Product Description
Technical Features
The high degree of modularity is a design feature of SRC helical gearboxes range. It can be connected respectively with motors such as normal motor, brake motor, explosion-proof motor, frequency conversion motor, servo motor, IEC motor and so on. This kind of product is widely used in drive fields such as textile, foodstuff, ceramics packing, logistics, plastics and so on. It is possible to set up the version required using flanges or feet.
Products characteristics
SRC series helical gear units has more than 4 types. Power 0.12-4kw; Ratio 3.66-54; Torque max 120-500Nm. It can be connected (foot or flange) discretionary and use multi-mounting positions according to customers requirements.
Ground-hardened helical gears;
Modularity,can be combined in many forms;
Aluminium casing, light weight;
Gears in carbonize hard, durable;
Universal mounting;
Refined design,space effective and low noise
Structure feature
Model illuminate
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1 |
Code for gear units series |
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2 |
No F code means foot mounted.With F code B5 flange mounted.With Z code B14 flange mounted |
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3 |
Specification code of gear units 01 |
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4 |
I,II,III,B5 Output flange specification,default I not to write out is ok |
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5 |
IEC: Input flange HS: shaft input |
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6 |
Transmission ratio of gear units |
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7 |
M1:Mounting position, default mounting position M1 not to write out is ok |
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8 |
Position diagram for motor terminal box,default position o°(R) not to write out is ok |
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9 |
No mark means without motor Model motor(poles of power) |
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10 |
Voltage – frequency |
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11 |
Coil in position for motor, default position S not to write out is ok |
4.2 Rotation speed n
n1 Gear units input speed
n2 Gear units output speed
If driven by the external gearing,1400r/min or lower rotation speed is suggested so as to optimize the working conditions and prolong the service life.Higher input rotation speed is permitted, but in this situation,the rated torque M2 will be reduced
4.5 Service factor fs
The effect of the driven machine on the gear unit is taken into account to a sufficient level of accuracy using the service factor fs. The service factor is determined according to the daily operation time and the starting frequency Z. Three load classifications are considered depending on the mass acceleration factor. You can read off the service factor applicable to your application in following figure. The service factor selected using this diagram must be less than or equal to the service factor as given in the performance parameter table.
* starting frequency Z: The cycles include all starting and braking procedures as well as change overs from low to high speed
SRC02..(HS) Performance parameter
|
kw |
Output speed |
Torque |
Speed ratio |
fs |
Model |
IEC |
|
0.37 |
16.7rpm |
204N.M |
54 |
1.0 |
SRC02 |
80B5/B14
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Helical gearbox outline dimension heet
| Foot Code | U | V | V1 | V2 | V3 | W | X | X1 | Y | Z |
| B02 | 18 | 107.5 | 60 | – | 130 | 11 | 136 | 155 | 100 | 17 |
| M02 | 25 | 85 | – | 110 | 120 | 9 | 112 | 145 | 80 | 15 |
| M01 | 18 | 80 | – | 110 | 120 | 9 | 118 | 145 | 80 | 15 |
| B01 | 18 | 87 | 50 | 110 | – | 9 | 118 | 130 | 90 | 15 |
SRC helical gearbox with motor mounting position and terminal box orientation
Package
1 pc / carton,several cartons / wooden pallet
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| Application: | Motor |
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| Layout: | Cycloidal |
| Hardness: | Soft Tooth Surface |
| Samples: |
US$ 192.65/Piece
1 Piece(Min.Order) | Order Sample SMRV-130-10-132M4
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| Customization: |
Available
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.shipping-cost-tm .tm-status-off{background: none;padding:0;color: #1470cc}
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Shipping Cost:
Estimated freight per unit. |
about shipping cost and estimated delivery time. |
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| Payment Method: |
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Initial Payment Full Payment |
| Currency: | US$ |
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| Return&refunds: | You can apply for a refund up to 30 days after receipt of the products. |
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Can you explain the impact of winch drives on the overall efficiency of lifting systems?
