Product Description
Detailed Photos
Product Description
High modular design, flexible mounting mode.
Integrated casting housing,compact dimension, stable transmitting and low noise level.
Perfect oil leakage preventing makes the good sealings and can be used in wide range of industry.
Advanced gear grinding and modified profile, high loading support and more safe operation.
High efficiency and save power.
Save cost and low maintenance.
Main applied for
Harbor and shipping
Hoist and transport
Electric power
Coal mining
Cement and construction
Paper and light industry
Product Parameters
|
Housing material |
Cast iron/Ductile iron |
|
Housing hardness |
HBS190-240 |
|
Gear material |
20CrMnTi alloy steel |
|
Surface hardness of gears |
HRC58°~62 ° |
|
Gear core hardness |
HRC33~40 |
|
Input / Output shaft material |
42CrMo alloy steel |
|
Input / Output shaft hardness |
HRC25~30 |
|
Machining precision of gears |
accurate grinding, 6~5 Grade |
|
Lubricating oil |
GB L-CKC220-460, Shell Omala220-460 |
|
Heat treatment |
tempering, cementiting, quenching, etc. |
|
Efficiency |
94%~96% (depends on the transmission stage) |
|
Noise (MAX) |
60~68dB |
|
Temp. rise (MAX) |
40°C |
|
Temp. rise (Oil)(MAX) |
50°C |
|
Vibration |
≤20µm |
|
Backlash |
≤20Arcmin |
|
Brand of bearings |
China top brand bearing, HRB/LYC/ZWZ/C&U. Or other brands requested, SKF, FAG, INA, NSK. |
|
Brand of oil seal |
CZPT — ZheJiang or other brands requested |
Our Advantages
Packaging & Shipping
Certifications
Company Profile
Xihu (West Lake) Dis.ng Transmission Equipment Co., Ltd. located HangZhou city, ZHangZhoug, as 1 professional
manufacturer and exporter of cycloidal pin wheel reducer,worm reducer, gear reducer, gearbox ,
AC motor and relative spare parts, owns rich experience in this line for many years.
We are 1 direct factory, with advanced production equipment, the strong development team and
producing capacity to offer quality products for customers.
Our products widely served to various industries of Metallurgy, Chemicals, textile,medicine,wooden
etc. Main markets: China, Africa,Australia,Vietnam, Turkey,Japan, Korea, Philippines…
Welcome to ask us any questions, good offer always for you for long term business.
FAQ
Q: Are you trading company or manufacturer?
A: We are factory.
Q: How long is your delivery time?
A: Generally it is 5-10 days if the goods are in stock. or it is 15-20 days if the goods are not in stock.
Q: Can we buy 1 pc of each item for quality testing?
A: Yes, we are glad to accept trial order for quality testing.
Q:How to choose a gearbox which meets your requirement?
A:You can refer to our catalogue to choose the gearbox or we can help to choose when you provide
the technical information of required output torque, output speed and motor parameter etc.
Q: What information shall we give before placing a purchase order?
A:a) Type of the gearbox, ratio, input and output type, input flange, mounting position, and motor informationetc.
b) Housing color.
c) Purchase quantity.
d) Other special requirements.
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| Application: | Motor, Machinery, Marine, Agricultural Machinery |
|---|---|
| Hardness: | Hardened Tooth Surface |
| Installation: | 90 Degree |
| Layout: | Coaxial |
| Gear Shape: | Bevel Gear |
| Step: | Single-Step |
| Samples: |
US$ 200/Piece
1 Piece(Min.Order) | |
|---|
Performance of Helical Gearboxes in Applications Requiring Frequent Starts and Stops
Helical gearboxes are well-suited for applications that involve frequent starts and stops due to their design characteristics. Here’s how they fare in such scenarios:
- Smooth Engagement: Helical gears offer gradual and smooth engagement, which reduces shock loads during starts and stops. This feature helps minimize wear and stress on gear teeth and other components.
- Noise and Vibration Reduction: The helical tooth arrangement results in less noise and vibration compared to other gear types. This is especially beneficial in applications where noise reduction is a priority.
- Efficient Power Transmission: Helical gears efficiently transmit power even during frequent starts and stops. The gradual contact between gear teeth and the larger tooth engagement area contribute to efficient power transfer.
- Less Backlash: Helical gearboxes typically have lower backlash compared to other gear types. This means there’s less play between gear teeth, resulting in more accurate and consistent motion control.
- Heat Dissipation: The helical tooth design distributes loads and heat more evenly, which can help dissipate heat generated during frequent starts and stops.
- Longevity: The reduced wear and improved load distribution contribute to the longevity of helical gearboxes, making them suitable for applications requiring frequent cyclic motion.
In summary, helical gearboxes perform well in applications involving frequent starts and stops. Their smooth engagement, reduced noise and vibration, efficient power transmission, and durability make them a reliable choice for industries that demand precise and controlled motion despite frequent changes in speed and direction.
Software Tools for Simulating Helical Gear Behavior
Several software tools are available for simulating the behavior of helical gears under different conditions. These tools aid engineers in designing and analyzing helical gear systems for optimal performance and reliability. Some notable software tools include:
- KISSsoft: KISSsoft is a widely used software for the design and analysis of mechanical components, including helical gears. It offers comprehensive calculations for gear geometry, load distribution, contact stresses, and more. The software assists in optimizing gear designs and predicting their behavior under various operating conditions.
- AGMA Rating Suite: The American Gear Manufacturers Association (AGMA) offers software tools that follow AGMA standards for gear design and analysis. These tools provide accurate calculations for gear rating, efficiency, and durability under different load scenarios.
- ANSYS Mechanical: ANSYS Mechanical is a versatile simulation software used for finite element analysis (FEA) of mechanical systems, including helical gears. It allows engineers to perform detailed stress and deformation analysis, simulate contact patterns, and assess the effects of different loads and boundary conditions.
- Gleason CAGE: Gleason’s Computer-Aided Gear Engineering (CAGE) software specializes in gear design and optimization. It offers advanced tools for gear tooth profile generation, simulation of meshing behavior, and optimization of gear parameters.
- MAGMA Soft: MAGMA Soft provides casting simulation software that can be used to predict the solidification behavior and mechanical properties of casted gear components, which is essential for ensuring quality and performance.
- Siemens NX: Siemens NX software includes gear design and analysis capabilities, allowing engineers to simulate gear behavior, calculate load distribution, and optimize gear designs within a comprehensive CAD/CAE environment.
These software tools enable engineers to model and analyze helical gears in a virtual environment, helping them make informed design decisions, optimize gear geometry, and assess gear performance under different conditions. By utilizing these tools, engineers can create reliable and efficient helical gear systems for various industrial applications.
