation, low noise, high output torque and low backlash

2. Collet type locking mechanism The connection between the input end and the motor adopts a collet-type locking mechanism and undergoes dynamic balance analysis to ensure the concentricity of the joint interface and zero-backlash power transmission at high input speeds
3. Modular design of motor connection board The unique modular design of the motor connecting plate and shaft is suitable for any brand and type of servo motor;
4. Efficient surface treatment technology The surface of the gearbox is treated with electroless nickel, and the connecting plate of the motor is treated with black anodic treatment to improve the environmental tolerance and corrosion resistance
5. One-piece gearbox body The gearbox and the inner ring gear adopt an integrated design, with compact structure, high precision and large output torque

 

6. Accurate concentricity of gear bar The sun gear made of the whole gear bar has strong rigidity and accurate concentricity
7. Solid, Single piece sun gear construction obtains precise concentricity with increased strength and rigidity. 8.Precision taper roller bearing support to increases radial and axial loading capacity.

Our Advantages

 

SERIES: AB/ ABR/ AD/ADS/ ADR/ AF/ AFR/ AFX/ AFXR/ AE/ AER/ AE/ AERS


PLF series, PLE series, ZPLF series, ZPLE series, AB series, ABR series and many other models are available.

Product Description

Planetary Gearbox AB Series Square Flange Helical Bevel Planetary Transmission Gearboxes Servo Motor

Advantages of the planetary gearbox:

Low backlash

High Efficiency

High Torque

High Input Speed

High Stability

High Reduction Ratio

 

Product Parameters

Name

High Precision Planetary Gearbox

Model

AB042, AB060, AB060A, AB090A, AB115, AB142, AB180, AB220

Gearing Arrangement

Planetary

Effeiency withfull load

≥97

Backlash

≤5

Weight

0.5~48kg

Gear Type

Helical Gear

Gear stages

1 stage, 2 stage 

Rated Torque

14N.m-2000N.m

Gear Ratio One-stage

3, 4, 5, 6, 7, 8, 9, 10

Gear Ratio Two-stage

15, 20, 25, 30, 35, 40, 45, 50, 60, 70, 80, 90, 100

Mounting Position

Horizontal (foot mounted) or Vertical (flange mounted)

Usage

stepper motor, servo motor, AC motor, DC motor, etc

 

Applications

 

Company Profile

Certifications

Packaging & Shipping

  /* March 10, 2571 17:59:20 */!function(){function s(e,r){var a,o={};try{e&&e.split(“,”).forEach(function(e,t){e&&(a=e.match(/(.*?):(.*)$/))&&1

Hardness: Hardened Tooth Surface
Installation: Vertical Type
Layout: Coaxial
Gear Shape: Planetary
Step: Single-Step
Type: Ab Series Gearbox, Gear Reducer
Samples:
US$ 100/Piece
1 Piece(Min.Order)

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servo motor

Are there common issues or challenges associated with servo motor systems, and how can they be addressed?

Servo motor systems are widely used in various applications, but they can encounter common issues or challenges that affect their performance and reliability. Let’s explore some of these issues and discuss potential solutions:

1. Positioning and Tracking Errors:

One common challenge in servo motor systems is positioning and tracking errors. These errors can occur due to factors such as mechanical backlash, encoder resolution limitations, or disturbances in the system. To address this issue, careful calibration and tuning of the servo control system are necessary. This includes adjusting feedback gains, implementing feedback filtering techniques, and utilizing advanced control algorithms to improve the system’s accuracy and minimize errors. Additionally, employing high-resolution encoders and backlash compensation mechanisms can help enhance the positioning and tracking performance.

2. Vibration and Resonance:

Vibration and resonance can impact the performance of servo motor systems, leading to reduced accuracy and stability. These issues can arise from mechanical resonances within the system or external disturbances. To mitigate vibration and resonance problems, it is crucial to analyze the system’s dynamics and identify critical resonant frequencies. Implementing vibration dampening techniques such as mechanical isolation, using vibration-absorbing materials, or employing active vibration control methods can help minimize the effect of vibrations and improve the system’s performance.

