Product Description
Product Description
The NBR115 series planetary gearboxes are designed and machined as a single unit with special tapered roller bearings to provide high radial load, high torque, ultra-precision, and small size. The NBR115 series uses in highly rigid industries such as fiber optic laser equipment, floor track equipment, robot seventh axis, Parallel robots (spider hand) machine tools, and rotating arms.
Product Name: High Precision Planetary Reducer
Product Series: NBA115 Series
Product features: high torque, high load, ultra-precision, small size
Product Description:
Integrated design concept with high-strength bearings ensure the product itself is durable and efficient
A variety of output ideas such as shaft output, flange and gear are available.
1 arc minute ≤ backlash ≤ 3 arc minutes
Reduction ratios ranging from 3 to 100
Frame design: increases torque and optimizes power transmission
Optimised selection of oil seals: reduces friction and laminate transmission efficiency
Protection class IP65
Warranty: 2 years
Our Advantages
High torque
High load
ultra-precision
Small size
Detailed Photos
Product Parameters
| Segment number | Double segment | ||||||||||||||||
| Ratio | i | 25 | 30 | 35 | 40 | 45 | 50 | 60 | 70 | 80 | 90 | 100 | 120 | 140 | 160 | 180 | 200 |
| Rated output torque | Nm | 300 | 290 | 280 | 240 | 210 | 210 | 290 | 280 | 240 | 210 | 210 | 290 | 280 | 240 | 210 | 210 |
| Emergency stop torque | Nm | Three times of Maximum Output Torque | |||||||||||||||
| Rated input speed | Rpm | 4000 | |||||||||||||||
| Max input speed | Rpm | 8000 | |||||||||||||||
| Ultraprecise backlash | arcmin | ≤4 | |||||||||||||||
| Precision backlash | arcmin | ≤7 | |||||||||||||||
| Standard backlash | arcmin | ≤9 | |||||||||||||||
| Torsional rigidity | Nm/arcmin | 25 | |||||||||||||||
| Max.bending moment | Nm | 6700 | |||||||||||||||
| Max.axial force | N | 3350 | |||||||||||||||
| Service life | hr | 20000(10000 under continuous operation) | |||||||||||||||
| Efficiency | % | ≥92% | |||||||||||||||
| Weight | kg | 14.2 | |||||||||||||||
| Operating Temperature | ºC | -10ºC~+90ºC | |||||||||||||||
| Lubrication | Synthetic grease | ||||||||||||||||
| Protection class | IP64 | ||||||||||||||||
| Mounting Position | All directions | ||||||||||||||||
| Noise level(N1=3000rpm,non-loaded) | dB(A) | ≤68 | |||||||||||||||
| Rotary inertia | Kg·cm² | 2.25 | 1.87 | ||||||||||||||
Applicable Industries
Packaging Machinery Mechanical Hand Textile Machinery
Non Standard automation Machine Tool Printing Equipment
Certifications
Company Profile
DESBOER (HangZhou) Transmission Technology Co., Ltd. is a subsidiary of DESBOER (China), which is committed to the design, development, customized production and sales of high precision planetary reducer as 1 of the technology company. Our company has over 10 years of design, production and sales experience, the main products are the high precision planetary reducer, gear, rack, etc., with high quality, short delivery period, high cost performance and other advantages to better serve the demand of global customers. It is worth noting that we remove the intermediate link sale from the factory directly to customers, so that you can get the most ideal price and also get our best quality service simultaneously.
About Research
In order to strengthen the advantages of products in the international market, the head company in Kyoto, Japan to established KABUSHIKIKAISYA KYOEKI, mainly engaged in the development of DESBOER high precision planetary reducer, high precision of transmission components such as the development work, to provide the most advanced design technology and the most high-quality products for the international market.
