Product Description
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| Item No. | φD | L | L1 | W | M | Tighten the strength(N.m) |
| SG7-11-30- | 30 | 50 | 18.5 | 13 | M3(4) | 1.2 |
| SG7-11-40- | 40 | 66 | 25 | 16 | M4(6) | 2.7 |
| SG7-11-55- | 55 | 78 | 30 | 18 | M5(4) | 6 |
| SG7-11-65- | 65 | 90 | 35 | 20 | M5(6) | 6 |
| SG7-11-80- | 80 | 114 | 45 | 24 | M6(8) | 10 |
| SG7-11-95- | 95 | 126 | 50 | 26 | M8(4) | 35 |
| SG7-11-105- | 105 | 140 | 56 | 28 | M8(4) | 35 |
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| Item No. | Rated torque | Maximum Torque | Max Speed | Inertia Moment | N.m rad | Tilting Tolerance | End-play | Weight:(g) |
| SG7-11-30- | 7.4N.m | 14.8N.m | 20000prm | 8.7×10-4kg.m² | 510N.m/rad | 1.0c | +0.6mm | 50 |
| SG7-11-40- | 9.5N.m | 19N.m | 15000prm | 1.12×10-3kg.m² | 550N.m/rad | 1.0c | +0.8mm | 120 |
| SG7-11-55- | 34N.m | 68N.m | 13000prm | 4.5×10-3kg.m² | 1510N.m/rad | 1.0c | +0.8mm | 280 |
| SG7-11-65- | 95N.m | 190N.m | 10500prm | 9.1×10-3kg.m² | 2800N.m/rad | 1.0c | +0.8mm | 450 |
| SG7-11-80- | 135N.m | 270N.m | 8600prm | 1.9×10-2kg.m² | 3600N.m/rad | 1.0c | +1.0mm | 960 |
| SG7-11-95- | 230N.m | 460N.m | 7500prm | 2.2×10-2kg.m² | 4700N.m/rad | 1.0c | +1.0mm | 2310 |
| SG7-11-105- | 380N.m | 760N.m | 6000prm | 3.3×10-2kg.m² | 5800N.m/rad | 1.0c | +1.0mm | 3090 |
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Comparison between Couplings with High Torsional Stiffness and Low Torsional Stiffness
Couplings used in motion control systems can vary significantly in their torsional stiffness, which is a crucial characteristic that affects their performance and behavior. Let’s explore the differences between couplings with high torsional stiffness and low torsional stiffness:
- Torsional Stiffness:
Torsional stiffness refers to the resistance of a coupling to rotational deflection or twisting under the influence of a torque. Couplings with high torsional stiffness offer greater resistance to twisting, while those with low torsional stiffness are more flexible and can accommodate more significant torsional deflections.
- Response to Torque:
Couplings with high torsional stiffness transmit torque more efficiently from one shaft to another, as they minimize torsional deflection. This characteristic is advantageous in applications where precise torque transmission and minimal power loss are essential. On the other hand, couplings with low torsional stiffness are better at absorbing shocks and torsional vibrations, making them suitable for applications where dampening is required.
- Misalignment Compensation:
Couplings with high torsional stiffness are less forgiving when it comes to misalignment between shafts. They require more accurate alignment to prevent excessive stress on the coupling and connected components. In contrast, couplings with low torsional stiffness can accommodate some degree of misalignment, reducing the need for precise alignment during installation.
- Resonance and Natural Frequency:
Couplings with high torsional stiffness have higher natural frequencies and are less prone to resonance. This characteristic is beneficial in high-speed applications where avoiding resonance is critical to prevent damaging vibrations. Couplings with low torsional stiffness, on the other hand, may have lower natural frequencies and need careful consideration to avoid resonance-related issues.
- Stress on Connected Equipment:
High torsional stiffness couplings can transfer torsional loads more directly to connected equipment, which may increase the stress on other system components. Low torsional stiffness couplings can act as vibration isolators, reducing the impact of torsional loads on connected equipment.
