Product Description
QY Precision specializes in design and production of high precision metal parts and components.Focus on industry and action on demand, to be your trusted partner is our mission.
| Services | CNC Milling, CNC Turning, Wire EDM Cutting, 3D Printing,Vacuum Casting,Reaction Injection Molding, Plastic CNC Machining, Laser, Cutting, Stamping Parts, Bending Parts |
| Material | Metal: Aluminum , Copper , Brass , Steel, Stainless Steel, Titanium and etc. |
| Plastic: ABS, POM, PP, PU, PC,PA66, PMMA, PVC, PVE, Nylon and etc. | |
| Surface treatment | Anodizing, Sandblasting, Metal Plating, Polishing, Painting, Powder coating, Brushing ,Silk-screen , Laser Engraving etc. |
| Heat treatment | Annealing, Normalizing , Nitriding, Tempering |
| File Formats | STP, STEP, IGS,STP,X_T ,DXF,DWG , Pro/E, PDF, SLDPRT |
| Inspection | In-house or third party, all the products are strictly inspected by skilled QC |
| Service Type | OEM & ODM Service |
Custom High Precision Brass Stainless Steel CNC Machining Screw gear Miter gear
Gear Introduction
Bevel Gears
Bevel gears are most commonly used to transmit power between shafts that intersect at a 90 degree angle. They are used in applications where a right angle gear drive is required. Bevel gears are generally more costly and are not able to transmit as much torque, per size, as a parallel shaft arrangement.
Worm Gear
Worm gears transmit power through right angles on non-intersecting shafts. Worm gears produce thrust load and are good for high shock load applications but offer very low efficiency in comparison to the other gears. Due to this low efficiency, they are often used in lower horsepower applications.
Helical Gears
Helical gears have teeth that are oriented at an angle to the shaft, unlike spur gears which are parallel. This causes more than 1 tooth to be in contact during operation and helical gears can carry more load than spur gears. Due to the load sharing between teeth, this arrangement also allows helical gears to operate smoother and quieter than spur gears. Helical gears produce a thrust load during operation which needs to be considered when they are used. Most enclosed gear drives use helical gears.
Spur Gears
Spur gears transmit power through shafts that are parallel. The teeth of the spur gears are parallel to the shaft axis. This causes the gears to produce radial reaction loads on the shaft, but not axial loads. Spur gears tend to be noisier than helical gears because they operate with a single line of contact between teeth. While the teeth are rolling through mesh, they roll off of contact with 1 tooth and accelerate to contact with the next tooth. This is different than helical gears, which have more than 1 tooth in contact and transmit torque more smoothly.
Hypoid Gears
Hypoid gears look very much like a spiral bevel gear, but unlike spiral bevel gears, they operate on shafts which do not intersect. In the hypoid arrangement because the pinion is set on a different plane than the gear, the shafts are supported by the bearings on either end of the shaft.
Herringbone Gears
Herringbone gears are very similar to the double helical gear, but they do not have a gap separating the 2 helical faces. Herringbone gears are typically smaller than the comparable double helical and are ideally suited for high shock and vibration applications. Herringbone gearing is not used very often due to their manufacturing difficulties and high cost.
Why Choose QY Precision
FAQ
1.How to get a quote?
Kindly send us the drawing of your product,please. Including details as below: a.Materials b. Surface Finish c. Tolerance d. Quantity If you need solutions for your application, kindly send us your detail requirements, and we will have engineers to service you.
2.How does the payment process work?
Payment terms are flexible for us. We can accept different type payment way:
3.How do I know about the production?
We will double confirm your requirements and send you the sample before the mass production as you required. During the mass production,
4.How do I know about the delivery?
Before shipment we will confirm with you about all the details including CI and other attention issues. After ship out, we will inform you of the tracking number and keep updating the latest shipping information for you.
5.What will you do for after sales?
