Product Description
Product Description
TWO-PIECES
easily installed and disassembled, reducing labor and downtime when adjustment, removal, or replacement is necessary. The two-piece shaft collar uses the full seating torque of its forged screws to apply a uniform distribution of forces around the shaft’ circumference. These clamping forces provide the collar with a holding power superior to one-piece and set screw shaft collars. we keeps both halves of the split collar together throughout the manufacturing process to assure a perfect match for proper fit, alignment, and holding power. This process also makes the two-piece collar more adaptable to shafts which vary a small amount from nominal size. we manufactures two-piece clamp shaft collars in 12l15 lead-free steel with a zinc or proprietary black oxide finish, 303 and 316 stainless steel, high-strength 2571 aluminum with or without an anodize finish, titanium, and engineered plastic. Bore sizes range from 1/8″ to 6″ and 3mm to 150mm.
1.materials:stainless steel,alloy steel ,aluminum ,brass etc.
2.Finish: Zinc plating, Nickel plating,nature
3.competitive price ,prompt delivery
4.OEM service as your drawings
Technics
1.Milling 2.grinding 3.Turning 4.wire-cutting 5.CNC bending 6.CNC machining 7.Stamping 8.forging 9.boring 10.broaching and so on .
Accuracy
1.Milling:0.01mm 2.Turning:0.01mm 3.Grinding:0.002mm 4.Wire-cutting :0.005mm 5.CNC Machining : 0.005mm
Production ability
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EQUIPMENT LIST |
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NAME
|
SPECIFICATION |
BRAND |
ORIGINAL PLACE |
QUANTITY |
|
CNC Machines |
Graph 600 |
KNUTH |
CHINA |
20 |
|
1370 |
KAFO |
TAPAN |
20 |
|
|
EDM Machines |
ZNC450 |
BHangZhouNA |
ZheJiang |
20 |
|
ZNC430 |
BHangZhouNA |
ZheJiang |
30 |
|
|
Grinding Machines |
ACC-350ST |
BESFORD |
CHINA |
50 |
|
Auto Lathe Machining |
L150G-II |
OKUMA |
CHINA |
80 |
|
Wire Cutting Machines |
DK7732 |
NEW FAST |
CHNA |
30 |
|
Milling Machine |
SHCM-97A |
GENTIGER |
ZheJiang |
20 |
|
CMM Machine |
CRT-PA574 |
MITUTYO |
JAPAN |
10 |
|
Hardness Tester |
TILO-T60 |
MITUTYO |
JAPAN |
5 |
Productions showing:
| More Detail Informations | |
| Sample Available |
1.Sample is free of charge if we have the existing,you only need to pay the freight cost.Sample will be provided within 3 to 10 working days. 2.If the products is non-standard and no existing tooling inventory,The full mould cost needed prepaid, sample will be provided within 7 to 15 working days, you’ll pay the freight cost. |
| MOQ | 1pcs |
| Pricing Term | EXW HangZhou ,FOB,CIF,CNF,DDU,etc. |
| Payment Term | TT(30% in advance as deposit,balance before delivery),L/C,Western Union,PayPal etc. |
| Port of loading | HangZhou port or ZheJiang port. |
| Lead Time | 15-35 working days after order and deposit received. |
| Warranty |
1.We shoulder the ability based on product categories to determine the warranty, and guarantee more than 18 months. 2.We don’t assume responsibility for the damage which is caused by indirect, accidental events at anytime anywhere. |
Founded in 2005,HangZhou HC Co.,Ltd is an IATF16949:2016 manufacturer.We have more than 20 years of production experience in the production of cnc machining/Milling parts,cold forming,graphite products, We not only have new imported prodution equipment and spacious storage space,but also have a group of experienced workers and professional engineering R & D team.Therefore, our company has enough strength to meet the needs of customers.
Equipments & Working plant:
Worry about our quality problem?
We are an IATF16949:2016 Certifed supplier, strictly execute inspection on ISO quality control system. All our products will pass 10-step inspections: it starts from incoming material inspection to IPQC, then FQC and final inspection with reports before shipment.
Packing:Generally carton or wooden case or plastic foam with standard export wooden pallet , or as per consumer’s requirements.
Certifications:
Your Satisfaction, Our Motivation!
FAQ
Q1. Are you factory or trading company?
A: We are a customized factory with independent oversea trading office .
Q2.Can you provide sample for us?
A: Yes, free sample is available
Q3. What raw material do you use?
A: Stainless Steel, Carbon Steel, Mild Steel, Galvanized Steel, Aluminum alloy, brass, copper, Aluminum etc.
Q4. What finishes can you provide?
A: powder coating, polishing, zinc/nickel /chrome plating, painting, anodized, hot dip galvanized, sandblasted etc.