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| Application: | Motor, Machinery, Marine, Agricultural Machinery, CNC Machine |
|---|---|
| Function: | Change Drive Torque, Speed Changing, Speed Reduction |
| Layout: | Plantery Type |
| Hardness: | Hardened Tooth Surface |
| Installation: | All Directions |
| Step: | Double-Step |
| Customization: |
Available
| Customized Request |
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Comparison of Helical Gearboxes and Bevel Gearboxes
Helical gearboxes and bevel gearboxes are both widely used for power transmission in various industrial applications. Here’s a comparison of their performance:
- Gear Meshing: Helical gearboxes use helical gears with inclined teeth that gradually engage, resulting in smoother and quieter operation compared to the more abrupt engagement of straight-cut bevel gears.
- Efficiency: Helical gearboxes generally offer higher efficiency due to their helical gear design, which distributes loads evenly across the teeth. Bevel gearboxes can have slightly lower efficiency due to the sliding action of gear teeth during engagement.
- Load Capacity: Helical gearboxes can handle higher loads and torque due to the larger contact area of the gear teeth. Bevel gearboxes are suitable for moderate loads and applications where the direction of power transmission needs to be changed.
- Space Efficiency: Bevel gearboxes are often more compact and suitable for applications where space is limited and a change in direction is required. Helical gearboxes may require more space due to the parallel shaft arrangement.
- Noise and Vibration: Helical gearboxes generate less noise and vibration compared to straight-cut bevel gearboxes. Bevel gearboxes can be noisier, especially at higher speeds.
- Application: Helical gearboxes are commonly used in applications requiring smooth and efficient power transmission, such as conveyors, pumps, and mixers. Bevel gearboxes are preferred for applications where changes in direction are necessary, such as in automotive differentials and printing presses.
Ultimately, the choice between helical and bevel gearboxes depends on the specific requirements of the application, including load capacity, space constraints, efficiency goals, and the need for directional changes in power transmission.
Troubleshooting Common Issues in Helical Gear Systems
Troubleshooting helical gear systems involves identifying and addressing common issues that can affect their performance. Here’s a step-by-step process:
- Visual Inspection: Begin by visually inspecting the gearbox for any signs of wear, damage, or misalignment. Look for worn or chipped gear teeth, oil leakage, and unusual noise.
- Noise Analysis: If noise is present, analyze its type and frequency. Whining or grinding noises could indicate misalignment or damaged gears, while clicking or knocking sounds might point to loose components.
- Lubrication Check: Ensure that the gearbox is properly lubricated with the recommended type and quantity of lubricant. Insufficient lubrication can lead to increased friction and wear.
- Alignment Check: Check the alignment of the gears and shafts. Misalignment can result in uneven wear, noise, and reduced efficiency. Realign components if necessary.
- Gear Inspection: Inspect gear teeth for signs of pitting, scoring, or wear. Replace any damaged gears to prevent further issues.
- Bearing Examination: Check the condition of bearings that support shafts and gears. Worn or damaged bearings can lead to increased vibration and noise.
- Tightening and Fastening: Ensure that all bolts, fasteners, and connections are properly tightened. Loose components can cause vibrations and noise.
- Load Analysis: Evaluate the load conditions and operating parameters of the gearbox. Ensure that the gearbox is not subjected to loads beyond its design capacity.
- Temperature Monitoring: Monitor the operating temperature of the gearbox. Excessive heat can indicate problems such as inadequate lubrication or overloading.
- Consulting Experts: If issues persist or if you’re unsure about the diagnosis and solution, consult gearbox experts or manufacturers for guidance.
By following this troubleshooting process, you can identify and resolve common issues in helical gear systems, ensuring optimal performance and longevity.
Advantages of Helical Gearboxes in Industrial Applications
Helical gearboxes offer several advantages that make them well-suited for a wide range of industrial applications. Here are some of the key advantages:
- Smooth and Quiet Operation: The helical design of the gears results in gradual tooth engagement, reducing noise and vibration during operation. This makes helical gearboxes ideal for applications where noise reduction is important.
- High Efficiency: Helical gears provide a larger contact area compared to straight-cut gears, leading to improved power transmission efficiency. The gradual engagement of teeth also reduces energy losses due to friction.