The efficiency of lifting systems is significantly influenced by the choice and performance of winch drives. Winch drives play a crucial role in converting power into mechanical work to lift or move heavy loads. Here’s a detailed explanation of the impact of winch drives on the overall efficiency of lifting systems:
- Power Transmission:
Winch drives are responsible for transmitting power from the energy source to the lifting mechanism. The efficiency of power transmission directly affects the overall efficiency of the lifting system. Well-designed winch drives minimize power losses due to friction, heat generation, or mechanical inefficiencies. By optimizing the gear system, bearings, and other mechanical components, winch drives can maximize power transmission efficiency and minimize energy waste.
- Mechanical Advantage:
Winch drives provide a mechanical advantage that allows the lifting system to handle heavier loads with less effort. The mechanical advantage is determined by the gear ratio and drum diameter of the winch drive. By selecting an appropriate gear ratio, the winch drive can multiply the input torque, enabling the lifting system to overcome the resistance of the load more efficiently. A higher mechanical advantage reduces the strain on the power source and improves the overall efficiency of the lifting system.
- Speed Control:
Winch drives offer speed control capabilities, allowing operators to adjust the lifting speed according to the specific requirements of the task. The ability to control the lifting speed is essential for efficient and safe operation. By utilizing winch drives with precise speed control mechanisms, the lifting system can optimize the speed to match the load, reducing unnecessary energy consumption and increasing overall efficiency.
- Load Distribution:
Winch drives play a vital role in distributing the load evenly across the lifting system. Uneven load distribution can lead to excessive stress on certain components, reducing the overall efficiency and potentially causing equipment failure. Well-designed winch drives ensure that the load is distributed evenly, minimizing stress concentrations and maximizing the efficiency of the lifting system.
- Control and Safety Features:
Winch drives incorporate control and safety features that contribute to the overall efficiency of the lifting system. Advanced control systems allow for precise positioning and smooth operation, minimizing unnecessary movements and reducing energy consumption. Safety features, such as overload protection or emergency stop mechanisms, help prevent accidents and equipment damage, ensuring uninterrupted and efficient operation of the lifting system.
- Reliability and Maintenance:
The reliability and maintenance requirements of winch drives directly impact the overall efficiency of lifting systems. Well-designed winch drives with robust construction and quality components minimize the risk of breakdowns or unplanned downtime. Additionally, winch drives that are easy to maintain and service reduce the time and resources required for maintenance, maximizing the uptime and efficiency of the lifting system.
In summary, the choice and performance of winch drives have a significant impact on the overall efficiency of lifting systems. By optimizing power transmission, providing a mechanical advantage, offering speed control, ensuring load distribution, incorporating control and safety features, and prioritizing reliability and maintenance, winch drives can enhance the efficiency, productivity, and safety of lifting operations.
How does the design of winch drives impact their performance in different environments?
The design of winch drives plays a critical role in determining their performance in different environments. Various design factors influence the reliability, efficiency, and adaptability of winch drives to specific operating conditions. Here’s a detailed explanation of how the design of winch drives impacts their performance:
- Load Capacity and Power:
The design of winch drives directly affects their load capacity and power capabilities. Factors such as motor size, gear ratio, and drum diameter determine the maximum load capacity a winch drive can handle. The power output of the motor and the mechanical advantage provided by the gear system impact the winch drive’s ability to lift or pull heavy loads effectively. A well-designed winch drive with appropriate load capacity and power ensures optimal performance in different environments.
- Speed and Control:
The design of winch drives influences their speed and control characteristics. The gear ratio and motor specifications determine the speed at which the winch drive can operate. Additionally, the presence of a variable speed control mechanism allows for precise and controlled movement of loads. The design should strike a balance between speed and control, depending on the specific application and operational requirements in different environments.
- Drive System:
Winch drives can utilize different drive systems, such as electric, hydraulic, or pneumatic. The design of the drive system impacts the performance of the winch drive in different environments. Electric winch drives are commonly used due to their ease of use, precise control, and suitability for various applications. Hydraulic winch drives offer high power output and are often preferred in heavy-duty applications. Pneumatic winch drives are suitable for environments where electricity or hydraulics are not readily available. The design should align with the specific requirements and constraints of the environment in which the winch drive will be used.