Differences Between Helical Gearboxes and Spur Gearboxes
Helical gearboxes and spur gearboxes are two common types of gearboxes used in various applications. Here are the key differences between them:
- Tooth Design: The main difference between helical and spur gearboxes lies in their tooth design. Helical gearboxes feature helical teeth that are cut at an angle to the gear axis, while spur gearboxes have straight-cut teeth that run parallel to the gear axis.
- Engagement: Helical gearboxes offer a gradual and smooth engagement of teeth due to their helical tooth design. This results in reduced noise and vibration compared to spur gearboxes, which can have more abrupt and noisy tooth engagement.
- Load Distribution: Helical gearboxes have a higher contact ratio between teeth at any given time, which leads to better load distribution across the gear teeth. Spur gearboxes, on the other hand, have fewer teeth in contact at a time, potentially leading to higher stress on individual teeth.
- Efficiency: Helical gearboxes tend to be more efficient than spur gearboxes due to the helical tooth design, which reduces friction and energy losses during gear meshing. The gradual engagement of helical teeth contributes to this higher efficiency.
- Noise and Vibration: Helical gearboxes generate less noise and vibration compared to spur gearboxes. The helical tooth design and smooth engagement help in reducing the impact of gear meshing on overall noise levels.
- Applications: Helical gearboxes are commonly used in applications that require higher torque and smoother operation, such as heavy machinery, automotive transmissions, and industrial equipment. Spur gearboxes are suitable for applications with moderate loads and where noise considerations are not critical.
Overall, helical gearboxes offer advantages in terms of efficiency, load distribution, and noise reduction compared to spur gearboxes. However, the choice between the two depends on specific application requirements and factors such as torque, speed, space constraints, and noise considerations.
editor by CX 2024-04-17
China factory Two Stage Helical Gearbox Motor Parallel Shaft Bevel Reducer Speed Spiral 90 Degree Right Angle Straight Supplier Competitive Price Stainless Steel Gearbox car gearbox
Product Description
Two Stage Helical Gearbox Motor Parallel Shaft Bevel Reducer Speed Spiral 90 Degree Right Angle Straight Supplier Competitive Price Stainless Steel Gearbox
Application of Helical Gearbox
Helical gearboxes are used in a wide variety of applications, including:
- Automotive: Helical gearboxes are used in a variety of automotive applications, including transmissions, differentials, and steering systems. They help to transmit power smoothly and efficiently, which improves the overall performance of the vehicle.
- Machinery: Helical gearboxes are used in a variety of machinery applications, including conveyor belts, elevators, and cranes. They help to transmit power smoothly and efficiently, which improves the overall performance of the equipment.
- Aerospace: Helical gearboxes are used in a variety of aerospace applications, including aircraft engines, landing gear, and control surfaces. They help to transmit power smoothly and efficiently, which improves the overall performance of the aircraft.
- Construction: Helical gearboxes are used in a variety of construction applications, including excavators, bulldozers, and cranes. They help to transmit power smoothly and efficiently, which improves the overall performance of the equipment.
- Other: Helical gearboxes are also used in a variety of other applications, such as wind turbines, robotics, and medical devices. They help to transmit power smoothly and efficiently, which improves the overall performance of the system.
Helical gears are a type of gear that has teeth that are cut at an angle. This angle allows the teeth to engage each other gradually and smoothly, which reduces noise and vibration. Helical gears are often used in high-speed applications, such as in automotive differentials.
Helical gears are made of a variety of materials, including steel, cast iron, and aluminum. The material of the gear will depend on the specific application and the environment in which it will be used.
Helical gears are available in a variety of sizes and styles to accommodate a wide range of applications. They are also available in a variety of ratios, which allows them to be used in a variety of applications.
Here are some of the advantages of using helical gears:
- Reduced noise and vibration: Helical gears help to reduce noise and vibration, which can improve the overall working environment.
- Increased efficiency: Helical gears are more efficient than straight gears, which can help to improve the overall performance of a system.
- Increased durability: Helical gears are made of durable materials that can withstand a lot of wear and tear.
- Cost-effectiveness: Helical gears are a cost-effective way to improve the performance and durability of a system.
Overall, helical gears are a versatile and reliable component that can be used in a wide variety of applications. They offer a number of advantages, including reduced noise and vibration, increased efficiency, increased durability, and cost-effectiveness.
| Application: | Motor, Electric Cars, Motorcycle, Machinery, Marine, Toy, Agricultural Machinery, Car |
|---|---|
| Function: | Distribution Power, Clutch, Change Drive Torque, Change Drive Direction, Speed Changing, Speed Reduction, Speed Increase |
| Layout: | Three-Ring |
| Hardness: | Hardened Tooth Surface |
| Installation: | Torque Arm Type |
| Step: | Stepless |
| Samples: |
US$ 9999/Piece
1 Piece(Min.Order) | |
|---|
Key Factors for Selecting a Helical Gearbox
Choosing the right helical gearbox for an application involves considering several key factors:
- Load and Torque: Evaluate the maximum load and torque requirements to ensure the gearbox can handle the application’s demands.
- Speed Range: Determine the required speed range and ensure the gearbox’s gear ratios can accommodate it.
- Efficiency: Helical gearboxes are known for their high efficiency. Select a gearbox with efficiency ratings that meet your application’s needs.
- Space Constraints: Consider the available installation space and choose a compact gearbox that fits within the available dimensions.
- Mounting Position: The mounting position affects lubrication, cooling, and overall performance. Ensure the gearbox is suitable for the desired mounting orientation.
- Service Life: Choose a gearbox with a service life that matches your application’s expected lifespan.
- Backlash: Evaluate the allowable backlash, which affects precision and positioning accuracy.
- Noise and Vibration: Assess the acceptable noise and vibration levels and choose a gearbox with suitable characteristics.
- Environmental Conditions: Consider factors like temperature, humidity, and dust levels to ensure the gearbox can operate reliably in the application environment.
- Maintenance: Factor in maintenance requirements and choose a gearbox with manageable maintenance needs.
- Cost: Balance performance with budget constraints to find a gearbox that offers the best value for your application.
By carefully evaluating these factors, you can select a helical gearbox that optimally meets your application’s requirements and ensures efficient and reliable operation.
Relationship Between Helix Angle and Load Capacity in Helical Gears
The helix angle of helical gears plays a significant role in determining their load-carrying capacity and overall performance. Here’s the relationship between the helix angle and load capacity:
1. Load Distribution: The helix angle affects how the load is distributed along the gear teeth. A larger helix angle results in a more gradual tooth engagement, allowing for smoother load sharing across multiple teeth. This improves the gear’s ability to handle higher loads.
2. Contact Ratio: The contact ratio, which indicates the number of teeth in contact at any given time, increases with a larger helix angle. A higher contact ratio helps distribute the load over a larger area of the gear teeth, enhancing load-carrying capacity.
