Product Description
Processing Custom Nylon POM Self lubricating Plastic Motor Toy Gear Machine Gear
Product Description
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Mold Material |
Aluminum,45#, P20, H13, 718, 1.2344, 1.2738 and so on |
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Plastic Material |
PC/ABS, ABS, PC, PVC, PA66, POM or other you want |
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silicon rubber Material |
NR, NBR, SBR, EPDM, IIR, CR, SILICONE, VITON,etc |
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Plastic Surface finish |
Polishing finish,Texture Finish,Glossy Finish,Painting,Slik print,Rubber Painting etc |
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Drawing format |
IGES, STEP, AutoCAD, Solidworks, STL, PTC Creo, DWG, PDF, etc.. |
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The Way of Color Contrast for Plastic |
RAL PANTONE |
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Certificated |
ISO 9001:2015 Certificated, SGS Certificated |
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Service Project |
To provide production design, production and technical service, mould development and processing, product assembly and packaging,etc |
Our Services
1.Product Design,Structural Optimization,Process Optimization
2.Mold Making,Plastic Molding Parts,Casting Parts,Machining Part
3.Manage Project,Control The Delivery and Quality of Products
4.Arranging the Transportation,Customs Clearance and other Matters for You.
We can offer the full range of service from mold designing, making, plastic part molding to printing, assembly, package, and shipping arrangement.
In the service of plastic injection, we are more than just an injection molder.
We provide solutions to manufacturing from start to finish.
Our expertise enables us to provide clients with superior product by providing the
highest quality in design, development, and solutions for precision injection molding and related manufacturing.
We have over 10 years production experience.
Custom Plastic Injection Molding Services
Precision Plastic Injection Molding Services
We offers comprehensive custom plastic injection molding services to a wide range of industries. From low volume work to high volume production runs, we have the expertise and facilities to meet our customers’ contract manufacturing needs. We offer 2 shot, sandwich and insert injection molding as well as micro and gas assist molding. We have both 10K and 100K clean room manufacturing facilities for those customers in the medical, pharmaceutical, food, beverage and electronics industries. Our comprehensive plastic injection molding abilities include machines with clamping forces from 18 to 3,000 tons, allowing us to produce nearly any plastic part including micro parts, thin-walled parts, and large components that require multiple shots.
Advantages:
1. Competitive price.
2. Strict quality control system.
3. Quick mold making and delivery.
4. Advanced equipment, excellent R&D teams.
5. Professional technicians and rich experienced workers.
Quality First,Price Best,Service Foremost!
We assure you of our best services at all times!
Q1. What’s your main business?
A1: We are mainly making plastic injection moulding parts.
Q2. Are you a trading company or manufacturer?
A2: We are a manufacturer with foreign trade experience.
Q3. What types of files(drawings) do you accept?
A3: With our cad systems we can take the following files in:.STP / .IGS / .DXF / .DWG / .PPT / .STL /
.X_T / .CATIA / UG files, etc..
Q4. Can you Provide OEM?
A4: Yes,we can provide OEM service.
Q5. If make the molds for us,will you disclose our files?
A5: All the files are confidential, we can CHINAMFG the NDA first when required.
Q6. Do you provide design service? I have an idea for a new products,but I don’t know whether it can be realized.
Can you help?
A6: Definitely ok. Our R&D department will help you design the idea to be realized with extensive technical
supports.
Q7. Do you have after-sales service?
A7: Yes,we will provide technical supports with 7×24 hours.
Q8. If I decide to go ahead with my project, how long will it take to get the trial samples?
A8: 3-6 weeks depends on the part construction.
Q9. How about your facilities?
A9: 8 sets sodick EDM, 9 mirror EDM, 8 high speed cnc.
You can look through our website to find your interest or email your any questions through
below approach! We will reply to you within 12 hours.
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| Material: | ABS |
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| Application: | Medical, Household, Electronics, Automotive, Agricultural |
| Certification: | TS16949, RoHS, ISO |
| Samples: |
US$ 5/Piece
1 Piece(Min.Order) | Order Sample Samples produced according to customer′s drawing
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| Customization: |
Available
| Customized Request |
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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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What are the limitations of using plastic gears in industrial settings?
