China OEM Wire Twisting Machine Assembly Gp50c Traverse Unit Rolling Ring Drive

Product Description

Product Description

Wire twisting machine assembly GP50C traverse unit rolling ring drive
Manufacturer of automatic linear transmission gear with well-equipped testing facilities and strong technical force

Type  GP50C
Shaft Diameter 50 mm
Number of Rolling Rings 3 Pieces
Maximum Thrust(N) 700 N
Weight-Bearing(KG) 70 kg
Maximum Pitch(mm) 40 mm
Weight(KG) 66 kg
Linear Xihu (West Lake) Dis. Length Standard length 1000mm or Customized length

 

Product Parameters

Detailed Photos

 

ROTATION DIRECTION (CAN CHANGE)

 

Packaging & Shipping

Package Material

 

Wooden Box or Carton

Package Detail

 

1piece or 5 pieces per carton package or wooden carton

Delivery Way

 

Deliver the goods by express, like UPS, DHL, FedEx or by sea shipment or according to customer’s requirement

 

Product Application

Rolling ring drive/ traverse unit device is mostly used in industry. Used in textile machine, wire spooling machine, traverse winding machine, wire winding machine, linear drive system, medical equipment, etc.
 

Different Type of Product

Rolling Ring Drive has GPA, GPB, CHINAMFG Series, It is widely used in wire,steel wire,electrical wire, cable, textile industry etc.
A Series : Rolling ring drives Type A Series just have 1 rolling ring linear drive box , which are divided into six types according to the diameter of the shafts.

B Series: Rolling ring drives Type B Series have One Rolling Ring linear drive with Xihu (West Lake) Dis. Rollers or Xihu (West Lake) Dis. Wheel , which are divided into 6 types according to the diameter of the shafts. 

C Series : Rolling ring drives Type C Series have One Rolling Ring linear drive with accessories, such as shaft,guide roller,bearing block,steady bar,etc , which are divided into six types according to the diameter of the shafts. 

FAQ

 

Q1. What is your terms of packing?
A: Generally, we pack our goods in carton boxes or wooden boxes.

Q2. What is your terms of payment?
A: T/T 100% paymeny in advance, or 30% as deposit, and 70% before delivery. We’ll show you the photos of the products and packages before you pay the balance.

Q3. What is your terms of delivery?

A: EXW, FOB, CFR, CIF, DDU.

Q4. How about your delivery time?
A: Generally, it will send this product within 3 or 5 days after receiving your payment. The specific delivery time depends on the items and the quantity of your order.

Q5. What is your sample policy?
A: We can supply the sample if we have ready parts in stock, but the customers have to pay the sample cost and the courier cost.

Q6. Do you test all your goods before delivery?
A: Yes, we have 100% test before delivery

Q7: How do you make our business long-term and good relationship?
A:1. We keep good quality and competitive price to ensure our customers benefit ;
2. We respect every customer as our friend and we sincerely do business and make friends with them, no matter where they come from.

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Color: Fixed
Customized: Customized
Standard: National
Customization:
Available

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Shipping Cost:

Estimated freight per unit.







about shipping cost and estimated delivery time.
Payment Method:







 

Initial Payment



Full Payment
Currency: US$
Return&refunds: You can apply for a refund up to 30 days after receipt of the products.

pitch drive

What safety considerations should be taken into account when using pitch drives in industrial settings?

When using pitch drives in industrial settings, several safety considerations should be taken into account to ensure the well-being of personnel, the protection of equipment, and the prevention of accidents. Here’s a detailed explanation of the safety considerations associated with the use of pitch drives in industrial settings:

  • Training and Competence: Proper training and competence of personnel operating and maintaining pitch drives are essential for safety. Adequate training should be provided to ensure that operators and maintenance personnel understand the operating principles, safety procedures, and potential hazards associated with pitch drives. Competent personnel can effectively identify and respond to safety risks, perform maintenance tasks safely, and mitigate potential accidents or malfunctions.
  • Protective Measures: Industrial settings utilizing pitch drives should incorporate appropriate protective measures to minimize the risk of accidents and injuries. This includes the installation of physical barriers, guards, or enclosures around pitch drive components to prevent unauthorized access and protect personnel from moving parts. Safety interlocks and emergency stop systems should also be in place to quickly halt pitch drive operation in case of emergencies or abnormal conditions.
  • Electrical Safety: Pitch drives in industrial settings typically involve electrical components and connections. Electrical safety measures should be observed, including proper grounding, insulation, and protection against electrical hazards. Qualified electricians should handle electrical installations, and regular inspections should be conducted to ensure the integrity of electrical systems associated with pitch drives.
  • Lockout/Tagout Procedures: Lockout/tagout procedures are crucial when performing maintenance, repair, or inspection tasks on pitch drives. These procedures ensure that energy sources are isolated, locked, and tagged to prevent accidental startup or release of stored energy. Lockout/tagout procedures should be strictly followed to protect personnel from electrical shocks, unexpected movements, or hazardous conditions during maintenance activities.
  • Risk Assessment and Hazard Identification: A comprehensive risk assessment should be conducted to identify potential hazards and assess the associated risks in industrial settings using pitch drives. This includes evaluating risks related to electrical hazards, mechanical hazards, ergonomic factors, and environmental factors. By identifying and understanding the specific risks, appropriate control measures can be implemented to minimize or eliminate hazards and reduce the likelihood of accidents or injuries.
  • Maintenance and Inspections: Regular maintenance and inspections are critical for ensuring the safe operation of pitch drives in industrial settings. Scheduled maintenance tasks, such as lubrication, alignment checks, and component replacements, should be performed according to manufacturer recommendations and industry standards. Inspections should be conducted to identify any signs of wear, damage, or deterioration that may compromise the safety and reliability of pitch drives.
  • Emergency Preparedness: Adequate emergency preparedness measures should be in place to respond to potential accidents or malfunctions involving pitch drives. This includes having well-defined emergency procedures, trained personnel, and appropriate safety equipment readily available. Emergency response drills and exercises can help familiarize personnel with the necessary actions to take during emergency situations and ensure a prompt and effective response.
  • Compliance with Standards and Regulations: Industrial settings should comply with relevant safety standards, regulations, and codes when using pitch drives. These standards may include electrical safety standards, machinery safety standards, and occupational health and safety regulations. Compliance ensures that safety requirements are met, and best practices are followed to protect personnel and maintain a safe working environment.

In summary, safety considerations are of utmost importance when using pitch drives in industrial settings. Training and competence, protective measures, electrical safety, lockout/tagout procedures, risk assessment, maintenance and inspections, emergency preparedness, and compliance with standards and regulations are key aspects to address. By implementing these safety considerations, industrial settings can mitigate risks, prevent accidents, and create a safer environment for personnel and equipment when using pitch drives.

pitch drive

Can you explain the impact of pitch drives on the overall efficiency of adjustable systems?

Pitch drives have a significant impact on the overall efficiency of adjustable systems. These drives enable precise and controlled adjustments of pitch angles, which in turn optimize the performance, energy consumption, and operational characteristics of various adjustable systems. Here’s a detailed explanation of the impact of pitch drives on overall system efficiency:

  • Optimized Power Output: In applications such as wind turbines or marine propulsion systems, pitch drives allow for the optimization of power output. By adjusting the pitch angle of turbine blades or propellers, pitch drives can maximize the capture of wind or water energy, ensuring that the system operates at its peak efficiency point. This results in higher power generation or propulsion efficiency, translating into improved overall system efficiency.
  • Load Distribution and Stress Reduction: Pitch drives play a crucial role in adjusting the pitch angles of rotor blades or propellers, which helps distribute loads evenly across the system. By optimizing load distribution, pitch drives minimize stress concentrations on specific components, reducing the risk of fatigue, wear, or failure. This balanced load distribution enhances the overall structural integrity and reliability of the adjustable systems, allowing them to operate efficiently over extended periods.
  • Responsive and Adaptive Performance: Adjustable systems equipped with pitch drives exhibit responsive and adaptive performance characteristics. The ability to adjust pitch angles enables quick response to changing operating conditions or external factors. For example, in wind turbines, pitch drives allow the system to respond to varying wind speeds and directions, optimizing power generation and maintaining safe operating conditions. This adaptability improves system efficiency by ensuring optimal performance under different environmental or operational scenarios.
  • Energy Conservation: Pitch drives contribute to energy conservation in adjustable systems. By adjusting the pitch angles to match the desired performance requirements, the system can avoid unnecessary power consumption or overloading. For instance, in HVAC systems with adjustable pitch fans, pitch drives allow for precise control of airflow, reducing energy waste and improving overall energy efficiency. This energy conservation leads to lower operational costs and a reduced environmental footprint.
  • Operating Cost Reduction: The efficiency gains achieved through pitch drives result in cost reductions for adjustable systems. By optimizing power output, reducing stress, and conserving energy, pitch drives contribute to lower maintenance, repair, and operational expenses. The improved overall efficiency translates into increased system reliability, reduced downtime, and longer service life, leading to cost savings over the operational lifespan of the system.
  • Improved Control and Safety: Pitch drives enhance the control and safety of adjustable systems. Precise adjustments of pitch angles provide operators with better control over system performance, allowing them to optimize operations for improved efficiency and safety. For example, in aircraft with variable-pitch propellers, pitch drives enable pilots to adjust the propeller pitch to match the desired thrust requirements, optimizing fuel efficiency and ensuring safe takeoffs, climbs, and descents.