3. Tooth Meshing: The helix angle affects how the teeth mesh with each other. A higher helix angle promotes gradual and smoother meshing, reducing the concentration of stress on individual teeth. This results in improved resistance to wear and fatigue.
4. Axial Thrust: Helical gears produce axial thrust due to their helical nature. This thrust can affect the gear’s ability to handle radial loads. Proper consideration of the helix angle can help manage axial thrust and prevent overloading.
5. Lubrication: The helix angle affects the lubrication conditions between gear teeth. A larger helix angle may allow better oil flow and lubrication, reducing friction and wear, thereby enhancing load capacity.
6. Noise and Vibration: The helix angle also influences noise and vibration levels in helical gears. Optimal helix angle selection can minimize noise and vibration, contributing to smoother operation and prolonged gear life.
Optimal Helix Angle Selection: While a larger helix angle generally increases load capacity, it’s important to strike a balance. Extremely large helix angles can lead to reduced tooth strength and efficiency. Engineers consider factors like application requirements, tooth strength, and noise considerations when selecting the optimal helix angle for a specific gear design.
The relationship between the helix angle and load capacity underscores the importance of proper gear design to ensure optimal performance, durability, and reliability in various applications.
Limitations and Disadvantages of Helical Gear Systems
While helical gear systems offer numerous advantages, they also come with certain limitations and disadvantages:
- Axial Thrust: Helical gears generate axial thrust due to the helix angle of the teeth. This thrust can cause additional load on bearings and may require additional measures to counteract.
- Complex Manufacturing: The manufacturing process for helical gears is more complex than that of straight-toothed gears, which can lead to higher production costs.
- Axial Length: Helical gears require more axial space compared to spur gears with the same gear ratio. This can be a limitation in applications with space constraints.
- Sliding Contact: Helical gears have sliding contact between their teeth, which can result in higher friction and more heat generation compared to rolling contact gears.
- Efficiency: Although helical gears are generally efficient, their efficiency can be slightly lower than that of some other gear types, especially at high speeds.
- Complexity in Gearbox Design: The inclination of helical gear teeth introduces additional complexity in gearbox design and alignment.
- Reverse Thrust: In some cases, reverse thrust can occur when helical gears are subjected to high axial loads, leading to undesirable effects.
It’s important to consider these limitations and disadvantages when selecting gear systems for specific applications. Despite these challenges, helical gears remain a popular choice in various industries due to their benefits and overall performance characteristics.
editor by CX 2023-09-04
China Parallel Shaft Helical Gearing Gearbox with Motor crossed helical gearbox
Product Description
Item profile
Parallel shaft helical geared motor is characterised by compact composition, mild fat, big torque and excellent performance. Prompt shipping and delivery within quick time. It is made of rib-bolstered rigid scenario and premium alloy-steel equipment which is hardened by carbon penetration and grinded exactly. Stable in working, low noise, huge in load, low in use, productive in transmission, reduced in temperature rise, and long in provider life. The mounting types are footing, flange, torque arm and so on. The output design are shaft, hollow shaft, the alpine and shrink disc are for choice.
Firm profile
We would like to introduce ourselves as:
The largest maker and exporter of worm equipment reducers in Asia.
Set up in 1976, we transformed from a county owned factory to non-public 1 in 1996. HangZhou SINO-DEUTSCH Electricity TRANSMISSION Tools CO.,LTD is our new identify given that 2001.
We are the initial producer of reducers and gearboxes in China who was offered export license since yr 1993.
“Fixedstar” model gearboxes and reducers are the 1st owner of CHINA Top Model and Most Popular Trade Mark for reducers.
First to achieve ISO9001 and CE Certificate among all companies of gearboxes in China.
As a specialist producer of worm gearbox and worm gear reducers in China, we mostly produce reduction gearbox,aluminum case worm gearboxes,arc gear cylindrical worm gearboxes, worm equipment reducers, in line helical gearboxes, and cyclo push reducers, and so on. These products function rational composition, secure overall performance, and reputable quality, and so on. They are commonly employed in electrical power, mining, metallurgy, constructing materials, chemical, foodstuff, printing, ceramic, paper-producing, tobacco, and other industries.
We have 600 personnel in our manufacturing facility, which covers 70,000 square CZPT in HangZhou. We have been creating 2,500 units of reducers each day because 2012. We are proudly exporting 70% of our products to a lot more than 40 countries all in excess of the term. Our consumers arrive from Italy, Germany, United states, Canada, Spain, United kingdom, Mexico, Brazil, Argentina, Turkey, Singapore and other main industrial countries in the entire world. 30% of them are OEM produced for direct manufacturers of other goods.
We warmly welcome buyers from other areas of the entire world to visit us. Seeing is believing. We are quite self-confident that after browsing our facility, you will have confidence on our products. We have the newest computerized equipments and knowledgeable employees to guarantee the secure good quality and large output. We have the most innovative complex and engineering staff to assistance most demanding need on normal and OEM items.
Hunting CZPT to assembly you in HangZhou, China.
|
/ Piece | |
1 Piece (Min. Order) |
###
| Application: | Motor, Industry |
|---|---|
| Material: | Cast Iron |
| Manipulate Way: | Semi-Automatic Manipulation |
| Trademark: | FIXEDSTAR |
###
| Customization: |
|---|
|
/ Piece | |
1 Piece (Min. Order) |
###
| Application: | Motor, Industry |
|---|---|
| Material: | Cast Iron |
| Manipulate Way: | Semi-Automatic Manipulation |
| Trademark: | FIXEDSTAR |
###
| Customization: |
|---|
How to Choose a Helical Gearbox
Choosing the best helical gearbox is dependent on the type of application you want to use the gear for. You will need to consider the contact ratios and the total of profile shifts required.
Spur gears are more efficient than helical gears
Compared to helical gears, spur gears have straight teeth that are parallel to the axis of the gear. Because they are more efficient, spur gears are often used in low speed applications. However, helical gears are better for low-noise and high-speed applications. Despite their advantages, spur gears are also used in some devices.
Spur gears are not as resilient as other gears. They are less efficient at transmitting power over long distances, and they generate too much noise at high speeds. They also impose a radial load on bearings. They also produce significant vibration that can limit the maximum speed of operation.
Helical gears are better at transferring loads. They are used in a number of applications, including car transmissions, elevators, and conveyors. Helical gears also generate large amounts of thrust. They are also quieter than spur gears.
Unlike spur gears, helical gears use bearings to support their thrust load. They also have more teeth, so they can handle more load than spur gears. They can also be used in non-parallel shafts.
Helical gears are generally used in high-speed mechanical systems. They also have less wear on individual teeth and are quieter running than spur gears.