Using plastic gears in industrial settings has certain limitations. Here’s a detailed explanation of these limitations:
- Lower Load Capacity: Plastic gears generally have lower load-bearing capacities compared to metal gears. They are more susceptible to deformation and wear under heavy loads or high torque conditions. This makes them less suitable for applications that require withstanding substantial forces or transmitting high power.
- Temperature Sensitivity: Plastic gears have temperature limitations, and their performance can be affected by temperature variations. Some plastic materials may experience dimensional changes, loss of strength, or reduced stiffness at elevated temperatures. Additionally, high temperatures can accelerate wear and reduce the lifespan of plastic gears. Therefore, plastic gears may not be suitable for applications that involve high-temperature environments or extreme temperature fluctuations.
- Environmental Sensitivity: Plastic gears can be sensitive to certain environmental conditions. Certain plastic materials may degrade or become brittle when exposed to specific chemicals, solvents, oils, or UV radiation. This restricts their use in applications where exposure to harsh chemicals, lubricants, or outdoor elements is common.
- Wear and Abrasion: While plastic gears can offer good wear resistance, they are generally more prone to wear and abrasion compared to metal gears. Under heavy-load or high-speed conditions, the surface of plastic gears can wear down, leading to a decrease in performance and potential failure over time. Additional measures, such as incorporating reinforcements or using lubrication, may be necessary to mitigate wear in certain applications.
- Dimensional Stability: Plastic materials can have lower dimensional stability compared to metals. They may experience creep, shrinkage, or expansion over time, which can affect the accuracy and reliability of gear operation, particularly in applications with tight tolerances or precise gear meshing requirements.
- Impact Resistance: Plastic gears may have limited impact resistance compared to metal gears. They can be more susceptible to damage or fracture when subjected to sudden impact or shock loads. This makes them less suitable for applications with high impact or heavy-duty requirements.
- Compatibility with Existing Systems: In some cases, replacing metal gears with plastic gears may require modifications to the existing system. Plastic gears may have different dimensions, mounting requirements, or gear ratios compared to metal gears, necessitating design changes or adaptations to accommodate the use of plastic gears.
Despite these limitations, plastic gears can still offer significant advantages in certain industrial settings, such as reduced weight, noise reduction, and cost-effectiveness. It’s crucial to carefully evaluate the specific application requirements and consider the trade-offs between the benefits and limitations of plastic gears when deciding whether they are suitable for a particular industrial setting.
How do you prevent premature wear and degradation in plastic gears?
Preventing premature wear and degradation in plastic gears requires implementing various measures and considerations. Here’s a detailed explanation of how to achieve this:
1. Material Selection: Choose a plastic material with suitable properties for the specific application. Consider factors such as strength, stiffness, wear resistance, and compatibility with operating conditions. Opt for materials that have good resistance to wear, fatigue, and environmental factors to minimize premature degradation.
2. Gear Design: Pay attention to the design of the plastic gears to minimize wear and degradation. Optimize the tooth profile, gear geometry, and load distribution to reduce stress concentrations and ensure even load sharing among the teeth. Incorporate features such as fillets, reinforcements, and optimized tooth profiles to enhance the gear’s durability.
3. Lubrication: Proper lubrication is essential to reduce friction, minimize wear, and prevent premature degradation. Choose lubricants that are compatible with the plastic material and the operating conditions. Ensure adequate lubrication by following manufacturer recommendations and implementing proper lubrication techniques such as oil bath, grease, or dry lubrication.
4. Operating Conditions: Consider the operating conditions and make adjustments to prevent premature wear and degradation. Control operating temperatures within the recommended range for the plastic material to avoid thermal degradation. Avoid excessive speeds or loads that can lead to increased friction and wear. Minimize exposure to harsh chemicals, UV radiation, or abrasive particles that can degrade the plastic material.
