China Best Sales Professional Manufacture High Quality and Precision Customized OEM Forging Casting Gearbox Helical Gear of Various Application with Stainless Steel/Alloy/Metal worm gear winch
Product Description
We are a professional company in bulk material handling, transportation, storage, processing, accessory equipment design, integration and manufacturing. We can provide a complete set of solutions. Thank you for reading the information and welcome to purchase! Welcome to agent distribution!
Brief introduction of the company’s manufacturing capacity
The company’s headquarters, technology and sales are located in Lingang New Area of China (ZheJiang ) pilot free trade zone,The company’s manufacture base is located in Xihu (West Lake) Dis. county, ZHangZhoug Province, which is known as “the most beautiful county in China”. It is 65 kilometers away from HangZhou city and 60 kilometers away from Qiandao Lake. The transportation to Xihu (West Lake) Dis. county from other places is very convenient. No matter by railway, highway or waterway. The manufacture base has a total plant area of around 30000 square CHINAMFG and workshop is equipped with more than 300 sets of various advance manufacture equipment, including 20 sets of CNC precision vertical lathe MODEL: SMVTM12000×50/150, CNC vertical lathe MODEL:DVT8000×30/32, CNC horizontal lathe, MODEL: CK61315×125/32, CNC horizontal lathe MODEL:CK61200×80/32, CNC Grounding boring and milling machine MODEL:TJK6920,etc.Most of the parts are machined by using CNC machine equipment. Theis is a hot treatment CHINAMFG with size 10.5m×8m×8m. The manufacture base also equipped with lifting capacity of 25t, 50t, 100t, 200t overhead crane to handle heavy workpiece and assembly work.
Metalworking equipment
| Name of equipment | Model number | Quantity | SCOPE of application | |
| A | Lathes | |||
| 1 | Vertical Lathe | Numerical control | 1 | Φ 12000 |
| 2 | Vertical Lathe | Numerical control | 1 | Φ 8000 |
| 3 | Vertical Lathe | 1 | Φ 1600 | |
| 4 | Vertical Lathe | C5112A | 1 | Ф 1250 |
| 5 | Horizontal Lathe | Numerical control | 1 | CK61315×12×100T |
| 6 | Horizontal Lathe | CW61200 | 1 | Ф 2000×8000 |
| 7 | Horizontal Lathe | CW61160 | 1 | Ф 1600×6500 |
| 8 | Horizontal Lathe | CW6180 | 2 | Ф 800×3000 |
| 9 | Horizontal Lathe | CW61125 | 2 | Ф 1250×5000 |
| 10 | Horizontal Lathe (remodel) | CW62500 | 2 | Ф 2800×6000 |
| 11 | Common Lathe | CY6140 | 3 | Ф 400×1000 |
| 12 | Common Lathe | CA6140 | 3 | Ф 400×1500 |
| 13 | Common Lathe | C620 | 2 | Ф 400×1400 |
| 14 | Common Lathe | C616 | 1 | Ф 320×1000 |
| 15 | Common Lathe | C650 | 1 | Ф 650×2000 |
| B | Drilling machine | |||
| 1 | Radial drilling machine | Z3080 | 3 | Ф 80×2500 |
| 2 | Radial drilling machine | Z3040 | 2 | Ф 60×1600 |
| 3 | Universal drilling machine | ZW3725 | 3 | Ф 25×880 |
| C | Planing machine | |||
| 1 | Shaper | B665 | 1 | L650 |
| 2 | Hydraulic Shaper | B690 | 1 | L900 |
| 3 | Gantry Planer | HD–16 | 1 | L10000×B1600 |
| D | Milling Machine | |||
| 1 | 4 Coordinate Milling Machine | Numerical control | 1 | 2500×4000 |
| 2 | Gantry milling machine | Numerical contro | 1 | 16mx5mx3m |
| 3 | Gantry milling machine | Numerical contro | 1 | 12mx4mx2.5m |
| 4 | Gantry milling and boring machine | Numerical contro | 1 | Φ 250 |
| 5 | Vertical Milling Machine | XS5054 | 1 | 1600×400 |
| 6 | Horizontal Milling Machine | C62W | 1 | 1250×320 |
| 7 | Horizontal Milling Machine | X60 | 1 | 800×200 |
| 8 | Gantry milling machine | X2014J | 1 | L4000×B1400 |
| 9 | Gantry milling machine | X2571J | 1 | L3000×B1000 |
| 10 | Floor end milling | TX32-1 | 1 | L1500×H800 |
| E | Grinding machine | |||
| 1 | External Grinder | M131W | 1 | Ф 300×1000 |
| 2 | External Grinder | M1432B | 1 | Ф 320×15000 |
| 3 | Surface Grinder | M7130 | 1 | L 1000×300 |
| 4 | Tool grinder | M6571C | 1 | Ф 250 |
| F | Boring machine | |||
| 1 | Floor-standing milling and boring machine | TJK6920 | 1 | X12000 × Y4500 × Z1000 |
| 2 | Boring machine | TSPX619 | 1 | Ф 1000 |
| 3 | Boring machine | T616 | 1 | Ф 800 |
| 4 | Boring machine | T611 | 1 | Ф 800 |
| G | Slotted bed | |||
| 1 | Slotted bed | B5032 | 1 | H320 |
| H | Other machine tools | |||
| 1 | Gear hobbing machine | Y3150 | 1 | Ф 500 M=6 |
| 2 | Hacksaw machine | G7571 | 1 | Ф 220 |