Helical gears are a refinement of spur gears. They are also used in the printing industry, elevators, and gearboxes for automobiles. They are often used in conjunction with a worm gear to distribute load. They have a higher speed capacity, but they are not as efficient as spur gears. They are used in some high-speed mechanical systems because they generate less noise and vibration.
Spur gears are commonly used in low-speed applications, like rack and pinion setups. Their design makes them more efficient at transmitting power, but they are less resilient than helical gears.
Design space is limited based on a required center distance, target gear ratio, and sum of profile shifts
Using statistically derived parameters, the authors performed a multi-objective optimization of the profile shift of two external cylindrical gears. The main objective of this study was to maximize efficiency and minimize the amount of power lost in the optimized space.
To do this, the authors used a multi-objective optimization algorithm that included all aspects of the optimal profile shift. The algorithm evaluates objective function over a series of generations to determine the best solution.
The multi-objective optimization algorithm was based on a verified optimization algorithm. This algorithm combines analytical pressure loads estimation with an effective method for calculating the deformations of the gear case. Using the aforementioned formulae, the authors were able to identify a feasible solution. The numerical calculations also showed that the corresponding specific sliding coefficients were perfectly balanced.
To identify the most efficient method for determining the profile shift, the authors selected the most efficient method based on the objectives of efficiency and mass. The efficiency objective was considered to be the largest given the small size of the resulting optimization space. This objective is useful in reducing wear failures.
The largest thermal treatment of a cylindrical gear is case hardening. The ISO/TR 4467:1982 standard provides a practical guide for gears. The largest radii of the pinion and wheel are rb1 and rb2. The ratio of tooth width to base circle diameter of the pinion is normally set to less than 1.
Sliding velocity increases as the distance from the pitch point increases in the line of action
Deflections of the involute profile of a helical gear occur due to the load on the teeth. However, the optimum pressure angle for the gear is not known.
The correct pressure angle for a helical gear cannot be calculated without a surface model. Assuming the pressure is uniform over the profile, a pressure angle of 20deg would be a good bet. However, this would require a mathematical model that can be derived from the Archard wear equation.
In general, the pressure angle will be influenced by the diameter, as well as the gear mesh geometry. It is important to know the actual angle of a helical gear since this will affect the curvature of the profile, the normal force, and the radial force.
The best way to measure the pressure angle is to consider the theoretical pitch diameter. If the pitch diameter is small, then the actual angle will be smaller. This will cause a gap between the flanks. However, it can also cause the gear to deform, leading to unexpected working behavior.
One interesting tangent is the pitch plane, an imaginary plane tangent to the pitch surfaces. The pitch plane is the plane perpendicular to the axial plane of the gear cross section. It is usually used as a reference point to calculate the transverse pressure angle.
The working pressure angle is the angle of the pressure line of the gear mesh. This angle is the same as the reference pressure angle, but the length of the contact line is reduced.
The best way to calculate the working pressure angle is to use the pressure line of the gear mesh. This will give a more accurate value. The actual angle of the pressure line is also related to the transmission ratio. This ratio is usually given as the nominal ratio of angular velocities. The actual velocities will fluctuate about this ratio.
Undercut of a helical gear tooth root
Having an undercut at the pinion root can affect the distribution of load along the line of contact of helical gears. This can result in higher than nominal loads on some teeth and amplitude modulated noise.
The tooth root is affected by a number of factors, including the shape of the tooth cutting tool. The cutting tool must be designed to avoid an undercut without reducing the number of teeth. This is achieved by a process called profile shifting.
Profile shift occurs when the cutting tool changes depth, thereby preventing an undercut. It is often used in the manufacturing process to achieve a greater overlap ratio. The higher the overlap ratio, the less variation there is between the contact lines. This reduces the dynamic tooth loads and reduces noise.
The profile shift is most often associated with the cutting tool tip. This is the point where the involute profile exits the gear, before the tip begins to taper. The involute profile can be defined for every transverse section of the gear face width. The boundary point is a point of tangency between the involute and root profiles.
The involute of a circle is a common way to define a gear-tooth profile. The involute is the path traced by the point on the line when rolling on a circle. It is a useful feature for cylindrical involute gears.
The helix angle is also important to the helical gear. It allows for greater contact capacity and increases the bending capacity of the gear. It must be included in specifications for helical teeth. The angle must be measurable and include the (+-) sign.
The bending strength of a tooth depends on the shape of the root. A large undercut reduces the strength of the tooth.
Contact ratios
Whether a helical gearbox is dynamic or steady-state, the contact ratio is a key factor. The total contact ratio defines the average number of teeth in contact in the plane of action. It is calculated by multiplying the transverse contact ratio with the overlap ratio. The overlap ratio is always non-zero.
The total contact ratio must be 1.0 or greater for a constant speed rotation on the driven side. Gears with a low total contact ratio are known to slow down rotation of the driven gear. The total contact ratio is influenced by the length of the contact line. A high contact ratio is a good choice for dynamic loading.
A low contact ratio results in a greater amount of profile shift and a larger amount of noise. If the contact ratio is too high, it may cause excessive EAP sliding velocity and cause scuffing. In addition, an uneven load share results in amplitude modulated vibrations.
A helical gear is a pair of slim spur gears. The gears are layered in a plane that runs parallel to the face width of the gear teeth. Each gear tooth makes contact with the flank of the next gear tooth. The helical gear tooth flank is a 3-dimensional surface that is a tangent to the base circles of the gears.
The tooth shape of the helical gear tooth is also a key factor in the contact ratio. The tooth form is designed to be in relation to the work piece, tooling, dedendum coefficients, tooth forces, and tooth bending stiffness. A gear tooth form must also relate to tooth surface kinematics and microgeometry modifications.
The active profile is a region of the involute profile between the start and end points. A tooth profile that satisfies the basic law of gear-tooth action is often called a conjugate profile.
editor by CX 2023-03-28
China F Series Helical Parallel Reducer Parallel Shaft Vertical Reducer Right Angle Horizontal Reduction Motor Gear Box skew bevel helical gearbox
Solution Description
About Us
1.We manufacture and promote HB,XB,P, F, S,K,R series velocity retarders and transmissions. 2.A range of models are offered. You are welcome to inquire.
3.We offer you certifications:CO/PVOC/ FERI/SUNCAP/ISO 9001:2008
4.OEM services :symbol,lable ,handbook ,and offers
Product Description
FC Parallel Shaft Helical Gearmotor
1. FC series parallel shaft helical gearmotor is primarily based on the design and style of parallel shaft framework , which have a center distance among input and output shaft.
2. Compact building, steady managing, large transmission effectiveness, robust carrying capability.
three. The materials of gears is 20CrMnTi alloy steel and the hardness can reach to HRC58°~ 62° after tempering, cementiting, quenching and many others. heat treatment. All the gears are processed by precise grinding and the precision can get to to quality 6~5.