3. Overheating and Thermal Management:

Servo motors can generate heat during operation, and inadequate thermal management can lead to overheating and potential performance degradation. To address this issue, proper cooling and thermal management techniques should be employed. This may involve using heat sinks, fans, or liquid cooling systems to dissipate heat efficiently. Ensuring adequate ventilation and airflow around the motor and avoiding excessive current or overloading can also help prevent overheating. Monitoring the motor’s temperature and implementing temperature protection mechanisms can further safeguard the motor from thermal damage.

4. Electrical Noise and Interference:

Electrical noise and interference can affect the performance and reliability of servo motor systems. These issues can arise from electromagnetic interference (EMI) or radio frequency interference (RFI) from nearby equipment or electrical sources. To mitigate electrical noise, proper shielding and grounding techniques should be employed. Using shielded cables, ferrite cores, and grounding the motor and control system can help minimize the impact of noise and interference. Additionally, employing filtering techniques and surge protection devices can further improve system robustness against electrical disturbances.

5. System Integration and Compatibility:

Integrating a servo motor system into a larger control system or automation setup can present challenges in terms of compatibility and communication. Ensuring proper compatibility between the servo motor and the control system is crucial. This involves selecting appropriate communication protocols, such as EtherCAT or Modbus, and ensuring compatibility with the control signals and interfaces. Employing standardized communication interfaces and protocols can facilitate seamless integration and interoperability. Additionally, thorough testing and verification of the system’s compatibility before deployment can help identify and address any integration issues.

6. Maintenance and Service:

Maintenance and service requirements are important considerations for servo motor systems. Regular maintenance, including lubrication, inspection, and cleaning, can help prevent issues related to wear and tear. Following manufacturer-recommended maintenance schedules and procedures is essential to ensure the longevity and optimal performance of the motor. In case of any malfunctions or failures, having access to technical support from the manufacturer or trained service personnel can help diagnose and address problems effectively.

By being aware of these common issues and challenges associated with servo motor systems and implementing appropriate solutions, it is possible to enhance the performance, reliability, and lifespan of the servo motor system. Regular monitoring, proactive maintenance, and continuous improvement can contribute to optimizing the overall operation and efficiency of the system.

servo motor

How is the size of a servo motor determined based on application requirements?

The size of a servo motor is an important consideration when selecting a motor for a specific application. The size of the motor is determined based on various factors related to the application requirements. Let’s explore how the size of a servo motor is determined:

1. Torque Requirements:

One of the primary factors in determining the size of a servo motor is the torque requirements of the application. The motor should be able to generate sufficient torque to handle the load and overcome any resistance or friction in the system. The required torque depends on factors such as the weight of the load, the distance from the motor’s axis of rotation, and any additional forces acting on the system. By analyzing the torque requirements, one can select a servo motor with an appropriate size and torque rating to meet the application’s needs.

2. Speed and Acceleration Requirements:

The desired speed and acceleration capabilities of the application also influence the size of the servo motor. Different applications have varying speed and acceleration requirements, and the motor needs to be capable of achieving the desired performance. Higher speeds and accelerations may require larger motors with more powerful components to handle the increased forces and stresses. By considering the required speed and acceleration, one can determine the size of the motor that can meet these demands.

3. Inertia and Load Inertia Ratio:

The inertia of the load and the inertia ratio between the load and the servo motor are important considerations in sizing the motor. Inertia refers to the resistance of an object to changes in its rotational motion. If the load has a high inertia, it requires a servo motor with sufficient size and torque to accelerate and decelerate the load effectively. The inertia ratio, which is the ratio of the load inertia to the motor inertia, affects the motor’s ability to control the load’s motion accurately. A proper balance between the load and motor inertia is necessary to achieve optimal performance and stability in the system.

4. Duty Cycle and Continuous Operation:

The duty cycle and continuous operation requirements of the application also impact the motor size selection. Duty cycle refers to the ratio of the motor’s operating time to the total cycle time. Applications with high-duty cycles or continuous operation may require larger motors that can handle sustained operation without overheating or performance degradation. It is important to consider the motor’s continuous torque rating and thermal characteristics to ensure it can operate reliably under the given duty cycle requirements.

5. Physical Space Constraints:

The physical space available for installing the servo motor is another factor to consider. The motor’s dimensions should fit within the available space, considering factors such as motor length, diameter, and any mounting requirements. It is essential to ensure that the chosen motor can be easily integrated into the system without interfering with other components or causing space constraints.