- Higher Load Capacity: The helical angle allows for multiple teeth to be engaged simultaneously, distributing the load across a larger area. This results in higher load-carrying capacity and increased durability of the gearbox.
- Compact Design: Helical gearboxes can achieve high gear ratios with fewer gear stages, leading to a more compact overall design. This is advantageous in applications where space is limited.
- Wide Range of Ratios: Helical gearboxes can achieve a wide range of gear ratios, making them versatile for various speed and torque requirements.
- Less Backlash: The gradual tooth engagement of helical gears results in reduced backlash, which is the play between gear teeth. This leads to improved accuracy and positioning in applications that require precise motion control.
- Heat Dissipation: The helical design allows for better heat dissipation due to the continuous contact between gear teeth. This is beneficial in high-speed applications where heat generation can be a concern.
- Highly Customizable: Helical gearboxes can be customized to meet specific application requirements, including input and output configurations, gear ratios, and mounting options.
Overall, the advantages of helical gearboxes make them a popular choice in industries such as manufacturing, automation, robotics, material handling, and more.
editor by CX 2024-03-28
China High Precision Servo Reducer, High Precision Servo Gearbox, High Precisions Helical Planetary Gear Box, High Precision Flange Output Planetary Gearbox with Hot selling
Item Description
Item Functions
* Compact structure, integration of alloy aluminum body to guarantee the optimum rigidity and corrosion resistance, and effortless to assemble with multiple precision machined surface.
* The use of best-level spiral bevel gear, with optimization design and style, the contact tooth floor of uniform load, allowable hith torque output.
* Gear is manufactured of high strength alloy metal carburizing, grinding precision.
* The layout of several alloy steel output and enter shaft applies to various industrial specifications.
* The simplified structure design with high torque and minimal backlash applies to apps of precision servo.
* Effortless mount, with maintenance-free of charge, no require to replace the grease and lengthy service daily life.
* Software in Precision Rotary Axis Drives, Travel Gantry and Columns, Materials Dealing with Axis Drives, Industrial Areas in Automation, Aerospace, and Device Device and Robotics.
Merchandise Description
Shaft Input Configuration – Higher Precision Spiral Bevel Gearboxes
* JAC-C Series: Shaft Input Configuration, and Hollow Output Shaft with Two Shrinks Discs.
* Designs: JAC065C, JAC075C, JAC090C, JAC0110C, JAC0140C, JAC0170C, JAC210C.
* JAC-H Series: Shaft Input Configuration, and Hollow Output Shaft with Essential Way.
* Models: JAC065H, JAC075H, JAC090H, JAC0110H, JAC0140H, JAC0170H, JAC210H.
* JAC-L Collection: Shaft Input Configuration, and Solid Output Shaft.
* Models: JAC065L, JAC075L, JAC090L, JAC0110L, JAC0140L, JAC0170L, JAC210L.
* Gear Ratios: Spiral bevel equipment set of large precision grinding can accomplish from 1:1 to 6:1 as regular.
* Phase: 1 stage (1:1 to 6:1).
* Rated Output Torque (N.m): From 12N.m to 1300N.m.
* Fault Stop Torque = 2 Times of Rated Output Torque.
* Max. Enter Velocity (rpm): From 2500RPM to 3500RPM.
* Rated Input Speed (rpm): From 1500RPM to 2500RPM.
* Low Backlash (arcmin): From 6 arcmin to 8 arcmin.
* Max. Radial Pressure (N) Of Output Shaft: From 900N to 11500N.
* Max. Axial Power (N) Of Output Shaft: From 450N to 5750N.
* Max. Radial Drive (N) Of Input Shaft: From 700N to 7800N.
* Max. Axial Pressure (N) Of Input Shaft: From 350N to 3900N.
* Low Sounds Amount (dB): From 71dB to 82dB.
* Higher Effectiveness (%): ninety eight%.
* Average Daily life Span (hr): 20000 hours.
* Lubrication: Synthetic lubrication grease
* Mass Times of Inertia (kg/cm2): From .43 kg/cm2 to 195.4 kg/cm2.