We will follow up and await your feedback. Any question related to our metal parts, our experienced engineers are ready to help. And welcome to contact for any supporting of your other application even if their is no relationship with our products.
| Application: | Fastener, Auto and Motorcycle Accessory, Hardware Tool, Machinery Accessory, Robotics |
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| Standard: | GB, EN, API650, China GB Code, JIS Code, TEMA, ASME, CE, FCC, RoHS, ISO9001:2008 |
| Surface Treatment: | Anodizing |
| Samples: |
US$ 0/Piece
1 Piece(Min.Order) | Order Sample |
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| Customization: |
Available
| Customized Request |
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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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How do miter gears handle changes in direction and torque transmission?
Miter gears are specifically designed to handle changes in direction and torque transmission efficiently. Here’s an explanation of how they accomplish this:
1. Right Angle Transmission:
Miter gears are primarily used to transmit rotational motion at a 90-degree angle. When two miter gears with intersecting shafts are meshed together, they allow the input and output shafts to be positioned perpendicular to each other. This right angle transmission capability enables changes in direction within a compact space.
2. Interlocking Tooth Design:
Miter gears have teeth that are cut at a specific angle to match the gear’s cone shape. When two miter gears mesh, their teeth interlock and transfer torque between the gears. The interlocking tooth design ensures a smooth and efficient torque transmission, minimizing power loss and maximizing mechanical efficiency.
3. Bevel Gear Configuration:
Miter gears belong to the bevel gear family, which includes straight bevel gears and spiral bevel gears. Straight bevel gears have straight-cut teeth and are suitable for applications with moderate torque and speed requirements. Spiral bevel gears have curved teeth that gradually engage, providing higher torque capacity and smoother operation. The choice between straight and spiral bevel gears depends on the specific application’s torque and performance requirements.
4. Meshing Alignment:
Proper alignment of miter gears is crucial for efficient torque transmission and smooth operation. The gears must be precisely positioned and aligned to ensure accurate meshing of the teeth. This alignment is typically achieved using precision machining and assembly techniques to maintain the desired gear contact pattern and tooth engagement.
5. Load Distribution:
When torque is transmitted through miter gears, the load is distributed across multiple teeth rather than concentrated on a single tooth. This load distribution helps to minimize tooth wear, reduce stress concentrations, and increase the overall load-carrying capacity of the gears.
6. Lubrication:
Proper lubrication is essential for the smooth operation and longevity of miter gears. Lubricants reduce friction and wear between the gear teeth, ensuring efficient torque transmission and minimizing heat generation. The type and method of lubrication depend on the specific application and operating conditions.
7. Backlash Control:
Backlash refers to the slight clearance between the mating teeth of gears. Miter gears can be designed with specific tooth profiles and manufacturing techniques to control backlash and minimize any unwanted movement or play. This helps maintain accuracy and precision in direction and torque transmission.
In summary, miter gears handle changes in direction and torque transmission through their right angle transmission capability, interlocking tooth design, bevel gear configuration, precise meshing alignment, load distribution across teeth, proper lubrication, and backlash control. These features make miter gears an effective choice for applications that require efficient and reliable direction and torque transmission.
How do miter gears contribute to transmitting power at different angles?
Miter gears play a crucial role in transmitting power at different angles due to their unique design and meshing characteristics. Here’s a detailed explanation:
1. Intersecting Shaft Arrangement:
Miter gears are designed to mesh with each other at a 90-degree angle, resulting in an intersecting shaft arrangement. This arrangement allows the input and output shafts to be oriented perpendicularly, enabling power transmission at different angles. By changing the orientation and position of the miter gears, power can be redirected or transmitted along different axes.
2. Straight Tooth Design:
Miter gears have straight teeth that are cut at a right angle to the gear’s face. This tooth design facilitates proper meshing and engagement between the gears when they are at a 90-degree angle. The straight tooth design ensures efficient power transmission and minimizes energy losses during the transfer of rotational motion.