- Application Suitability:
The choice between high and low torsional stiffness couplings depends on the specific requirements of the application. High torsional stiffness couplings are suitable for applications where precise torque transmission and accuracy are crucial, such as CNC machines and robotics. Low torsional stiffness couplings are ideal for applications involving misalignment, shock absorption, and vibration dampening, such as printing machinery and conveyor systems.
Ultimately, the selection of a coupling with high or low torsional stiffness depends on the specific needs and performance requirements of the motion control system, ensuring optimal functionality and efficiency in the application.
Handling Angular and Axial Misalignments Simultaneously with Servo Couplings
Servo couplings are designed to handle both angular and axial misalignments simultaneously, making them versatile components for motion control systems. Here’s how they achieve this:
- Angular Misalignment: Angular misalignment occurs when the motor shaft and the driven load shaft are not perfectly aligned, resulting in an angular offset between them. Servo couplings with flexible elements, such as bellows or beam couplings, can accommodate angular misalignment without inducing excessive stress on the components.
- Axial Misalignment: Axial misalignment happens when there is a parallel displacement between the motor and the driven load along the shaft axis. Servo couplings with flexible elements allow for axial movement, absorbing any axial misalignment while maintaining torque transmission.
- Combination of Both: Servo couplings are designed to handle the combination of angular and axial misalignments simultaneously. As the flexible elements of the coupling can move in multiple directions, they can compensate for both angular and axial deviations, ensuring smooth and efficient power transmission.
The ability of servo couplings to handle both angular and axial misalignments is vital in many motion control applications. It allows for greater flexibility in design and installation, as well as improved system performance and reduced wear on the components.
Types of Servo Couplings Used in Industrial Automation
Industrial automation often relies on servo couplings to achieve precise motion control and power transmission between servo motors and driven loads. Different types of servo couplings are available, each designed to suit specific application requirements. Here are some common types of servo couplings used in industrial automation:
- Flexible Beam Couplings: Beam couplings are made of a single piece of material with cuts along the length of the coupling, resembling multiple helical beams. They offer flexibility in multiple directions and can handle angular and axial misalignments. Beam couplings are well-suited for applications that require high torsional rigidity and low inertia, making them ideal for high-speed and high-precision systems.
- Bellows Couplings: Bellows couplings consist of a thin-walled metal bellows element that allows angular and axial misalignments. They provide excellent torsional stiffness and low backlash, making them suitable for applications requiring high precision and torque transmission. Bellows couplings are also known for their ability to handle high-speed applications while maintaining accuracy.
- Oldham Couplings: Oldham couplings have three components: two hubs and a center disc. The center disc connects the hubs and allows misalignment compensation in two directions while eliminating backlash. These couplings are effective in applications that require high torque transmission and moderate misalignment tolerance.
- Servo Motor Couplings: Servo motor couplings are specifically designed for use with servo motors. They are versatile and can come in various configurations, such as jaw-type, disk-type, or elastomeric couplings. They offer good misalignment compensation and are suitable for medium- to high-torque applications with moderate to high precision requirements.
- Disc Couplings: Disc couplings consist of thin metal discs stacked alternately to allow angular misalignment. They offer high torsional stiffness and can handle high torque loads while maintaining accurate motion. Disc couplings are commonly used in high-performance servo motor applications where precision and reliability are critical.
- Jaw Couplings: Jaw couplings have two hubs with elastomeric elements in between. They are capable of compensating for small amounts of angular, parallel, and axial misalignments. Jaw couplings are popular in light to medium-duty applications due to their simplicity, cost-effectiveness, and ease of installation.
When selecting a servo coupling for industrial automation, it is essential to consider factors such as torque capacity, misalignment compensation, speed, precision, and environmental conditions. Each type of servo coupling offers distinct advantages and limitations, so choosing the most suitable type will depend on the specific requirements of the application.
editor by CX 2024-02-05