Motor Flange Enter Configuration – Higher Precision Spiral Bevel Gearboxes
* JAC-FC Sequence: Motor Flange Enter Configuration, and Hollow Output Shaft with Two Shrinks Discs.
* Types: JAC065FC, JAC075FC, JAC090FC, JAC0110FC, JAC0140FC, JAC0170FC, JAC210FC.
* JAC-FH Series: Motor Flange Enter Configuration, and Hollow Output Shaft with Key Way.
* Designs: JAC065FH, JAC075FH, JAC090FH, JAC0110FH, JAC0140FH, JAC0170FH, JAC210FH.
* JAC-FL Sequence: Motor Flange Enter Configuration, and Sound Output Shaft.
* Versions: JAC065FL, JAC075FL, JAC090FL, JAC0110FL, JAC0140FL, JAC0170FL, JAC210FL.
* Gear Ratios: Spiral bevel gear established of large precision grinding can obtain from 1:1 to 100:1 as normal, personalized-manufactured max. 400:1 ratio.
* Phase: 1 stage (1:1 to 6:1), 2 stage (8:1 to thirty:1), 3 stage (32:1 to 100:1).
* Rated Output Torque (N.m): From 12N.m to 1300N.m.
* Fault End Torque = 2 Instances of Rated Output Torque.
* Max. Input Speed (rpm): From 2000RPM to 5000RPM.
* Rated Input Speed (rpm): From 1500RPM to 2500RPM.
* Low Backlash (arcmin): From 6 arcmin to 15 arcmin.
* Max. Radial Pressure (N) Of Output Shaft: From 900N to 11500N.
* Max. Axial Pressure (N) Of Output Shaft: From 450N to 5750N.
* Low Noise Stage (dB): From 71dB to 82dB.
* Higher Efficiency (%): From 94% to ninety eight%.
* Average Life Span (hr): 20000 hrs.
* Mass Times of Inertia (kg/cm2): From .fifteen kg/cm2 to 195.4 kg/cm2.
Product Parameters
Shaft Input Configuration – Large Precision Spiral Bevel Gearboxes
Motor Flange Enter Configuration – Higher Precision Spiral Bevel Gearboxes
Product Dimensions
Shaft Input Configuration – Higher Precision Spiral Bevel Gearboxes
* JAC-C Sequence: Shaft Input Configuration, and Hollow Output Shaft with Two Shrinks Discs.
* Models: JAC065C, JAC075C, JAC090C, JAC0110C, JAC0140C, JAC0170C, JAC210C.
Shaft Enter Configuration – Higher Precision Spiral Bevel Gearboxes
* JAC-H Series: Shaft Enter Configuration, and Hollow Output Shaft with Important Way.
* Designs: JAC065H, JAC075H, JAC090H, JAC0110H, JAC0140H, JAC0170H, JAC210H.
Shaft Input Configuration – High Precision Spiral Bevel Gearboxes
* JAC-L Series: Shaft Input Configuration, and Solid Output Shaft.
* Models: JAC065L, JAC075L, JAC090L, JAC0110L, JAC0140L, JAC0170L, JAC210L.
Motor Flange Input Configuration – Large Precision Spiral Bevel Gearboxes
* JAC-FC Collection: Motor Flange Input Configuration, and Hollow Output Shaft with Two Shrinks Discs.
* Models: JAC065FC, JAC075FC, JAC090FC, JAC0110FC, JAC0140FC, JAC0170FC, JAC210FC.
Motor Flange Enter Configuration – Higher Precision Spiral Bevel Gearboxes
* JAC-FH Series: Motor Flange Enter Configuration, and Hollow Output Shaft with Crucial Way.
* Versions: JAC065FH, JAC075FH, JAC090FH, JAC0110FH, JAC0140FH, JAC0170FH, JAC210FH.
Motor Flange Input Configuration – Higher Precision Spiral Bevel Gearboxes
* JAC-FL Collection: Motor Flange Enter Configuration, and Solid Output Shaft.