Q5. How do you ensure quality control?
A: We inspect every process based on your drawings or samples and also check the products before packing
Q6. Is small quantity available?
A: Yes, Small quantity for trial order is available.
Q7. How do you ship the goods?
A: We have our cooperation forwarder, they can deliver the goods to you in very short time with competitive price, and you can ship by your own agent as your convenience.
Q8. How about your delivery time ?
A: 3-10 days for samples and 15-45 days for mass production .
Q: How To Place A Order?
* You send us drawing or sample
* We make the sample and send it to you
* You think the sample is good then place an order and pay us 30% deposit
* We start to make the product
* When the goods is done, we take photoes for your check and you then pay the balance
* We deliver the products to courier company
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| Application: | Auto and Motorcycle Accessory, Machinery Accessory |
|---|---|
| Standard: | GB, EN, JIS Code, TEMA, ASME |
| Surface Treatment: | Anodizing |
| Production Type: | Mass Production |
| Machining Method: | CNC Turning |
| Material: | Nylon, Steel, Plastic, Alloy, Aluminum |
| Samples: |
US$ 10/Piece
1 Piece(Min.Order) | |
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| Customization: |
Available
| Customized Request |
|---|
Can I purchase locking collars with specific features suitable for use in conveyor systems?
Yes, you can purchase locking collars with specific features that are suitable for use in conveyor systems. Conveyor systems often require specialized locking collars to ensure secure and reliable shaft attachment, accommodate the unique demands of conveyor applications, and optimize overall system performance. Here are some specific features to consider when purchasing locking collars for conveyor systems:
- Anti-Slip Design:
- High Load Capacity:
- Corrosion Resistance:
- Easy Installation and Adjustment:
- Shaft Protection:
- Alignment and Positioning:
- Industry Standards and Compatibility:
- Manufacturer Support and Expertise:
Look for locking collars that have anti-slip features to prevent unintended movement or slippage of the collar on the conveyor shaft. These features can include serrations, knurls, or specialized surface treatments that enhance the grip between the locking collar and the shaft, providing a secure and reliable connection.
Conveyor systems often handle heavy loads, so it’s important to choose locking collars with a high load capacity. Look for collars that are designed to withstand the specific loads and forces encountered in conveyor applications. Consider factors such as the material strength, geometry, and construction of the locking collar to ensure it can handle the anticipated load requirements.
Depending on the environment in which the conveyor system operates, corrosion resistance may be crucial. Look for locking collars made from materials that offer excellent corrosion resistance, such as stainless steel or corrosion-resistant coatings. This helps to protect the collars from degradation due to exposure to moisture, chemicals, or other corrosive substances.
Consider locking collars that offer ease of installation and adjustment features. Conveyor systems often require frequent maintenance, adjustments, or replacements, so having locking collars that are designed for quick and convenient installation and adjustment can save time and effort. Look for collars with user-friendly designs, such as tool-free locking mechanisms or integrated adjustment features.
Locking collars that provide shaft protection features can help prevent damage or wear to the conveyor shaft. Look for collars that have smooth internal surfaces, chamfered edges, or materials that minimize friction and abrasion on the shaft. This helps to extend the lifespan of both the locking collar and the shaft, reducing maintenance requirements.
In conveyor systems, precise alignment and positioning of components are crucial for smooth operation. Consider locking collars that offer alignment or positioning features, such as set screws, keyways, or specialized designs that facilitate accurate placement of the collar on the shaft. These features can help maintain proper alignment of conveyor components and minimize the risk of misalignment-related issues.
Ensure that the locking collars you purchase comply with relevant industry standards and specifications. This ensures compatibility and interchangeability with other components of the conveyor system. Look for locking collars that meet recognized standards to ensure proper integration and reliable performance.
Consider purchasing locking collars from manufacturers or suppliers who specialize in conveyor systems or mechanical power transmission components. These manufacturers often have in-depth knowledge and expertise in designing locking collars specifically for conveyor applications. They can provide guidance, technical support, and customized solutions to meet your specific requirements.
When purchasing locking collars for conveyor systems, it’s important to consider the specific needs and requirements of your application. Consult with manufacturers, suppliers, or industry experts to ensure that the locking collars you select are suitable for your conveyor system and will deliver optimal performance and reliability.
By considering these specific features and factors, you can purchase locking collars that are tailored to the unique demands of conveyor systems, ultimately enhancing the efficiency, durability, and overall performance of your conveyor application.
What are the design considerations when incorporating locking collars in machinery and equipment?