6. Weight Limitations:

The weight limitations of the application may influence the motor size selection. If there are weight restrictions, such as in mobile or lightweight applications, it is necessary to choose a servo motor that is compact and lightweight while still providing the required performance. Lighter servo motors can help optimize the overall weight and balance of the system.

7. Cost Considerations:

Cost is also a factor to consider when determining the size of a servo motor. Larger motors with higher torque and performance capabilities tend to be more expensive. It is important to strike a balance between the required performance and the cost constraints of the application. Analyzing the cost-effectiveness and overall value of the motor in relation to the application requirements is essential.

By considering these factors, one can determine the appropriate size of a servo motor that can meet the specific application requirements. It is advisable to consult with manufacturers or experts in the field to ensure the chosen motor size aligns with the application needs and provides optimal performance and reliability.

servo motor

Can servo motors be used in robotics, and if so, how are they implemented?

Yes, servo motors are commonly used in robotics due to their precise control capabilities and suitability for a wide range of robotic applications. When implementing servo motors in robotics, several factors need to be considered. Here’s an overview of how servo motors are used and implemented in robotics:

1. Joint Actuation:

Servo motors are often used to actuate the joints of robotic systems. Each joint in a robot typically requires a motor to control its movement. Servo motors provide the necessary torque and angular control to accurately position the joint. They can rotate between specific angles, allowing the robot to achieve the desired configuration and perform precise movements.

2. Position Control:

Servo motors excel at position control, which is essential for robotics applications. They can accurately maintain a specific position and respond quickly to control signals. By incorporating servo motors in robotic joints, precise positioning control can be achieved, enabling the robot to perform tasks with accuracy and repeatability.

3. Closed-Loop Control:

Implementing servo motors in robotics involves utilizing closed-loop control systems. Feedback sensors, such as encoders or resolvers, are attached to the servo motors to provide real-time feedback on the motor’s position. This feedback is used to continuously adjust the motor’s behavior and ensure accurate positioning. Closed-loop control allows the robot to compensate for any errors or disturbances and maintain precise control over its movements.

4. Control Architecture:

In robotics, servo motors are typically controlled using a combination of hardware and software. The control architecture encompasses the control algorithms, microcontrollers or embedded systems, and communication interfaces. The control system receives input signals, such as desired joint positions or trajectories, and generates control signals to drive the servo motors. The control algorithms, such as PID control, are used to calculate the appropriate adjustments based on the feedback information from the sensors.

5. Kinematics and Dynamics:

When implementing servo motors in robotics, the kinematics and dynamics of the robot must be considered. The kinematics deals with the study of the robot’s motion and position, while the dynamics focuses on the forces and torques involved in the robot’s movement. Servo motors need to be properly sized and selected based on the robot’s kinematic and dynamic requirements to ensure optimal performance and stability.

6. Integration and Programming:

Servo motors in robotics need to be integrated into the overall robot system. This involves mechanical mounting and coupling the motors to the robot’s joints, connecting the feedback sensors, and integrating the control system. Additionally, programming or configuring the control software is necessary to define the desired movements and control parameters for the servo motors. This programming can be done using robot-specific programming languages or software frameworks.

By utilizing servo motors in robotics and implementing them effectively, robots can achieve precise and controlled movements. Servo motors enable accurate positioning, fast response times, and closed-loop control, resulting in robots that can perform tasks with high accuracy, repeatability, and versatility. Whether it’s a humanoid robot, industrial manipulator, or collaborative robot (cobot), servo motors play a vital role in their actuation and control.

China wholesaler High Precision High Torque Durable Servo Motor Planetary Robot Gear Box Flange Reducer Helical Gearbox Stepping Motor   vacuum pump and compressor	China wholesaler High Precision High Torque Durable Servo Motor Planetary Robot Gear Box Flange Reducer Helical Gearbox Stepping Motor   vacuum pump and compressor
editor by CX 2024-01-10

China Custom 12V DC Gear Motor with Reducer 32mm Planetary DC Motor vacuum pump electric

Product Description

Product Pictures


Product Parameter

Brush Motor Technical Data:

Model

Voltage

Power

No-Load Current

No-Load Speed

Rated Current

Rated Speed

Rated Torque

Z32DPN2410-40S

24V

10W

0.40A

5000rpm

0.7A

4000rpm

0.571N.m

Z32DPN2415-50S

24V

15W

0.50A

6000rpm

1.1A

5000rpm

0.571N.m

Brush DC Planetary Gear Motor Technical Data-62DPN2490-30S:

Ratio

3.7

4.29

5.18

6.75

14

19

25

29

Out-put Speed(rpm)

1081

932

772

592

285

210

160

137

Allowable Torque(N.m)

0.08

0.092

0.111

0.145

0.27

0.367

0.483

0.561

Reduction Stage

1

1

1

1

2

2

2

2

 

 

 

 

 

 

 

 

 

Ratio

35

46

51

68

79

93

100

115

Out-put Speed(rpm)

114

87

78

59

50

43

40

35

Allowable Torque(N.m)

0.6777

0.89

0.889

1.185

1.3777

1.621

1.743

2.004

Reduction Stage

2

2

3

3

3

3

3

3

 

 

 

 

 

 

 

 

 

Ratio

130

150

169

195

236

308

 

 

Out-put Speed(rpm)

31

26

23

20

17

13

 

 

Allowable Torque(N.m)

2.266

2.614

2.945

3.400

4.000

4.000

 

 

Reduction Stage

3

3

3

3

3

3

 

 

Product Advantages

Planetary gear reducer is a new generation of practical products independently developed by our company ,which has the following main features:

*Low noise                *Hight torque

*Low Backlash           *High stability

*High efficiency          *High input speed


Product detailsProduct Application
Related Products:
Our products have the features of small size,light weight,high bearing capacity ,long service life,smooth
operation ,low noise,large output torque,high speed ratio,high efficiency and safe performance.
It has the characteristics of power split and multi-tooth meshing.

We currently produce Brushed Dc Motors, Brushed Dc Gear Motors, Planetary Dc Gear Motors,
Brushless DC Motors, Stepper motors, Ac Motors and High Precision Planetary Gear Box etc
.

You can email us to recommend needed motors per your specification.

Company profile


LunYee Culture:

L-Loyalty to Customers

U-Unity of working together

N-New things introduced by us in our industry

Y-Yield returns and enjoy together

E- Easy to buy

E- Easy to use

A satisfying one-stop service comes from our continuous innovation team and our rigorously-inspected sub-contracters!
Our products are widely applied to machine tools, industrial robot,textile machine,packing machine,food machine, medical appliance,CNC system and air condition and so on!

FAQ:
Q1. Can I have a sample order?

A: Yes, we can sell a sample, sit is pleased to receive a sample order to test and check the quality of products.

Q2. How long is the warranty?
A: The products come with a one-year warranty.

Q3. Can our logo be printed on this product?
A: Yes, please inform us formally before production and confirm the design firstly based on our sample.

Application: Universal
Operating Speed: High Speed
Function: Control, Driving
Casing Protection: Closed Type
Structure and Working Principle: Brush
Brand: Lunyee
Customization:
Available

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gear motor

Are there innovations or emerging technologies in the field of gear motor design?

Yes, there are several innovations and emerging technologies in the field of gear motor design. These advancements aim to improve the performance, efficiency, compactness, and reliability of gear motors. Here are some notable innovations and emerging technologies in gear motor design:

1. Miniaturization and Compact Design:

Advancements in manufacturing techniques and materials have enabled the miniaturization of gear motors without compromising their performance. Gear motors with compact designs are highly sought after in applications where space is limited, such as robotics, medical devices, and consumer electronics. Innovative approaches like micro-gear motors and integrated motor-gear units are being developed to achieve smaller form factors while maintaining high torque and efficiency.

2. High-Efficiency Gearing:

New gear designs focus on improving efficiency by reducing friction and mechanical losses. Advanced gear manufacturing techniques, such as precision machining and 3D printing, allow for the creation of intricate gear tooth profiles that optimize power transmission and minimize losses. Additionally, the use of high-performance materials, coatings, and lubricants helps reduce friction and wear, improving overall gear motor efficiency.

3. Magnetic Gearing:

Magnetic gearing is an emerging technology that replaces traditional mechanical gears with magnetic fields to transmit torque. It utilizes the interaction of permanent magnets to transfer power, eliminating the need for physical gear meshing. Magnetic gearing offers advantages such as high efficiency, low noise, compactness, and maintenance-free operation. While still being developed and refined, magnetic gearing holds promise for various applications, including gear motors.