* Types: JAC065FL, JAC075FL, JAC090FL, JAC0110FL, JAC0140FL, JAC0170FL, JAC210FL.
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US $99-999 / Piece | |
1 Piece (Min. Order) |
###
| 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: | Right-Angle, 90 Degree |
| Hardness: | Hardened Tooth Surface |
| Installation: | Horizontal Type |
| Step: | 1-Stage, 2-Stage, 3-Stage |
###
| Customization: |
Available
|
|---|
|
US $99-999 / Piece | |
1 Piece (Min. Order) |
###
| 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: | Right-Angle, 90 Degree |
| Hardness: | Hardened Tooth Surface |
| Installation: | Horizontal Type |
| Step: | 1-Stage, 2-Stage, 3-Stage |
###
| Customization: |
Available
|
|---|
Helical Gearbox
Generally, a helical gearbox consists of two gears. The two gears have cut teeth and are inserted into one another. These two gears work together to transmit torque and speed. This type of gearbox is used in a wide variety of applications.
Working principle
Besides being cheaper to make, helical gears have several advantages over straight-cut spur gears. Firstly, they offer a smoother operation, less vibration, and lower noise levels. They also transmit larger loads than spur gears. These gears are used in a variety of industries, such as food processing, plastic industries, and oil industries.
Another important feature of helical gears is the smooth and gradual engagement of teeth. This helps them function more smoothly, especially when working under heavy loads. This process reduces shock and backlash, and also reduces wear.
In addition to this, the helix angle is a variable that can be adjusted to suit the application. The angle is usually either left or right, and can vary based on the view.
Helical gears are usually used in enclosed gear drives, such as conveyors, blowers, and elevators. They offer a smoother operation, which makes them ideal for applications that require quiet operation. However, helical gears are less efficient at transmitting power than spur gears.
The relative contact stress (RCS) calculated for a helical gear is similar to that of a spur gear. However, the volume Vi, which is a helix-dependent quantity, is different. This volume is defined as the total volume of the helical pocket, calculated by integrating along the face width. The volume of a generic pocket is larger than that of a helical pocket without a helix.
In addition, the contact ratio is reduced. This is due to the fact that two teeth are not parallel to each other. A thick oil film prevents the teeth from making contact. This film also cools the gear tooth surfaces.
The service factor is a number that takes into account the conditions under which a gear is used. It is usually a ratio between the maximum torque and the torque produced.
Efficiency
During a recent gearbox measurement campaign, 13 commercial gearboxes were extensively tested. Efficiency was measured at nominal torque and power. The resulting efficiency maps presented in this paper show that the efficiency of each gearbox is fairly similar.
The efficiency of a gearbox depends on the gears’ teeth and the ratio between them. The lower the ratio, the higher the efficiency.
Efficiency is also affected by the load torque. The higher the load torque, the lower the efficiency. This is especially true for gearboxes with high ratios.
The power loss is also affected by the contact and overlap ratios. For gearboxes with high ratios, the difference between the efficiency of the catalog and model-based efficiency is greater than for low-ratio gearboxes. Fortunately, improvements in lubrication are closing this gap.
The helical gearbox is the most effective gearbox in the industry. It transfers motion between parallel configurations and has less noise than spur gears. These gears engage gently and smoothly, so they are less prone to wear and tear. They also allow for greater power carrying capacity.
Although helical gears are effective, they are more expensive than traditional gears. However, the cost savings can be significant over time. It is important to consider the advantages of a helical gearbox before choosing a gearbox for your application.
When comparing the efficiency of a helical gearbox to that of a worm gearbox, the worm gearbox is more efficient. However, the difference in efficiency is not as great as many other gearboxes.
The efficiency of a helical gearbox is also affected by the speed of the gears. The gearbox must have adequate lubrication for bearings. It is also important to consider the space requirements in the drive line.