Products and services available
Material handling equipment
Storage equipment
Conveying equipment
Feeding equipment
Component of conveying system
Belt conveyor parts
Large and medium sized finishing parts
If you need above products, please contact us!
ZheJiang Sunshine Industrial Technology Co. , Ltd.
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| Application: | Motor, Electric Cars, Motorcycle, Machinery, Marine, Toy, Agricultural Machinery, Car, Customization |
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| Hardness: | Customization |
| Gear Position: | Customization |
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| Currency: | US$ |
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| Return&refunds: | You can apply for a refund up to 30 days after receipt of the products. |
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What is the lifespan of a typical helical gear?
The lifespan of a typical helical gear can vary depending on several factors, including the quality of the gear design, manufacturing processes, operating conditions, maintenance practices, and the specific application in which the gear is used. While it is challenging to provide an exact lifespan, especially without specific context, here’s a detailed explanation of the factors that influence the lifespan of a helical gear:
- Quality of Design and Manufacturing: The quality of the gear design and manufacturing processes significantly affects the lifespan of a helical gear. Gears that are well-designed, with accurate tooth profiles and proper material selection, tend to have longer lifespans. Precise manufacturing techniques, including gear cutting and tooth hardening processes, contribute to the gear’s durability and resistance to wear.
- Operating Conditions: The operating conditions in which a helical gear is used play a crucial role in its lifespan. Factors such as the magnitude and frequency of torque loads, rotational speed, lubrication, temperature, and the presence of contaminants or corrosive substances can impact gear performance and longevity. Gears operating under heavy loads or in harsh environments may experience more wear and have a shorter lifespan compared to gears operating under lighter loads and cleaner conditions.
- Maintenance Practices: Regular and proper maintenance practices can significantly extend the lifespan of a helical gear. This includes routine inspections, lubrication, and cleaning to ensure optimal gear performance. Inadequate maintenance, such as insufficient lubrication or neglecting to address early signs of wear or misalignment, can accelerate gear deterioration and reduce its lifespan.
- Load Distribution: The distribution of the load across the gear teeth affects the lifespan of a helical gear. Proper alignment, accurate gear meshing, and evenly distributed torque loads help prevent localized wear and excessive stress on specific teeth. Uneven load distribution or misalignment can lead to premature wear and reduce the gear’s overall lifespan.
- Material Selection: The choice of materials for the helical gear impacts its durability and lifespan. High-quality materials with excellent strength, hardness, and wear resistance properties, such as alloy steels or specialized gear materials, can enhance gear longevity. The selection of materials should consider the specific application requirements, including the expected torque loads and operating conditions.
- Application Specifics: The nature of the application in which the helical gear is used also influences its lifespan. Some applications may involve intermittent or cyclical loading, while others may require continuous operation. The severity of the application, such as high-speed or high-torque environments, can affect gear wear and lifespan. Properly selecting a helical gear that is specifically designed and rated for the intended application can help maximize its lifespan.
It’s important to note that the lifespan of a helical gear is not necessarily a fixed value but rather an estimation based on various factors. With proper design, quality manufacturing, suitable materials, appropriate operating conditions, and regular maintenance, a well-engineered helical gear can have a long and reliable lifespan in its intended application.