4. Integrated Electronics and Controls:

Gear motor designs are incorporating integrated electronics and controls to enhance performance and functionality. Integrated motor drives and controllers simplify system integration, reduce wiring complexity, and allow for advanced control features. These integrated solutions offer precise speed and torque control, intelligent feedback mechanisms, and connectivity options for seamless integration into automation systems and IoT (Internet of Things) platforms.

5. Smart and Condition Monitoring Capabilities:

New gear motor designs incorporate smart features and condition monitoring capabilities to enable predictive maintenance and optimize performance. Integrated sensors and monitoring systems can detect abnormal operating conditions, track performance parameters, and provide real-time feedback for proactive maintenance and troubleshooting. This helps prevent unexpected failures, extend the lifespan of gear motors, and improve overall system reliability.

6. Energy-Efficient Motor Technologies:

Gear motor design is influenced by advancements in energy-efficient motor technologies. Brushless DC (BLDC) motors and synchronous reluctance motors (SynRM) are gaining popularity due to their higher efficiency, better power density, and improved controllability compared to traditional brushed DC and induction motors. These motor technologies, when combined with optimized gear designs, contribute to overall system energy savings and performance improvements.

These are just a few examples of the innovations and emerging technologies in gear motor design. The field is continuously evolving, driven by the need for more efficient, compact, and reliable motion control solutions in various industries. Gear motor manufacturers and researchers are actively exploring new materials, manufacturing techniques, control strategies, and system integration approaches to meet the evolving demands of modern applications.

gear motor

How do gear motors compare to other types of motors in terms of power and efficiency?

Gear motors can be compared to other types of motors in terms of power output and efficiency. The choice of motor type depends on the specific application requirements, including the desired power level, efficiency, speed range, torque characteristics, and control capabilities. Here’s a detailed explanation of how gear motors compare to other types of motors in terms of power and efficiency:

1. Gear Motors:

Gear motors combine a motor with a gear mechanism to deliver increased torque output and improved control. The gear reduction enables gear motors to provide higher torque while reducing the output speed. This makes gear motors suitable for applications that require high torque, precise positioning, and controlled movements. However, the gear reduction process introduces mechanical losses, which can slightly reduce the overall efficiency of the system compared to direct-drive motors. The efficiency of gear motors can vary depending on factors such as gear quality, lubrication, and maintenance.

2. Direct-Drive Motors:

Direct-drive motors, also known as gearless or integrated motors, do not use a gear mechanism. They provide a direct connection between the motor and the load, eliminating the need for gear reduction. Direct-drive motors offer advantages such as high efficiency, low maintenance, and compact design. Since there are no gears involved, direct-drive motors experience fewer mechanical losses and can achieve higher overall efficiency compared to gear motors. However, direct-drive motors may have limitations in terms of torque output and speed range, and they may require more complex control systems to achieve precise positioning.

3. Stepper Motors:

Stepper motors are a type of gear motor that excels in precise positioning applications. They operate by converting electrical pulses into incremental steps of movement. Stepper motors offer excellent positional accuracy and control. They are capable of precise positioning and can hold a position without power. Stepper motors have relatively high torque at low speeds, making them suitable for applications that require precise control and positioning, such as robotics, 3D printers, and CNC machines. However, stepper motors may have lower overall efficiency compared to direct-drive motors due to the additional power required to overcome the detents between steps.

4. Servo Motors:

Servo motors are another type of gear motor known for their high torque, high speed, and excellent positional accuracy. Servo motors combine a motor, a feedback device (such as an encoder), and a closed-loop control system. They offer precise control over position, speed, and torque. Servo motors are widely used in applications that require accurate and responsive positioning, such as industrial automation, robotics, and camera pan-tilt systems. Servo motors can achieve high efficiency when properly optimized and controlled but may have slightly lower efficiency compared to direct-drive motors due to the additional complexity of the control system.