3. Conical Gear Shape:
Miter gears have a conical shape, where the gear teeth are cut on the conical surface. This conical shape allows for the correct alignment and engagement of the teeth when the gears mesh at a 90-degree angle. The conical gears ensure that the teeth maintain proper contact and transmit power smoothly, even when power is transmitted at different angles.
4. Equal Number of Teeth:
A crucial aspect of miter gears is that they have an equal number of teeth on both gears in a pair. This balanced tooth configuration ensures proper meshing and a constant speed ratio between the gears. The equal number of teeth is essential for transmitting power accurately and maintaining the desired rotational relationship between the input and output shafts.
5. Tooth Contact and Load Distribution:
When miter gears mesh, the contact between the teeth occurs along a single line, known as the line of contact. This concentrated contact area facilitates effective load distribution and ensures that the gear teeth bear the transmitted torque evenly. Proper tooth contact is vital for efficient power transmission and preventing premature wear or damage to the gears.
6. Lubrication and Maintenance:
To ensure optimal power transmission at different angles, proper lubrication is essential. Lubricants help reduce friction and wear between the gear teeth, ensuring smooth operation and extending the lifespan of the gears. Regular maintenance, including lubrication and inspection, helps maintain the performance and reliability of the miter gears over time.
In summary, miter gears contribute to transmitting power at different angles through their intersecting shaft arrangement, straight tooth design, conical gear shape, equal number of teeth, and consideration for tooth contact and load distribution. By utilizing these design features and ensuring appropriate lubrication and maintenance, miter gears enable efficient power transmission at various angles, making them valuable components in machinery and mechanical systems.
What is the purpose of using miter gears in mechanical systems?
Miter gears serve several purposes and offer distinct advantages when used in mechanical systems. Here’s a detailed explanation:
1. Change of Shaft Direction:
One of the primary purposes of using miter gears is to facilitate a change in the direction of shaft rotation. When two miter gears with intersecting shafts are meshed together, they allow the transmission of rotational motion at a 90-degree angle. This enables the redirection of power and torque to a different axis, which can be crucial for the functioning of various mechanical systems.
2. Power Transmission:
Miter gears are designed to efficiently transmit power between intersecting shafts. The meshing of the gear teeth ensures a smooth transfer of rotational energy, enabling the transmission of torque and rotational motion from one shaft to another. This makes miter gears suitable for applications where power needs to be transmitted between perpendicular axes.
3. Speed Reduction or Increase:
By using miter gears with different numbers of teeth or by combining them with other gears, speed reduction or speed increase can be achieved. The gear ratio between the miter gears determines the change in rotational speed. This allows for the adjustment of output speed to match the requirements of the mechanical system, ensuring optimal performance.
4. Compact Design:
Miter gears are known for their compact design, making them valuable in applications where space is limited. The intersecting shafts and the conical shape of the gears allow for efficient power transmission while occupying a small footprint. This compactness is particularly beneficial in devices and systems where size and weight constraints are critical factors.
5. Alignment and Torque Distribution:
Miter gears help maintain proper alignment and torque distribution between intersecting shafts. The gear teeth engagement ensures accurate alignment, which is essential for smooth and efficient operation. Additionally, the equal distribution of torque among the teeth of miter gears helps prevent excessive stress on individual gear teeth, promoting longevity and reliability.
6. Applications:
Miter gears find applications in a wide range of mechanical systems, including:
- Power transmission systems
- Automotive differentials
- Mechanical clocks
- Robotics
- Printing machinery
- Woodworking tools
- Camera lenses
In summary, the purpose of using miter gears in mechanical systems is to facilitate a change in shaft direction, transmit power efficiently, achieve speed reduction or increase, maintain a compact design, and ensure proper alignment and torque distribution. These characteristics make miter gears suitable for various applications, contributing to the functionality and performance of mechanical systems.
editor by CX 2023-12-04