The impact of pitch drives on overall system efficiency is evident across various industries, including renewable energy, aerospace, marine, HVAC, and industrial applications. By enabling precise pitch adjustments, these drives optimize power output, load distribution, responsiveness, energy conservation, and operating costs, ultimately leading to improved overall efficiency for adjustable systems.

pitch drive

How does the design of a pitch drive contribute to efficient adjustment or movement?

The design of a pitch drive plays a crucial role in enabling efficient adjustment or movement of the pitch angle in machinery or systems. The design factors of a pitch drive are carefully considered to ensure precise control, reliability, and optimal performance. Here’s a detailed explanation of how the design of a pitch drive contributes to efficient adjustment or movement:

The design considerations of a pitch drive include the following aspects:

  • Mechanical Structure: The mechanical structure of a pitch drive is designed to provide the necessary strength, rigidity, and durability to withstand the operational forces and loads. It ensures that the pitch drive can effectively transmit and control the required torque and movement to adjust the pitch angle. The design considers factors such as material selection, component dimensions, and overall structural integrity to ensure efficient adjustment without compromising the system’s reliability.
  • Gearing System: Pitch drives often incorporate gearing systems to transmit and amplify the rotational motion. The design of the gearing system is crucial for efficient adjustment or movement. It ensures precise torque transmission, minimal backlash, and smooth operation. The gear ratio and gear quality are carefully chosen to achieve the desired pitch angle adjustment range and accuracy. The design of the gears also considers factors such as noise reduction, lubrication, and maintenance requirements.
  • Actuation Mechanism: The actuation mechanism of a pitch drive depends on the specific application and requirements. It can involve various technologies such as hydraulic, pneumatic, or electric actuators. The design of the actuation mechanism focuses on providing precise and responsive control over the pitch angle adjustment. Factors such as actuator speed, force or torque output, and control system integration are considered to ensure efficient adjustment or movement.
  • Control System Integration: The design of a pitch drive includes the integration of a control system that governs the pitch angle adjustment. The control system receives input signals or commands and translates them into appropriate actuation signals for the pitch drive mechanism. The design of the control system ensures accurate and responsive control, taking into account factors such as sensor feedback, signal processing, and control algorithms. Efficient control system design facilitates precise and dynamic adjustment of the pitch angle in real-time.

The design features and considerations of a pitch drive contribute to efficient adjustment or movement in several ways:

  • High Precision: The design ensures precise control over the pitch angle, allowing for fine adjustments and accurate positioning. This precision is crucial in applications where small changes in the pitch angle can significantly impact performance, efficiency, or safety.
  • Smooth Operation: The design minimizes friction, backlash, and mechanical vibrations, resulting in smooth and consistent movement during pitch angle adjustment. Smooth operation reduces wear and tear, enhances system reliability, and improves overall performance.
  • Speed and Responsiveness: The design factors in the actuation mechanism and control system to enable fast and responsive pitch angle adjustments. This is particularly important in applications where rapid changes in the pitch angle are required to adapt to dynamic operating conditions.
  • Reliability: The design ensures the pitch drive’s structural integrity, component durability, and system reliability. This contributes to long-term operation without significant maintenance or downtime, enhancing the efficiency and productivity of the machinery or system.
  • Safety: The design incorporates safety features and mechanisms to prevent unintended or excessive pitch angle adjustments. Safety considerations may include limit switches, emergency stop controls, or redundant systems to ensure safe operation and protect against potential hazards.

Overall, the design of a pitch drive is carefully engineered to provide efficient adjustment or movement of the pitch angle. By considering mechanical structure, gearing systems, actuation mechanisms, and control system integration, the design aims to achieve precise control, reliability, and optimal performance in machinery or systems that rely on pitch angle adjustment.

China OEM Wire Twisting Machine Assembly Gp50c Traverse Unit Rolling Ring Drive  China OEM Wire Twisting Machine Assembly Gp50c Traverse Unit Rolling Ring Drive
editor by Dream 2024-04-22