Applications
helical gearbox applications are widespread and they are used in many industries. Some of the applications include the printing industry, the rubber industry, the plastics industry, the cement industry, the earth-moving industry, and the chemical industry.
helical gearboxes are also used for conveyors and elevators. They are very durable and they can carry larger loads. They are also quieter than straight cuts. They are also used in many automotive transmissions.
helical gearboxes transmit power between two parallel shafts. They are a good substitute for spur gears. They are compact and they reduce vibration and noise. They are also very durable and they can work in non-parallel shafts.
The most common application is in the automotive industry. Helical gearboxes are also used in other industries. They are very useful in elevators, conveyors, and other heavy industrial settings. They also provide a high level of speed reduction and they are commonly used in automation control systems. They are also used in the mining industry and the cement industry.
helical gearboxes can be fabricated with various modifications. This is important because some industries may require different gearboxes.
Helical gears have a higher number of teeth. This leads to less wear and tear. They are also less noisy than spur gears. Their ability to generate a large thrust force is what makes them ideal for high-speed applications. They are also able to distribute load among several axes. They are also used in high shock and vibration applications.
helical gearboxes work at a higher efficiency than spur gears. However, the manufacturing costs for helical gears are greater than for spur gears.
helical gearboxes also have the advantage of transferring power between right-angle shafts. They can work in conjunction with crossed axis gears, which eliminate shock loading.
Variations
Several variations of helical gearbox are available in the market for different industries. They are widely used in automobile transmissions and other industries. They are quieter than spur gears. They are also durable and are highly efficient. However, they can cause higher friction and wear.
Helical gears are made of teeth that twist around a cylindrical gear body at an angle. The angle at which the gear teeth are cut is called the helix angle. The helix angle can be adjusted to fit the gear and its surroundings.
The helix angle also determines how much axial force the gear produces. A larger helix angle will generate more axial force. This increase in axial force must be absorbed by the bearings. The pressure angle also has a direct impact on the normal force and curvature radii of the tooth.
Helical gears can be mounted in parallel or crossed configuration. Helical gears connected in parallel require the same pitch and pressure angle to work correctly. Helical gears connected in crossed configuration can operate more quietly and smoothly than spur gears. However, they can also be used to transmit higher torques.
Helical gears are also available in single and double helical designs. Single helical gears are produced with the same tools and equipment as spur gears. Unlike spur gears, single helical gears have more surface contact. They are also better for precision drives.
Double helical gears are also called herringbone gears. They are produced by cutting a groove between two teeth. They can eliminate axial forces and are also used to provide high load carrying capacity.
Helical gears are commonly used for low power transmission applications. They also provide an alternative for connecting parallel and non-parallel shafts. They are also used in high speed applications.
Tool tip radius
Among the many parameters that are used in a helical gearbox design, the tooth tip radius is probably the most important, albeit only because it is one of the least intuitive. The best way to estimate the diameter of a helical gear tooth is to use a tooth reference profile as the basis for the calculation. A similar procedure is used to calculate the helix angle. A tool tip that is too small will result in a tooth that undercuts, which is a problem if you have a gear that has a high number of teeth and you want to reduce the chance of tooth failure.
For the gear buffs, there are many helical gearbox tools and processes, the tip diameter being but one of them. Luckily for gear design geeks, there is a lot more to the helical gearbox than meets the eye. For example, a helical gear tooth is a three-dimensional surface, so its shape and function can be computed mathematically or numerically.
In addition to a tooth tip that flies by the seat of your pants, the helical gearbox is also the product of a manufacturing process. The main culprit is the profile shift, which is the distance between the gear pitch diameter and the datum line of the cutting tool. While a gear designer could choose to ignore this issue, it is often a design consideration for the benefit of maximizing contact ratios. This means that the gear teeth must be able to withstand the torque of their respective gear trains.
A helical gear is a geometric package, and the best way to package the gears is to minimize tooth bending strength while maximizing tooth bending stiffness. To do this, you must limit the thickness of your tooth tip. This is usually accomplished with a tooth profile that is shaped to match the tooth contour of the gear it is intended to replace.
editor by czh 2022-12-12