5. Maintenance: Implement regular maintenance practices to prevent premature wear and degradation. Conduct periodic inspections to identify signs of wear or damage. Replace worn or damaged gears promptly to prevent further degradation. Follow recommended maintenance schedules for lubrication, cleaning, and any other specific requirements for the plastic gears.
6. Proper Installation: Ensure that plastic gears are installed correctly to minimize wear and degradation. Follow manufacturer guidelines and recommendations for installation procedures, such as proper alignment, torque values, and fastening techniques. Improper installation can lead to misalignment, increased stress concentrations, and accelerated wear.
7. Optimized Load Distribution: Design the gear system to ensure even load distribution across the gear teeth. Consider factors such as tooth profile, tooth width, and the number of teeth to optimize load sharing. Uneven load distribution can lead to localized wear and premature degradation of specific gear teeth.
8. Environmental Protection: Protect plastic gears from harsh environmental conditions that can accelerate wear and degradation. Implement measures such as sealing mechanisms, coatings, or encapsulation to shield the gears from exposure to chemicals, moisture, UV radiation, or abrasive particles.
9. Quality Manufacturing: Ensure high-quality manufacturing processes to minimize defects and inconsistencies that can compromise the durability of plastic gears. Use reputable suppliers and manufacturers that adhere to strict quality control measures. Conduct thorough inspections and testing to verify the quality of the gears before installation.
By considering these preventive measures, such as material selection, gear design, lubrication, operating conditions, maintenance, proper installation, load distribution optimization, environmental protection, and quality manufacturing, it’s possible to minimize premature wear and degradation in plastic gears, ensuring their longevity and performance.
Are there different types of plastic materials used for making gears?
Yes, there are different types of plastic materials used for making gears. Here’s a detailed explanation of some commonly used plastic materials in gear manufacturing:
- Acetal (Polyoxymethylene – POM): Acetal is a popular choice for gear applications due to its excellent strength, dimensional stability, low friction, and wear resistance. It has good machinability and can be easily molded into gears with precise tooth profiles. Acetal gears offer low noise operation and have good resistance to moisture and chemicals. They are commonly used in automotive, consumer electronics, and industrial applications.
- Polyamide (Nylon): Polyamide or nylon is another widely used plastic material for gears. It offers good mechanical properties, including high strength, toughness, and impact resistance. Nylon gears have low friction characteristics, good wear resistance, and self-lubricating properties. They are commonly used in applications such as automotive components, power tools, and industrial machinery.
- Polyethylene (PE): Polyethylene is a versatile plastic material that can be used for gear applications. It offers good chemical resistance, low friction, and excellent electrical insulation properties. While polyethylene gears may have lower strength compared to other plastic materials, they are suitable for low-load and low-speed applications, such as in light-duty machinery, toys, and household appliances.
- Polypropylene (PP): Polypropylene is a lightweight and cost-effective plastic material that finds applications in gear manufacturing. It offers good chemical resistance, low friction, and low moisture absorption. Polypropylene gears are commonly used in various industries, including automotive, consumer electronics, and household appliances.
- Polycarbonate (PC): Polycarbonate is a durable and impact-resistant plastic material used for gears that require high strength and toughness. It offers excellent dimensional stability, transparency, and good resistance to heat and chemicals. Polycarbonate gears are commonly used in applications such as automotive components, electrical equipment, and machinery.
- Polyphenylene Sulfide (PPS): Polyphenylene sulfide is a high-performance plastic material known for its excellent mechanical properties, including high strength, stiffness, and heat resistance. PPS gears offer low friction, good wear resistance, and dimensional stability. They are commonly used in demanding applications such as automotive transmissions, industrial machinery, and aerospace equipment.
These are just a few examples of the plastic materials used for making gears. The choice of plastic material depends on the specific requirements of the gear application, including load capacity, operating conditions, temperature range, chemical exposure, and cost considerations. It’s important to select a plastic material that offers the necessary combination of mechanical properties and performance characteristics for optimal gear performance.
editor by CX 2024-04-10