Descripción del Producto
Products Description
Product Paramenters
| MODEL | FLE28 | Reduction ratio | Number of stage | |
| Nominal Output Torque | N.m | 4 | 3.71 | L1 |
| 4 | 5.18 | |||
| 6 | 13.70 | L2 | ||
| 6 | 19.20 | |||
| 6 | 27.00 | |||
| 6 | 51.00 | L3 | ||
| 6 | 71.00 | |||
| 6 | 99.00 | |||
| 6 | 139.00 | |||
| Sudden Stop Torque | N.m | 2 times of nominal output torque | ||
| Nominal Input Speed | rpm | 1000 | ||
| Max Input Speed | rpm | 2000 | ||
| Max Radial Load | N | 160 | ||
| Max Axial Load | N | 60 | ||
| Eficiencia | % | 90 | L1 | |
| 81 | L2 | |||
| 73 | L3 | |||
| Reacción | arcmin | ≤60 | L1 | |
| ≤75 | L2 | |||
| ≤90 | L3 | |||
| Noise | dB | ≤60 | ||
| Protection Level | IP | 54 | ||
| Life Span | h | 20000 | ||
| Working Temp. | C° | -20°~+150° | ||
| Lubrication Method | Permanent Lubrication | |||
| Weight | kg | ≈0.18 | FLE28-L1 | |
| ≈0.20 | FLE28-L2 | |||
| ≈0.25 | FLE28-L3 | |||
Company Profile
Certifications
Exhibition
Product packaging
| Solicitud: | Motor, Electric Cars, Motorcycle, Machinery, Marine, Toy, Agricultural Machinery |
|---|---|
| Función: | Distribution Power, Clutch, Change Drive Torque, Change Drive Direction, Speed Changing, Speed Reduction, Speed Increase |
| Disposición: | Planetary Reducer |
| Dureza: | Superficie del diente endurecida |
| Instalación: | Vertical Type |
| Paso: | Four-Step |
| Personalización: |
Disponible
| Solicitud personalizada |
|---|
¿Cómo mejoran los reductores de engranajes la eficiencia de los sistemas de transporte y la robótica?
Los reductores de engranajes desempeñan un papel fundamental en la mejora de la eficiencia de los sistemas de transporte y la robótica, optimizando la velocidad, el par y el control. A continuación, se detalla su contribución:
Sistemas transportadores:
En los sistemas transportadores, los reductores de engranajes mejoran la eficiencia de las siguientes maneras:
- Control de velocidad: Los reductores de engranajes permiten un control preciso de la velocidad de rotación de las cintas transportadoras, garantizando que los materiales se transporten a la velocidad deseada para procesos de producción eficientes.
- Ajuste de par: Al ajustar las relaciones de engranajes, los reductores de engranajes proporcionan el torque necesario para manejar cargas variables y evitar la sobrecarga, minimizando el desperdicio de energía.
- Operación inversa: Los reductores de engranajes permiten un movimiento bidireccional suave de las cintas transportadoras, facilitando tareas como carga, descarga y distribución sin necesidad de componentes adicionales.
- Sincronización: Los reductores de engranajes garantizan el movimiento sincronizado de múltiples cintas transportadoras en sistemas complejos, optimizando el flujo de material y minimizando atascos o cuellos de botella.
Robótica:
En robótica, los reductores de engranajes mejoran la eficiencia a través de los siguientes medios:
- Movimiento de precisión: Los reductores de engranajes proporcionan un control preciso sobre el movimiento de las articulaciones y los brazos del robot, lo que permite un posicionamiento y una manipulación precisos de los objetos.
- Inercia reducida: Los reductores de engranajes ayudan a reducir la inercia que experimentan los componentes robóticos, lo que permite movimientos más rápidos y con mayor capacidad de respuesta al tiempo que conservan energía.
- Diseño compacto: Los reductores de engranajes ofrecen una solución compacta y liviana para lograr diversos perfiles de movimiento en sistemas robóticos, lo que permite un uso eficiente del espacio y los recursos.
- Amplificación de par: Al amplificar el torque del motor, los reductores de engranajes permiten a los robots manejar cargas más pesadas y realizar tareas que requieren mayor fuerza, mejorando sus capacidades generales.
Al proporcionar un control de velocidad preciso, ajuste de torque y transmisión de movimiento confiable, los reductores de engranajes optimizan el rendimiento de los sistemas transportadores y la robótica, lo que genera una mayor eficiencia, un menor consumo de energía y capacidades operativas mejoradas.
Can gear reducers be used for both speed reduction and speed increase?
Yes, gear reducers can be utilized for both speed reduction and speed increase, depending on their design and arrangement. The functionality to either decrease or increase rotational speed is achieved by altering the arrangement of gears within the gearbox.
1. Reducción de velocidad: In speed reduction applications, a gear reducer is designed with gears of different sizes. The input shaft connects to a larger gear, while the output shaft is connected to a smaller gear. As the input shaft rotates, the larger gear turns the smaller gear, resulting in a decrease in output speed compared to the input speed. This configuration provides higher torque output at a lower speed, making it suitable for applications that require increased force or torque.
2. Speed Increase: For speed increase, the gear arrangement is reversed. The input shaft connects to a smaller gear, while the output shaft is connected to a larger gear. As the input shaft rotates, the smaller gear drives the larger gear, resulting in an increase in output speed compared to the input speed. However, the torque output is lower than that of speed reduction configurations.
By choosing the appropriate gear ratios and arrangement, gear reducers can be customized to meet specific speed and torque requirements for various industrial applications. It’s important to select the right type of gear reducer and configure it correctly to achieve the desired speed reduction or speed increase.
Can you explain the different types of gear reducers available in the market?
There are several types of gear reducers commonly used in industrial applications:
1. Spur Gear Reducers: These reducers have straight teeth and are cost-effective for applications requiring moderate torque and speed reduction. They are efficient but may produce more noise compared to other types.
2. Helical Gear Reducers: Helical gears have angled teeth, which provide smoother and quieter operation compared to spur gears. They offer higher torque capacities and are suitable for heavy-duty applications.
3. Bevel Gear Reducers: Bevel gears have conical shapes and intersect at an angle, allowing them to transmit power between non-parallel shafts. They are commonly used in applications where shafts intersect at 90 degrees.
4. Worm Gear Reducers: Worm gears consist of a worm (screw) and a mating gear (worm wheel). They offer high torque reduction and are used for applications requiring high ratios, although they can be less efficient.
5. Planetary Gear Reducers: These reducers use a system of planetary gears to achieve high torque output in a compact design. They provide excellent torque multiplication and are commonly used in robotics and automation.
6. Cycloidal Gear Reducers: Cycloidal drives use an eccentric cam to achieve speed reduction. They offer high shock load resistance and are suitable for applications with frequent starting and stopping.
7. Harmonic Drive Reducers: Harmonic drives use a flexible spline to achieve high gear reduction ratios. They provide high precision and are commonly used in applications requiring accurate positioning.
8. Hypoid Gear Reducers: Hypoid gears have helical teeth and non-intersecting shafts, making them suitable for applications with space limitations. They offer high torque and efficiency.
Each type of gear reducer has its own advantages and limitations, and the choice depends on factors such as torque requirements, speed ratios, noise levels, space constraints, and application-specific needs.
editor by CX 2023-10-24