How do you calculate the efficiency of a helical gear?
The efficiency of a helical gear can be calculated by comparing the power input to the gear with the power output. The efficiency represents the ratio of the output power to the input power, expressed as a percentage. Here’s a detailed explanation of how to calculate the efficiency of a helical gear:
The formula for calculating gear efficiency is:
Efficiency = (Power Output / Power Input) * 100%
To calculate the efficiency, you need to determine the power input and power output values. Here are the steps involved:
- Power Input: The power input to the gear is the amount of power supplied to the gear system. It can be determined by multiplying the input torque (Tin) by the input rotational speed (Nin) in radians per second. The formula for power input is:
Power Input = Tin * Nin
- Power Output: The power output from the gear is the amount of power delivered by the gear system. It can be calculated by multiplying the output torque (Tout) by the output rotational speed (Nout) in radians per second. The formula for power output is:
Power Output = Tout * Nout
- Calculate Efficiency: Once you have determined the power input and power output values, you can calculate the gear efficiency using the formula mentioned earlier:
Efficiency = (Power Output / Power Input) * 100%
The resulting efficiency value will be a percentage, representing the proportion of input power that is effectively transmitted as output power by the helical gear system. A higher efficiency value indicates a more efficient gear system, with less power loss during the gear transmission.
It’s important to note that gear efficiency can be influenced by various factors, including gear design, tooth profile, operating conditions, lubrication, and manufacturing quality. Therefore, the calculated efficiency represents an estimate based on the given input and output power values, and it may vary in real-world applications.
What is a helical gear and how does it work?
A helical gear is a type of cylindrical gear with teeth that are cut at an angle to the gear axis. It is widely used in various mechanical systems to transmit power and motion between parallel shafts. Here’s a detailed explanation of helical gears and their working principles:
A helical gear consists of a cylindrical shape with teeth that are cut in a helical pattern around the gear’s circumference. The teeth of a helical gear are not perpendicular to the gear axis but are instead aligned at an angle, forming a helix shape. This helix angle allows for gradual engagement and disengagement of the gear teeth, resulting in smoother and quieter operation compared to spur gears.
The working principle of a helical gear involves the transfer of rotational motion and power between parallel shafts. When two helical gears mesh together, their helical teeth gradually come into contact, causing a sliding action as the gears rotate. This sliding action creates both axial and radial forces on the teeth, resulting in a thrust load along the gear axis.
As the helical gears rotate, the sliding action between the teeth causes a force component along the gear axis. This axial force is responsible for generating the thrust load on the gear, which must be properly supported by suitable thrust bearings or other means to ensure smooth and efficient operation.
The helical gear design offers several advantages:
- Smooth and Quiet Operation: The helical teeth engagement allows for a gradual contact between the gear teeth, reducing impact and noise during operation. This results in smoother and quieter gear performance compared to spur gears.
- Increased Load-Carrying Capacity: The helical gear design provides greater tooth contact compared to spur gears. This increased contact area allows helical gears to transmit higher loads and handle greater torque without experiencing excessive wear or tooth failure.
- Parallel Shaft Operation: Helical gears are primarily used for transmitting power and motion between parallel shafts. By meshing two helical gears on parallel shafts, rotational motion can be efficiently transmitted from one shaft to the other with a constant speed ratio.
- Ability to Transmit Motion at Various Angles: While helical gears are commonly used for parallel shaft applications, they can also be used to transmit motion at non-parallel shaft angles by using a combination of helical gears or by incorporating additional components such as bevel gears.
It is important to consider a few factors when using helical gears:
- Helix Angle: The helix angle determines the degree of tooth engagement and sliding action. A higher helix angle increases the smoothness of operation but also introduces a larger axial force and thrust load on the gear.
- Direction of Helix: Helical gears can have either a right-hand or left-hand helix. When two helical gears mesh, they must have opposite helix directions to ensure proper engagement.
- Lubrication: Due to the sliding action between helical gear teeth, proper lubrication is crucial to minimize friction, wear, and heat generation. Adequate lubrication helps ensure the longevity and efficiency of the gear system.
In summary, a helical gear is a cylindrical gear with teeth cut in a helical pattern. It operates by gradually engaging and disengaging the teeth, resulting in smooth and quiet operation. Helical gears are widely used in various mechanical systems for parallel shaft applications, providing high load-carrying capacity and efficient power transmission.
editor by Dream 2024-05-03