4. The goods have been largely employed in cranes, conveyors, ceramic machinery, etc.
Kind and specification: FC37~FC157
Solution Parameters
Business Profile
FAQ
1. How to decide on a gearbox which satisfies our requirement?
You can refer to our catalogue to pick the gearbox or we can support to decide on when you supply
the technological data of essential output torque, output pace and motor parameter and so forth.
two. What information shall we give before inserting a purchase purchase?
a) Type of the gearbox, ratio, enter and output kind, enter flange, mounting placement, and motor informationetc.
b) Housing coloration.
c) Buy quantity.
d) Other special needs.
3. What industries are your gearboxes currently being utilised?
Our gearboxes are widely utilised in the areas of textile, foodstuff processing, beverage, chemical market,
escalator,computerized storage equipment, metallurgy, tabacco, environmental safety, logistics and and so on.
4. Do you promote motors?
We have stable motor suppliers who have been coperating with us for a extended-time. They can offer motors
with substantial top quality.
| Application: | Machinery, Car, Lifting Equipment |
|---|---|
| Hardness: | Hardened Tooth Surface |
| Installation: | Horizontal Type |
| Layout: | Expansion |
| Gear Shape: | Cylindrical Gear |
| Step: | Four-Step |
###
| Samples: |
US$ 2000/Piece
1 Piece(Min.Order) |
|---|
###
| Customization: |
Available
|
|---|
| Application: | Machinery, Car, Lifting Equipment |
|---|---|
| Hardness: | Hardened Tooth Surface |
| Installation: | Horizontal Type |
| Layout: | Expansion |
| Gear Shape: | Cylindrical Gear |
| Step: | Four-Step |
###
| Samples: |
US$ 2000/Piece
1 Piece(Min.Order) |
|---|
###
| Customization: |
Available
|
|---|
How to Choose a Helical Gearbox
Choosing the best helical gearbox is dependent on the type of application you want to use the gear for. You will need to consider the contact ratios and the total of profile shifts required.
Spur gears are more efficient than helical gears
Compared to helical gears, spur gears have straight teeth that are parallel to the axis of the gear. Because they are more efficient, spur gears are often used in low speed applications. However, helical gears are better for low-noise and high-speed applications. Despite their advantages, spur gears are also used in some devices.
Spur gears are not as resilient as other gears. They are less efficient at transmitting power over long distances, and they generate too much noise at high speeds. They also impose a radial load on bearings. They also produce significant vibration that can limit the maximum speed of operation.
Helical gears are better at transferring loads. They are used in a number of applications, including car transmissions, elevators, and conveyors. Helical gears also generate large amounts of thrust. They are also quieter than spur gears.
Unlike spur gears, helical gears use bearings to support their thrust load. They also have more teeth, so they can handle more load than spur gears. They can also be used in non-parallel shafts.
Helical gears are generally used in high-speed mechanical systems. They also have less wear on individual teeth and are quieter running than spur gears.
Helical gears are a refinement of spur gears. They are also used in the printing industry, elevators, and gearboxes for automobiles. They are often used in conjunction with a worm gear to distribute load. They have a higher speed capacity, but they are not as efficient as spur gears. They are used in some high-speed mechanical systems because they generate less noise and vibration.
Spur gears are commonly used in low-speed applications, like rack and pinion setups. Their design makes them more efficient at transmitting power, but they are less resilient than helical gears.
Design space is limited based on a required center distance, target gear ratio, and sum of profile shifts
Using statistically derived parameters, the authors performed a multi-objective optimization of the profile shift of two external cylindrical gears. The main objective of this study was to maximize efficiency and minimize the amount of power lost in the optimized space.
To do this, the authors used a multi-objective optimization algorithm that included all aspects of the optimal profile shift. The algorithm evaluates objective function over a series of generations to determine the best solution.
The multi-objective optimization algorithm was based on a verified optimization algorithm. This algorithm combines analytical pressure loads estimation with an effective method for calculating the deformations of the gear case. Using the aforementioned formulae, the authors were able to identify a feasible solution. The numerical calculations also showed that the corresponding specific sliding coefficients were perfectly balanced.
To identify the most efficient method for determining the profile shift, the authors selected the most efficient method based on the objectives of efficiency and mass. The efficiency objective was considered to be the largest given the small size of the resulting optimization space. This objective is useful in reducing wear failures.
The largest thermal treatment of a cylindrical gear is case hardening. The ISO/TR 4467:1982 standard provides a practical guide for gears. The largest radii of the pinion and wheel are rb1 and rb2. The ratio of tooth width to base circle diameter of the pinion is normally set to less than 1.
Sliding velocity increases as the distance from the pitch point increases in the line of action
Deflections of the involute profile of a helical gear occur due to the load on the teeth. However, the optimum pressure angle for the gear is not known.
The correct pressure angle for a helical gear cannot be calculated without a surface model. Assuming the pressure is uniform over the profile, a pressure angle of 20deg would be a good bet. However, this would require a mathematical model that can be derived from the Archard wear equation.
In general, the pressure angle will be influenced by the diameter, as well as the gear mesh geometry. It is important to know the actual angle of a helical gear since this will affect the curvature of the profile, the normal force, and the radial force.
The best way to measure the pressure angle is to consider the theoretical pitch diameter. If the pitch diameter is small, then the actual angle will be smaller. This will cause a gap between the flanks. However, it can also cause the gear to deform, leading to unexpected working behavior.
One interesting tangent is the pitch plane, an imaginary plane tangent to the pitch surfaces. The pitch plane is the plane perpendicular to the axial plane of the gear cross section. It is usually used as a reference point to calculate the transverse pressure angle.
The working pressure angle is the angle of the pressure line of the gear mesh. This angle is the same as the reference pressure angle, but the length of the contact line is reduced.
The best way to calculate the working pressure angle is to use the pressure line of the gear mesh. This will give a more accurate value. The actual angle of the pressure line is also related to the transmission ratio. This ratio is usually given as the nominal ratio of angular velocities. The actual velocities will fluctuate about this ratio.
Undercut of a helical gear tooth root
Having an undercut at the pinion root can affect the distribution of load along the line of contact of helical gears. This can result in higher than nominal loads on some teeth and amplitude modulated noise.
The tooth root is affected by a number of factors, including the shape of the tooth cutting tool. The cutting tool must be designed to avoid an undercut without reducing the number of teeth. This is achieved by a process called profile shifting.
Profile shift occurs when the cutting tool changes depth, thereby preventing an undercut. It is often used in the manufacturing process to achieve a greater overlap ratio. The higher the overlap ratio, the less variation there is between the contact lines. This reduces the dynamic tooth loads and reduces noise.
The profile shift is most often associated with the cutting tool tip. This is the point where the involute profile exits the gear, before the tip begins to taper. The involute profile can be defined for every transverse section of the gear face width. The boundary point is a point of tangency between the involute and root profiles.