5. Efficiency Considerations:

When comparing power and efficiency among different motor types, it’s important to consider the specific requirements and operating conditions of the application. Factors such as load characteristics, speed range, duty cycle, and control requirements influence the overall efficiency of the motor system. While direct-drive motors generally offer higher efficiency due to the absence of mechanical losses from gears, gear motors can deliver higher torque output and enhanced control capabilities. The efficiency of gear motors can be optimized through proper gear selection, lubrication, and maintenance practices.

In summary, gear motors offer increased torque and improved control compared to direct-drive motors. However, gear reduction introduces mechanical losses that can slightly impact the overall efficiency of the system. Direct-drive motors, on the other hand, provide high efficiency and compact design but may have limitations in terms of torque and speed range. Stepper motors and servo motors, both types of gear motors, excel in precise positioning applications but may have slightly lower efficiency compared to direct-drive motors. The selection of the most suitable motor type depends on the specific requirements of the application, balancing power, efficiency, speed range, and control capabilities.

gear motor

Are there specific considerations for selecting the right gear motor for a particular application?

When selecting a gear motor for a specific application, several considerations need to be taken into account. The choice of the right gear motor is crucial to ensure optimal performance, efficiency, and reliability. Here’s a detailed explanation of the specific considerations for selecting the right gear motor for a particular application:

1. Torque Requirement:

The torque requirement of the application is a critical factor in gear motor selection. Determine the maximum torque that the gear motor needs to deliver to perform the required tasks. Consider both the starting torque (the torque required to initiate motion) and the operating torque (the torque required to sustain motion). Select a gear motor that can provide adequate torque to handle the load requirements of the application. It’s important to account for any potential torque spikes or variations during operation.

2. Speed Requirement:

Consider the desired speed range or specific speed requirements of the application. Determine the rotational speed (in RPM) that the gear motor needs to achieve to meet the application’s performance criteria. Select a gear motor with a suitable gear ratio that can achieve the desired speed at the output shaft. Ensure that the gear motor can maintain the required speed consistently and accurately throughout the operation.

3. Duty Cycle:

Evaluate the duty cycle of the application, which refers to the ratio of operating time to rest or idle time. Consider whether the application requires continuous operation or intermittent operation. Determine the duty cycle’s impact on the gear motor, including factors such as heat generation, cooling requirements, and potential wear and tear. Select a gear motor that is designed to handle the expected duty cycle and ensure long-term reliability and durability.

4. Environmental Factors:

Take into account the environmental conditions in which the gear motor will operate. Consider factors such as temperature extremes, humidity, dust, vibrations, and exposure to chemicals or corrosive substances. Choose a gear motor that is specifically designed to withstand and perform optimally under the anticipated environmental conditions. This may involve selecting gear motors with appropriate sealing, protective coatings, or materials that can resist corrosion and withstand harsh environments.

5. Efficiency and Power Requirements:

Consider the desired efficiency and power consumption of the gear motor. Evaluate the power supply available for the application and select a gear motor that operates within the specified voltage and current ranges. Assess the gear motor’s efficiency to ensure that it maximizes power transmission and minimizes wasted energy. Choosing an efficient gear motor can contribute to cost savings and reduced environmental impact.

6. Physical Constraints:

Assess the physical constraints of the application, including space limitations, mounting options, and integration requirements. Consider the size, dimensions, and weight of the gear motor to ensure it can be accommodated within the available space. Evaluate the mounting options and compatibility with the application’s mechanical structure. Additionally, consider any specific integration requirements, such as shaft dimensions, connectors, or interfaces that need to align with the application’s design.

7. Noise and Vibration:

Depending on the application, noise and vibration levels may be critical factors. Evaluate the acceptable noise and vibration levels for the application’s environment and operation. Choose a gear motor that is designed to minimize noise and vibration, such as those with helical gears or precision engineering. This is particularly important in applications that require quiet operation or where excessive noise and vibration may cause issues or discomfort.

By considering these specific factors when selecting a gear motor for a particular application, you can ensure that the chosen gear motor meets the performance requirements, operates efficiently, and provides reliable and consistent power transmission. It’s important to consult with gear motor manufacturers or experts to determine the most suitable gear motor based on the specific application’s needs.

China Custom 12V DC Gear Motor with Reducer 32mm Planetary DC Motor   vacuum pump electricChina Custom 12V DC Gear Motor with Reducer 32mm Planetary DC Motor   vacuum pump electric
editor by CX 2023-11-29