Product Description
Worm Gear Series Double Enveloping Worm Gear Unit
Product Description
1, High torque double enveloping worm gear adjust toughest working condition .
2,Universal design double enveloping worm gearbox.
3, Smooth and noiseless operation double worm gearbox.
4, Higher driving efficiency than traditional worm gear.
5, Increasing loading capacity .
6, Strict quality test before shipping
7, Customized design for various application
8, Long life service period
9,suitable price with moderated
10, moderate price & high quality
In a Worm Gearbox, Worm Reduction Gear Box, Worm Speed Reducer and Gear Motor Manufacturer, three to 11 gear teeth are typically in contact with the worm, depending CHINAMFG the ratio. The increased number of driven gear teeth that are in contact with the worm significantly increases torque capacity also raises shock load resistance. In addition to increasing the number of driven gear teeth in contact with the worm, Worm Gearbox, Worm Reduction Gear Box, Worm Speed Reducer and Gear Motor Manufacturer also increases the contact area on each gear tooth. The actual areas of instantaneous contact between the worm threads and the driven gear tooth are lines. These lines of contact move across the face of the gear tooth as it progresses through its total time of mesh with the worm. The lines of contact in double-enveloping worm gearing are configured to increase the power transmission capability and reduce the stress on each gear tooth.
Working conditions
Two shafts for 90 ° Intersect, input speed must not be more than 1500 rpm.The working environment temperature should range from 0 ~ 40 ° C, when the environment temperature below 0 ° C or above 40 ° C.Before starting the lubricating oil to corresponding heating and cooling, The worm shafts, reverse operation can be positive.
Data sheet on CUW double enveloping worm gear reducer :
Model | ShaftDia. (mm) | Center Height (CUW) | (CUW) Output shaft Dia. | Power | Ratio | Permitted Torque | Weight |
(CUW) input Solid(h6) | (mm) | (mm) | (kw) | (Nm) | (KGS) | ||
100 | 28 | 190 | 48 | 1.41~11.5 | 10 .25~ 62 | 683-1094 | 42 |
125 | 32 | 225 | 55 | 2.42~19.7 | 10 .25 ~ 62 | 1170~2221 | 65 |
140 | 38 | 255 | 65 | 3.94~25.9 | 10 .25 ~ 62 | 1555 ~ 3473 | 85 |
160 | 42 | 290 | 70 | 4.39~35.7 | 10 .25 ~ 62 | 2143 ~4212 | 120 |
180 | 48 | 320 | 80 | 5.83~47.5 | 10 .25 ~ 62 | 2812 ~ 5387 | 170 |
200 | 55 | 350 | 90 | 7.52 ~61.2 | 10 .25 ~ 62 | 3624 ~6859 | 220 |
225 | 60 | 390 | 100 | 9.9~81.4 | 10 .25 ~ 62 | 4872 ~ 9224 | 290 |
250 | 65 | 430 | 110 | 12.9 ~105 | 10 .25~ 62 | 6284~11892 | 380 |
280 | 70 | 480 | 120 | 16.9 ~ 138 | 10 .25 ~ 62 | 8347 ~ 15820 | 520 |
315 | 75 | 530 | 140 | 22.5 ~183 | 10 .25 ~ 62 | 11068~ 19450 | 700 |
355 | 80 | 595 | 150 | 30~245 | 10 .25 ~ 62 | 14818 ~28014 | 1030 |
400 | 90 | 660 | 170 | 32.1 ~261 | 10 .25 ~ 62 | 15786~29918 | 1400 |
450 | 100 | 740 | 190 | 42.6 ~347 | 10 .25 ~ 62 | 2571~39881 | 1980 |
500 | 110 | 815 | 210 | 54.9 ~ 448 | 10 .25 ~ 62 | 27097~51180 | 2700 |
Advantage:
The advantage of CHINAMFG High Efficiency, Low Noice Cone Worm Series Worm Gearbox design are dramatic. First, the total load is divided among more individual gear teeth, and the load is further divided where teeth support 2 lines of contact. This superior load distribution greatly increases load carrying capacity. Second, the improved torque throughput allows a smaller reducer to produce the same amount of torque, resulting in size and weight savings.
Double-enveloping worm gearing can carry loads that would require much larger and heavier cylindrical worm gearing.