The involute of a circle is a common way to define a gear-tooth profile. The involute is the path traced by the point on the line when rolling on a circle. It is a useful feature for cylindrical involute gears.
The helix angle is also important to the helical gear. It allows for greater contact capacity and increases the bending capacity of the gear. It must be included in specifications for helical teeth. The angle must be measurable and include the (+-) sign.
The bending strength of a tooth depends on the shape of the root. A large undercut reduces the strength of the tooth.
Contact ratios
Whether a helical gearbox is dynamic or steady-state, the contact ratio is a key factor. The total contact ratio defines the average number of teeth in contact in the plane of action. It is calculated by multiplying the transverse contact ratio with the overlap ratio. The overlap ratio is always non-zero.
The total contact ratio must be 1.0 or greater for a constant speed rotation on the driven side. Gears with a low total contact ratio are known to slow down rotation of the driven gear. The total contact ratio is influenced by the length of the contact line. A high contact ratio is a good choice for dynamic loading.
A low contact ratio results in a greater amount of profile shift and a larger amount of noise. If the contact ratio is too high, it may cause excessive EAP sliding velocity and cause scuffing. In addition, an uneven load share results in amplitude modulated vibrations.
A helical gear is a pair of slim spur gears. The gears are layered in a plane that runs parallel to the face width of the gear teeth. Each gear tooth makes contact with the flank of the next gear tooth. The helical gear tooth flank is a 3-dimensional surface that is a tangent to the base circles of the gears.
The tooth shape of the helical gear tooth is also a key factor in the contact ratio. The tooth form is designed to be in relation to the work piece, tooling, dedendum coefficients, tooth forces, and tooth bending stiffness. A gear tooth form must also relate to tooth surface kinematics and microgeometry modifications.
The active profile is a region of the involute profile between the start and end points. A tooth profile that satisfies the basic law of gear-tooth action is often called a conjugate profile.
editor by czh 2023-01-06
China F Series Parallel Solid Shaft Helical Gearbox with Motor helical bevel gearbox manufacturers
Solution Description
Solution Description
Item Description
-F Series Parallel Shaft Helical gearbox
Solution Functions
1. Modular design, compact construction. Further-slim parallel shaft helical gearmotors are the best remedy when place is limited
2. F series parallel shaft helical gearmotors are generally utilised in conveyors and resources processing applications
three. Multi-stage (2 or 3 phases) equipment units for lower output speed
four. Hollow output shaft with keyed link, shrink disk, splined hollow shaft, or torque arm
five. Can be mixed with other kinds of gearboxes (Such as R Series, UDL Sequence)
six. Optional mounting choices (foot-mounted, flange-mounted, shaft-mounted)
Solution Parameters
| Models | Output Shaft Dia. | Enter Shaft Dia. | Energy(kW) | Ratio | Max. Torque(Nm) | |
| Reliable Shaft | Hollow Shaft | |||||
| F38 | 25mm | 30mm | 16mm | .eighteen~3. | three.81~128.fifty one | two hundred |
| F48 | 30mm | 35mm | 16mm | .18~3. | 5.06~189.39 | 400 |
| F58 | 35mm | 40mm | 19mm | .eighteen~5.five | five.18~199.70 | 600 |
| F68 | 40mm | 40mm | 19mm | .eighteen~5.five | 4.21~228.ninety nine | 820 |
| F78 | 50mm | 50mm | 24mm | .37~eleven | 4.thirty~281.71 | 1500 |
| F88 | 60mm | 60mm | 28mm | .75~22 | 4.20~271.ninety two | 3000 |
| F98 | 70mm | 70mm | 38mm | one.1~30 | four.sixty eight~276.64 | 4300 |
| F108 | 90mm | 90mm | 42mm | 2.2~forty five | 6.twenty~255.25 | 7840 |
| F128 | 110mm | 100mm | 55mm | seven.5~90 | 4.63~172.33 | 12000 |
| F158 | 120mm | 120mm | 70mm | 11~two hundred | twelve.07~270.18 | 18000 |
Resources Info Sheet
| Housing substance |
Grey Forged iron |
| Housing hardness |
HBS163~255 |
| Equipment substance |
20CrMnTi alloy steel |
| Floor hardness of gears |
HRC58°~sixty two ° |
| Gear core hardness |
HRC33~48 |
| Input / Output shaft material |
40Cr alloy metal |
| Enter / Output shaft hardness |
HRC32~36 |
| Machining precision of gears |
precise grinding, 6~5 Grade |
| Lubricating oil |
GB L-CKC220-460, Shell Omala220-460 |
| Heat remedy |
tempering, cementiting, quenching, normalizing, and many others. |
| Efficiency |
94%~ninety six% (depends on the transmission stage) |
| Sounds (MAX) |
60~68dB |
| Temp. rise (MAX) |
40°C |
| Temp. rise (Oil)(MAX) |
50°C |
| Vibration |
≤20µm |
| Backlash |
≤20Arcmin |
| Brand of bearings |
China prime model bearing, HRB/LYC/ZWZ/C&U. Or other brand names asked for, SKF, FAG, INA, NSK. |
| Brand name of oil seal |
NAK — ZheJiang or other brands requested |
Detailed Pictures
Our procedure of manufacturing
Our solution line
Organization Profile
Firm Profile
Bode was founded in 2007, which is situated in HangZhou metropolis, ZHangZhoug province. As 1 specialist producer and exporter, we have more than 17 years’ knowledge in R & D of worm reducer, gear reducer, gearbox , AC motor and relative spare areas. We have manufacturing unit with superior manufacturing and examination gear, the strong advancement of staff and generating capability offer you our customers with high good quality products. Our items extensively served to various industries of Metallurgy, Substances, lifting, mining, Petroleum, textile, medicine, picket and many others. Primary marketplaces: China, Africa, Australia, Vietnam, Turkey, Japan, Korea, Philippines… Welcome to question us any concerns, great supply usually for you for lengthy phrase enterprise.
FAQ
Q1: Are you buying and selling company or manufacturer?
A: We are factory.
Q2: What types of gearbox can you create for us?
A: Major products of our organization: R, S, K, F series helical-tooth reducer, RV series worm gear reducer,H Series Parallel Shaft Helical Reduction Equipment Box
Q3: Can you make as for each personalized drawing?
A: Of course, we supply custom-made service for buyers.
This autumn: Can we get 1 computer of each product for quality tests?
A: Of course, we are glad to take trial order for top quality tests.
Q5: What information shall we give before placing a obtain get?
A: a) Type of the gearbox, ratio, input and output variety, input flange, mounting position, and motor informationetc.
b) Housing color.
c) Obtain quantity.
d) Other specific specifications.