When incorporating locking collars in machinery and equipment, several design considerations should be taken into account to ensure their effective and reliable operation. Here are some important design considerations:
- Shaft and Collar Compatibility:
- Load-Bearing Capacity:
- Environmental Conditions:
- Installation and Adjustment:
- Anti-Rotation and Axial Positioning:
- Clearance and Interference:
- Maintenance and Accessibility:
Ensure that the locking collar is compatible with the shaft and the components it needs to secure. Consider factors such as shaft diameter, tolerance, surface finish, and material compatibility. The dimensions and specifications of the collar should align with the shaft to provide a proper fit and secure grip.
Assess the expected loads and forces that the locking collar will need to withstand. Consider factors such as the weight of the components being secured, the rotational speeds involved, and any external forces or vibrations. Select a locking collar with an appropriate load-bearing capacity to ensure it can handle the anticipated loads without compromising performance or safety.
Take into account the environmental conditions in which the locking collar will operate. Consider factors such as temperature extremes, moisture, chemicals, dust, or other contaminants. Choose a locking collar made from materials that are resistant to corrosion, wear, or degradation in the specific environment to ensure long-term performance and reliability.
Consider the ease of installation and adjustment of the locking collar. Depending on the application, it may be necessary to disassemble or reposition components, or make fine adjustments during the installation process. Design the machinery or equipment in a way that allows for convenient access to the locking collar and its adjustment mechanism, ensuring efficient and accurate installation.
Locking collars are often used to prevent rotation or axial movement of components. Ensure that the design incorporates features that effectively prevent rotational or axial forces from causing slippage or misalignment. This may involve incorporating additional features such as keyways, flats, or precision mating surfaces to enhance the stability and positioning of the components.
Consider the clearance and potential interference between the locking collar and adjacent components or structures. Ensure that there is sufficient space around the collar to allow for its installation, adjustment, and removal without obstruction. Account for any potential interference that may occur during the operation or maintenance of the machinery or equipment.
Design the machinery or equipment to facilitate easy maintenance and accessibility to the locking collar. This includes providing adequate clearance for lubrication, inspection, and potential replacement of the collar if needed. Consider the overall maintenance requirements and ensure that the locking collar can be effectively serviced without significant disassembly or disruption to the surrounding components.
By considering these design considerations, you can optimize the incorporation of locking collars in machinery and equipment, ensuring their proper functionality, longevity, and ease of maintenance. Collaborating with experienced engineers and following industry standards and guidelines can also help in designing robust and efficient systems that benefit from the use of locking collars.
How do locking collars compare to other types of shaft collars, such as set-screw collars or clamp collars?
When comparing locking collars to other types of shaft collars, such as set-screw collars or clamp collars, there are several factors to consider:
- Installation Method:
- Security and Holding Power:
- Shaft Protection:
- Adjustability:
- Application Suitability:
- Complexity and Cost:
Locking collars typically use mechanisms like split designs, threads, ratcheting, or adhesive lining to secure them to the shaft. In contrast, set-screw collars rely on a screw that is tightened against the shaft, while clamp collars utilize a band or clamp that is tightened around the shaft.
Locking collars are often designed to provide high levels of security and holding power. The various mechanisms they employ, such as the split design, threading, or ratcheting, offer a more secure grip on the shaft, minimizing the risk of slippage or loosening under torque or vibration. Set-screw collars and clamp collars, while effective in many applications, may be more prone to slippage or require periodic adjustment to maintain their grip.
Locking collars, particularly those with split designs or adhesive lining, can provide better protection for the shaft. They distribute the clamping force more evenly, reducing the risk of damage or deformation to the shaft. Set-screw collars, if not properly installed or tightened, can potentially create localized stress points or indentations on the shaft surface. Clamp collars, while generally providing good protection, may exert more localized pressure due to their band or clamp design.
Set-screw collars offer some adjustability as the set screw can be loosened and repositioned on the shaft. This allows for fine-tuning or repositioning of the collar. Clamp collars often provide a degree of adjustability as well, as the clamp or band can be loosened and repositioned. Locking collars, depending on their specific design, may offer limited or no adjustability once fully tightened.
The choice between locking collars, set-screw collars, or clamp collars depends on the specific application requirements. Locking collars are often preferred in high-torque or high-vibration applications where secure and reliable shaft connections are crucial. Set-screw collars and clamp collars are commonly used in applications with lower torque or where occasional adjustment or removal is necessary.
Locking collars, with their various mechanisms and designs, can be more complex in construction compared to set-screw collars or clamp collars. This complexity may result in higher manufacturing costs. Set-screw collars and clamp collars, being simpler in design, are often more cost-effective options.
Ultimately, the choice between locking collars, set-screw collars, or clamp collars depends on the specific needs of the application. Consider factors such as torque requirements, vibration levels, ease of installation, adjustability, shaft protection, and budget constraints to determine the most suitable collar type for your particular application.
editor by CX 2024-01-04