Double-enveloping worm gearbox figure :
(Click on picture for more information)
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Application: | Motor, Machinery, Marine, Agricultural Machinery |
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Function: | Distribution Power, Change Drive Torque, Change Drive Direction, Speed Changing, Speed Reduction, Speed Increase |
Layout: | Angle |
Hardness: | Hardened Tooth Surface |
Installation: | Horizontal Type |
Step: | Single-Step |
Samples: |
US$ 500/Piece
1 Piece(Min.Order) | |
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Customization: |
Available
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How does the design of worm wheels impact their performance in different environments?
The design of worm wheels plays a significant role in determining their performance in different environments. Here’s a detailed explanation of how the design of worm wheels impacts their performance:
- Tooth Profile: The tooth profile of a worm wheel can significantly affect its performance. Different tooth profiles, such as involute, cycloidal, or modified profiles, offer varying characteristics in terms of contact area, load distribution, and efficiency. The selection of the appropriate tooth profile depends on factors such as the application requirements, load capacity, and desired efficiency. For example, in applications where high load capacity is crucial, a modified tooth profile may be preferred to enhance the gear’s strength and durability.
- Material Selection: The choice of material for worm wheels is crucial for their performance in different environments. Worm wheels can be made from various materials, including steel, bronze, brass, or specialized alloys. Each material offers different properties such as strength, wear resistance, corrosion resistance, and self-lubrication. The selection of the appropriate material depends on factors such as the operating conditions, anticipated loads, and environmental factors. For example, in applications where corrosion resistance is essential, a stainless steel or corrosion-resistant alloy may be chosen to ensure long-term performance in harsh environments.
- Lubrication and Sealing: Proper lubrication and sealing are vital for the performance of worm wheels, especially in challenging environments. The design of worm wheels should consider factors such as lubrication requirements, sealing mechanisms, and the ability to prevent contamination ingress. Lubrication ensures smooth operation, reduces friction, and minimizes wear between the worm gear and the worm wheel. Effective sealing prevents the entry of contaminants such as dust, dirt, or moisture, which can adversely affect the gear’s performance and lifespan. The design should incorporate appropriate lubrication and sealing provisions based on the specific environmental conditions.
- Heat Dissipation: In environments where high temperatures are present, the design of worm wheels should consider heat dissipation mechanisms. Excessive heat can lead to premature wear, reduced efficiency, and potential damage to the gear system. The design may include features such as cooling fins, heat sinks, or ventilation channels to facilitate heat dissipation and maintain optimal operating temperatures. Proper heat dissipation design ensures the longevity and reliability of worm wheels in high-temperature environments.
- Noise and Vibration Control: The design of worm wheels can incorporate features to control noise and vibration, which are particularly important in certain environments. Modifications to the tooth profile, manufacturing tolerances, or the addition of damping elements can help reduce noise and vibration generation. In noise-sensitive environments or applications where excessive vibration can affect precision or stability, the design should prioritize noise and vibration control measures to ensure smooth and quiet operation.
- Environmental Factors: The design of worm wheels should consider specific environmental factors that can impact their performance. These factors may include temperature extremes, humidity, corrosive substances, abrasive particles, or even exposure to outdoor elements. The design may incorporate protective coatings, specialized materials, or enhanced sealing mechanisms to mitigate the effects of these environmental factors. Considering and addressing the specific environmental challenges helps ensure optimal performance and longevity of worm wheels in different environments.
By carefully considering the design aspects mentioned above, worm wheels can be tailored to perform reliably and efficiently in different environments. The design choices made for tooth profile, material selection, lubrication, heat dissipation, noise and vibration control, and addressing environmental factors are essential for optimizing the performance and durability of worm wheels in their intended applications.
Can you describe the various types and configurations of worm wheels available?
There are several types and configurations of worm wheels available to suit different applications and requirements. Here’s a description of the various types and configurations:
- Single-Threaded Worm Wheel: This is the most common type of worm wheel configuration. It has a single thread on its circumference that meshes with the worm gear. Single-threaded worm wheels provide a high gear reduction ratio and are used in applications where high torque and low-speed operation are required.
- Double-Threaded Worm Wheel: Double-threaded worm wheels have two threads on their circumference, which results in increased contact area and improved load distribution. This configuration allows for higher torque transmission capacity and smoother operation. Double-threaded worm wheels are utilized in applications that require even higher torque output and improved efficiency.
- Non-Cylindrical Worm Wheel: In some cases, the worm wheel may have a non-cylindrical shape. For example, it can have a concave or convex profile. Non-cylindrical worm wheels are used in specific applications where the shape is designed to accommodate unique requirements such as increased contact area, improved load distribution, or specialized motion control.