Q6: How long is your shipping and delivery time?
A: Usually it is 5-10 days if the products are in inventory. or it is fifteen-twenty times if the merchandise are not in stock.
Q7: What is your phrases of payment ?
A: 30% Advance payment by T/T after signing the deal.70% just before shipping and delivery
Pricey consumers, If you are fascinated in our item, welcome to get in touch with with us.
Our team will do our ideal to meet your want 🙂
|
US $50 / Piece | |
1 Piece (Min. Order) |
###
| Application: | Machinery, Marine, Agricultural Machinery |
|---|---|
| Function: | Distribution Power, Change Drive Torque, Speed Changing, Speed Reduction |
| Layout: | Coaxial |
| Hardness: | Hardened Tooth Surface |
| Installation: | Vertical Type |
| Step: | Single-Step |
###
| Samples: |
US$ 50/Piece
1 Piece(Min.Order) |
|---|
###
| Customization: |
Available
|
|---|
###
| Models | Output Shaft Dia. | Input Shaft Dia. | Power(kW) | Ratio | Max. Torque(Nm) | |
| Solid Shaft | Hollow Shaft | |||||
| F38 | 25mm | 30mm | 16mm | 0.18~3.0 | 3.81~128.51 | 200 |
| F48 | 30mm | 35mm | 16mm | 0.18~3.0 | 5.06~189.39 | 400 |
| F58 | 35mm | 40mm | 19mm | 0.18~5.5 | 5.18~199.70 | 600 |
| F68 | 40mm | 40mm | 19mm | 0.18~5.5 | 4.21~228.99 | 820 |
| F78 | 50mm | 50mm | 24mm | 0.37~11 | 4.30~281.71 | 1500 |
| F88 | 60mm | 60mm | 28mm | 0.75~22 | 4.20~271.92 | 3000 |
| F98 | 70mm | 70mm | 38mm | 1.1~30 | 4.68~276.64 | 4300 |
| F108 | 90mm | 90mm | 42mm | 2.2~45 | 6.20~255.25 | 7840 |
| F128 | 110mm | 100mm | 55mm | 7.5~90 | 4.63~172.33 | 12000 |
| F158 | 120mm | 120mm | 70mm | 11~200 | 12.07~270.18 | 18000 |
###
| Housing material |
Grey Cast iron
|
| Housing hardness |
HBS163~255
|
| Gear material |
20CrMnTi alloy steel
|
| Surface hardness of gears |
HRC58°~62 °
|
| Gear core hardness |
HRC33~48
|
| Input / Output shaft material |
40Cr alloy steel
|
| Input / Output shaft hardness |
HRC32~36
|
| Machining precision of gears |
accurate grinding, 6~5 Grade
|
| Lubricating oil |
GB L-CKC220-460, Shell Omala220-460
|
| Heat treatment |
tempering, cementiting, quenching, normalizing, etc.
|
| Efficiency |
94%~96% (depends on the transmission stage)
|
| Noise (MAX) |
60~68dB
|
| Temp. rise (MAX) |
40°C
|
| Temp. rise (Oil)(MAX) |
50°C
|
| Vibration |
≤20µm
|
| Backlash |
≤20Arcmin
|
| Brand of bearings |
China top brand bearing, HRB/LYC/ZWZ/C&U. Or other brands requested, SKF, FAG, INA, NSK.
|
| Brand of oil seal |
NAK — Taiwan or other brands requested
|
|
US $50 / Piece | |
1 Piece (Min. Order) |
###
| Application: | Machinery, Marine, Agricultural Machinery |
|---|---|
| Function: | Distribution Power, Change Drive Torque, Speed Changing, Speed Reduction |
| Layout: | Coaxial |
| Hardness: | Hardened Tooth Surface |
| Installation: | Vertical Type |
| Step: | Single-Step |
###
| Samples: |
US$ 50/Piece
1 Piece(Min.Order) |
|---|
###
| Customization: |
Available
|
|---|
###
| Models | Output Shaft Dia. | Input Shaft Dia. | Power(kW) | Ratio | Max. Torque(Nm) | |
| Solid Shaft | Hollow Shaft | |||||
| F38 | 25mm | 30mm | 16mm | 0.18~3.0 | 3.81~128.51 | 200 |
| F48 | 30mm | 35mm | 16mm | 0.18~3.0 | 5.06~189.39 | 400 |
| F58 | 35mm | 40mm | 19mm | 0.18~5.5 | 5.18~199.70 | 600 |
| F68 | 40mm | 40mm | 19mm | 0.18~5.5 | 4.21~228.99 | 820 |
| F78 | 50mm | 50mm | 24mm | 0.37~11 | 4.30~281.71 | 1500 |
| F88 | 60mm | 60mm | 28mm | 0.75~22 | 4.20~271.92 | 3000 |
| F98 | 70mm | 70mm | 38mm | 1.1~30 | 4.68~276.64 | 4300 |
| F108 | 90mm | 90mm | 42mm | 2.2~45 | 6.20~255.25 | 7840 |
| F128 | 110mm | 100mm | 55mm | 7.5~90 | 4.63~172.33 | 12000 |
| F158 | 120mm | 120mm | 70mm | 11~200 | 12.07~270.18 | 18000 |
###
| Housing material |
Grey Cast iron
|
| Housing hardness |
HBS163~255
|
| Gear material |
20CrMnTi alloy steel
|
| Surface hardness of gears |
HRC58°~62 °
|
| Gear core hardness |
HRC33~48
|
| Input / Output shaft material |
40Cr alloy steel
|
| Input / Output shaft hardness |
HRC32~36
|
| Machining precision of gears |
accurate grinding, 6~5 Grade
|
| Lubricating oil |
GB L-CKC220-460, Shell Omala220-460
|
| Heat treatment |
tempering, cementiting, quenching, normalizing, etc.
|
| Efficiency |
94%~96% (depends on the transmission stage)
|
| Noise (MAX) |
60~68dB
|
| Temp. rise (MAX) |
40°C
|
| Temp. rise (Oil)(MAX) |
50°C
|
| Vibration |
≤20µm
|
| Backlash |
≤20Arcmin
|
| Brand of bearings |
China top brand bearing, HRB/LYC/ZWZ/C&U. Or other brands requested, SKF, FAG, INA, NSK.
|
| Brand of oil seal |
NAK — Taiwan or other brands requested
|
Helical Gearbox
Using a helical gearbox can greatly improve the accuracy of a machine and reduce the effects of vibration and shaft axis impact. A gearbox is a circular machine part that has teeth that mesh with other teeth. The teeth are cut or inserted and are designed to transmit speed and torque.
Sliding
Among the many types of gearboxes, the helical gearbox is the most commonly used gearbox. This is because the helical gearbox has a sliding contact. The contact between two gear teeth begins at the beginning of one tooth and progresses to line contact as the gear rotates.