- Enclosure and Protection:
The design of the winch drive enclosure and protection features significantly impacts its performance in different environments. Winch drives used in outdoor or harsh environments should have robust enclosures that provide protection against dust, moisture, and other contaminants. Sealed or weatherproof enclosures prevent damage to internal components and ensure reliable operation. Additionally, features such as thermal protection and overload protection are designed to safeguard the winch drive from overheating or excessive strain, enhancing its performance and longevity.
- Mounting and Installation:
The design of winch drives should consider the ease of mounting and installation. Mounting options such as bolt-on, weld-on, or integrated mounting plates offer flexibility for different installation scenarios. The design should also take into account the space constraints and mounting requirements of the specific environment. Easy and secure installation ensures proper alignment, stability, and efficient operation of the winch drive.
- Control and Safety Features:
The design of winch drives includes control and safety features that impact their performance in different environments. Control systems can range from simple push-button controls to advanced remote controls or integrated control panels. The design should provide intuitive and user-friendly control interfaces for efficient operation. Safety features such as emergency stop mechanisms, load limiters, and overload protection are crucial to prevent accidents and ensure safe operation in various environments. The design should prioritize the incorporation of appropriate safety features based on the specific application and environmental conditions.
By considering these design factors, winch drives can be optimized for performance, reliability, and safety in different environments. A well-designed winch drive that aligns with the specific requirements of the environment will deliver efficient and effective lifting or pulling capabilities while ensuring long-term durability and functionality.
How does the design of a winch drive contribute to efficient load lifting and pulling?
The design of a winch drive plays a critical role in ensuring efficient load lifting and pulling operations. Various design considerations are implemented to optimize performance, reliability, and safety. Here’s a detailed explanation of how the design of a winch drive contributes to efficient load lifting and pulling:
- Power and Torque:
A well-designed winch drive is equipped with a power source and gearbox that provide sufficient power and torque to handle the intended load. The power source, whether it’s an electric motor or hydraulic system, should have adequate capacity to generate the required energy for the pulling or lifting operation. The gearbox or transmission is designed to provide the appropriate torque output, matching the load requirements. By ensuring the winch drive has the necessary power and torque, it can efficiently handle the load without straining the components or compromising performance.
- Gearing and Speed Control:
The gearing system within the winch drive allows for precise control over the speed of the pulling or lifting operation. The gearbox is designed with different gear ratios, enabling the operator to select the desired speed based on the specific requirements of the task. This capability is crucial for efficient load handling. For instance, a higher gear ratio can be used for lighter loads or faster pulling speeds, while a lower gear ratio provides increased pulling power for heavier loads. The ability to control the speed optimizes the efficiency of the winch drive by adapting to the load characteristics and operational needs.
- Drum Size and Cable Capacity:
The design of the winch drive includes considerations for the drum size and cable capacity. The drum is responsible for winding or unwinding the cable during the pulling or lifting operation. A larger drum diameter allows for a greater length of cable to be wound, which increases the pulling capacity of the winch. The drum design should also ensure proper cable alignment and smooth winding to prevent cable damage or entanglement. By optimizing the drum size and cable capacity, the winch drive can efficiently handle the load and accommodate the necessary cable length required for the task.
- Braking System:
An efficient winch drive incorporates a reliable braking system. The braking system is designed to hold the load securely when the winch is not actively pulling or lifting. It prevents the load from slipping or releasing unintentionally, ensuring safety and stability during operation. The braking system should engage quickly and provide sufficient holding force, even in the event of power loss or sudden load changes. A well-designed braking system contributes to the efficiency of load lifting and pulling by maintaining control and preventing accidents or damage.
- Control System and Safety Features:
The design of the winch drive includes a control system with intuitive controls and safety features. The control system allows the operator to manage the operation of the winch drive, including start/stop functions, direction control, and speed adjustment. Clear and user-friendly controls enhance operational efficiency and facilitate precise load handling. Additionally, safety features such as overload protection, emergency stop mechanisms, and limit switches are integrated into the winch drive design to ensure safe operation and prevent damage to the equipment or injury to personnel.
By considering power and torque requirements, gearing and speed control, drum size and cable capacity, braking systems, control systems, and safety features, the design of a winch drive contributes to efficient load lifting and pulling. These design elements work together to optimize performance, control, and safety, allowing the winch drive to handle loads effectively and reliably in various applications and industries.
editor by CX 2024-02-21