- Enveloping Worm Wheel: Enveloping worm wheels have specialized tooth profiles that provide increased contact area and improved load-carrying capacity. The teeth of the worm wheel wrap around the helical threads of the worm gear, resulting in enhanced meshing and load distribution. Enveloping worm wheels are typically used in high-load applications that require superior torque transmission and durability.
- Hypoid Worm Wheel: Hypoid worm wheels are designed with a hypoid offset, meaning that the centerline of the worm gear is offset from the centerline of the worm wheel. This configuration allows for smoother meshing and increased contact area, leading to improved load distribution and reduced wear. Hypoid worm wheels are often utilized in applications that require high torque, compact design, and smooth operation.
- Materials: Worm wheels can be made from a variety of materials depending on the application requirements. Common materials include steel, bronze, brass, and specialized alloys. Steel worm wheels offer high strength and durability, while bronze and brass worm wheels provide excellent wear resistance and self-lubricating properties. The choice of material depends on factors such as load capacity, operating conditions, and cost considerations.
These are some of the types and configurations of worm wheels available. The selection of a particular type depends on the specific application requirements, including torque, speed, load capacity, space constraints, and desired efficiency. It’s important to consider factors such as tooth profile, material selection, and manufacturing precision to ensure the reliable and efficient operation of the worm wheel in a given application.
How does the design of a worm wheel contribute to the efficiency of power transmission?
The design of a worm wheel plays a significant role in ensuring efficient power transmission in mechanical systems. The specific characteristics and features of the worm wheel design contribute to its efficiency. Here’s a detailed explanation of how the design of a worm wheel contributes to the efficiency of power transmission:
1. Helical Tooth Profile: The teeth of a worm wheel are cut in a helical pattern around its circumference. This helical tooth profile allows for a larger contact area between the worm gear and the worm wheel, distributing the load over multiple teeth. As a result, it reduces the stress on individual teeth and minimizes wear, leading to improved efficiency and longevity of the gear system.
2. Sliding Action: The interaction between the worm gear and the worm involves a sliding action. As the worm rotates, its threads engage with the helical teeth of the worm wheel, causing a sliding motion between the two components. This sliding action helps distribute the load and reduces the concentration of forces on specific points, minimizing friction and wear. Consequently, the sliding action contributes to smoother power transmission and improved overall efficiency.
3. Lubrication: Proper lubrication is essential for the efficient operation of a worm wheel. Lubricants reduce friction between the mating surfaces, minimizing energy losses due to heat and wear. The helical tooth profile and sliding action of the worm wheel allow for effective lubrication distribution along the gear teeth and the worm’s threads, ensuring smooth movement and reducing power losses due to friction.
4. Material Selection: The choice of materials for constructing the worm wheel can impact its efficiency. Materials with low friction coefficients and high wear resistance, such as hardened steel or bronze alloys, are often used to minimize friction losses and ensure long-lasting performance. Additionally, selecting materials with appropriate strength and hardness characteristics helps maintain the dimensional stability and integrity of the gear teeth, further enhancing the efficiency of power transmission.
5. Gear Geometry and Tooth Profile: The precise design of the teeth on the worm wheel contributes to efficient power transmission. Factors such as the tooth profile, pressure angle, tooth width, and backlash control impact the meshing and engagement between the worm gear and the worm wheel. Optimized gear geometry ensures proper load distribution, reduces tooth deflection, and minimizes power losses due to inefficient contact and meshing of the teeth.
6. Preloading and Backlash Control: Proper preloading and backlash control in the worm wheel system can improve its efficiency. Preloading refers to applying a controlled amount of force to eliminate any clearance or backlash between the worm gear and the worm wheel. This reduces vibrations, improves the contact between the teeth, and minimizes power losses associated with backlash. By ensuring a precise and tight meshing between the components, the efficiency of power transmission is enhanced.
7. Manufacturing Precision: The manufacturing precision of the worm wheel is crucial for its efficiency. Accurate machining and assembly processes are necessary to achieve the desired gear geometry, tooth profile, and dimensional tolerances. High manufacturing precision ensures proper alignment and meshing of the worm gear and the worm wheel, reducing unnecessary friction and power losses caused by misalignment or poor gear quality.
By incorporating these design considerations and optimizing the various aspects of worm wheel design, such as tooth profile, lubrication, materials, and manufacturing precision, the efficiency of power transmission can be maximized. This results in reduced energy losses, improved overall system performance, and extended gear life.
editor by Dream 2024-05-08