Helical gears are cylindrical gears with teeth cut at an angle to the axis. This angle enables helical gears to capture the velocity reversal at the pitch line due to the sliding friction. This leads to a much smoother motion and less wear. Moreover, the helical gearbox is more durable and quieter than other gearboxes.
Helical gears are divided into two categories. The first group comprises of crossed-axis helical gears, commonly used in automobile engine distributor/oil pump shafts. The second group comprises of zero-helix-angle gears, which do not produce axial forces. However, they do create heat, which causes loss of efficiency.
The helical gearbox configuration is often confounded, which results in higher working costs. In addition, the helical gearbox configuration does not have the same torque/$ ratio as zero-helix angle planetary gears.
When designing gears, it is important to consider the effects of gear sliding. Sliding can lead to friction, which can cause loss of power transmission. It also leads to uneven load distribution, which decreases the loadability of the helical planetary gearbox.
In addition, the mesh stiffness of helical gears is commonly ignored by researchers. An analytical model for the mesh stiffness of helical gears has been proposed.
Axial thrust forces
Several options are available for axial thrust forces in helical gearboxes. The most obvious is to use a double helical gear to offset the force component. Another option is to use a thrust bearing with a lower load carrying capacity. This becomes a sacrificial component.
In order to transmit a force, it must be distributed along the contact line. This force is the sum of tangential, radial and axial force components. All these components must be transferred from the source to the output. This is a complex process that involves the use of gears.
The axial force component must be transferred through the gears. The resultant force is then divided into orthogonal components and divided into the thrust directions. The radial force component is from the contact point to the driven gear center.
The axial force component is also determined by the size of the gear’s pitch diameter. A larger pitch diameter results in a greater bearing moment. Similarly, a larger gear ratio will produce a higher torque transmission.
It should be noted that the axial force component is only a small part of the total force. The normal force is distributed along the contact line.
The double helical gear is also not a perfect duplicate of the herringbone gear. It has two equal halves. It is used interchangeably with the herringbone gear. It also has the same helix angle.
Reduced impact on the shaft axis
Increasing the helix angle of a gear pair will reduce resonance effects on the shaft axis of a helical gearbox. However, this will not reduce the overall vibration in the gearbox. In fact, it will increase the vibration. This can lead to serious fatigue faults in the drive train.
This is because the helix angle has an effect on the contact line between two teeth. As the helix angle increases, the length of the contact line decreases. In addition, it has an effect on the normal force and curvature radii of the teeth. The pressure angle also affects the curvature radii.
Helical gears have several advantages over spur gears. These advantages include: lower vibration, NVH (noise, vibration and harshness) characteristics, and smooth operation under heavy loads. They also have better torque capability. However, they produce higher friction. They also require unique approaches to control their thrust forces.
The first step in reducing resonance effects is to regulate the meshing frequency of the helical gear stage. This can be done by varying the shift factors in the gear. If the shift factors are too large, then the gear will experience resonance effects. The helix angle is also affected by the gear’s shift factors. It is therefore important to control the gear’s geometry in order to reduce the resonance effects.
Next, the effects of the web structure and rim thickness on the root stress of the gear are examined. These are measured by strain gage. The results indicate that the maximum root stress is obtained when the worst meshing position is reached.
Quieter operation
Compared to spur gears, helical gears are much quieter in operation. This is due to their larger teeth. Aside from this, they have a higher load-carrying capacity. They also run smoother and have a higher speed capability. Helical gears are also a good substitute for spur gears.
The most significant parameter relating to noise reduction is the gear contact ratio. It ranges from below 1 to more than 10 and is determined by the number of teeth intersecting a parallel shaft line at the pith circle. It is also a good indicator of the level of noise reduction that helical gears provide.
In addition, helical gears have a lower impulse flexure than spur gears. This is because the contact point slides along the helical surface of each tooth. This also adds internal damping to the gear system.
While helical gears are less noisy than spur gears, they do have a high level of wear and tear. This can affect the performance of the gear. However, it is possible to improve the smoothness of the tooth surface by grinding. In addition, running the gears in oil can also help improve the smoothness of the tooth surface.
There are many industries that use helical gears. For example, the automotive industry uses them in their transmissions. They also are used in the agricultural industry. They are often used in heavy trucks.
Helical gears are also known to generate less heat and are quieter than other gears. They can also deliver parallel power transfers between parallel or non-parallel shafts.
Improved accuracy
Increasing the accuracy of a helical gearbox is the key to its operation and reliability. The accuracy of the gearbox is dependent on several features. Among the most important are the profile and lead. Moreover, the power requirements of a gear drive should be taken into consideration.
The profile is the most sensitive feature of a helical gear. If the profile is not symmetric, the gear will run with a noisy spur gear. In addition, the profile is also the most sensitive to lead.
A helical gearbox plays a key role in the power transmission of industrial applications. However, the heavy duty operating conditions make it susceptible to a variety of faults.
A helical gearbox’s performance depends on the accuracy of the individual gears. This is accomplished by minimizing the backlash. A common way to reduce backlash is to approach all target positions from a common direction. This approach also reduces transmission noise.
The accuracy of a helical gearbox can be improved by using a flexible electronic gearbox. This can reduce the degree of twist. Moreover, it can increase the accuracy of gear machining.
A helical gearbox with an electronic gearbox can increase the accuracy of twist compensation. It can also improve the linkage between B-axis, C-axis, and Z-axis. Moreover, the electronic gearbox will ensure the linkage relationship between Y-axis, Z-axis, and C-axis.
The accuracy of a helical Gearbox can be improved by calculating the position error of the gear train. Pitch deviation and helix angle deviation are two types of position error.
Reduced vibration
Using helical gearboxes can reduce vibration and noise. These gears are used in a variety of applications, including automotive transmissions. Moreover, these gears are quiet enough to operate in noise-sensitive applications.
Using CZPT software, three different gearbox housing designs are compared. The external dimensions and mass of each design are kept constant, but different quantities of longitudinal and transverse stiffeners are employed. The resulting models are then compared to experimental results. In addition, the free vibration response of these models is analyzed. The results are shown in Fig. 5.
In terms of noise reduction, the cellular model produces the lowest sound pressure level. However, the cross model produces the higher sound level. The cellular model also produces better peak to peak results.
The input-stage gear pair is the power source of the output-stage gear pair. The output-stage gear pair’s vibration is also studied. This includes a phase diagram and a frequency-domain diagram. The influence of the driving torque and the pinion’s velocity on the vibration is studied in a numerical manner. The time evolution of the normal force and the lubricant stiffness is also studied.
The input-stage pinion modification reduces the input-stage gear pair’s vibration. This reduction is achieved by adding dual bearing support to the input shaft.
editor by czh 2022-12-22