Product Description
Product Description
Free Forging and Open Die Forging factory for 30 years. ZPMC, CHINAMFG and ZheJiang Electric long term stable supplier.
Our Forged Steel Products
Tiangong Forging supplies a variety of semi-finished forged steel products, with the main materials being nickel-molybdenum steel, alloy steel, die steel, stainless steel and carbon steel. In addition to general steel grades such as 35#, 45#, 42CrMo, 42CrMo4, 18CrNiMo7-6, 20CrNi2Mo, 30CrNiMo8 and etc., we can also prepare the required steel according to other national specifications or specified alloy compositions requested by customers.
The maximum production shaft forging length/weight is 12m/15T; the maximum gear and wheel forging diameter/weight is 1.9m/9T.
We are particularly specialized in the forging of special-shaped forging parts.
Our main products:
A.Forged Gear Blank
B.Wheel and Pulley
C.Forged Shaft
D.Hollow Shaft
E.Crankshaft
F.Multi-stepped Shaft
G.Various forged blank and block
I. Special-shaped Forging Parts
Product Parameters
Our open die forging process capabilities include:
|
ITEM |
MAX OD |
MAX HEIGHT |
|
Gear |
120″ |
20″ |
|
ITEM |
MAX OD |
MAX THICKNESS |
|
RECTANGLE / BLOCKS |
20″ |
8,000 |
|
ITEM |
MAX DIAMETER |
MAX LENGTH |
|
SHAFTS |
36″ |
78″ |
|
ITEM |
MAX OD |
MAX LENGTH |
|
CYLINDERS |
50″ |
40″ |
More Products
Production Flow Chart
Certifications
Factory Show
Our company located in HangZhou city, ZheJiang province. Neaby ZheJiang . With over 30 years of forging experience. Our focus is on using high-efficiency electro-hydraulic hammer facilities to produce free forged and open-die forged products.
We are proud of our independent quality assurance laboratory, which ensures that all of our products meet our customers’ requirements.
A. More than 25 years of professional free forging and open-die forging manufacturing experience
B. The company covers an area of 71,000 square CHINAMFG
C. The construction area of the production workshop is 12,000 square CHINAMFG
D. Total number of employees: 158
E. 28 engineering and technical personnel
F. 59 skilled workers
G. Annual production capacity is 38,000 tons
H. Annual raw material steel throughput turnover reaches 56,000 tons
Reliable production
At Tiangong Forging, we invest in production equipment every year to maintain and further improve the quality of our products.
The only way to achieve the required quality is to start with a correctly specified material and process it on an efficient forging machine. To ensure the final standards required by our customers, a correct and precisely controlled heat treatment process is a key factor.
Various types of high-precision machining equipment are also an important part of providing products with high customer satisfaction.
- 12 tons Electro-hydraulic Hammer with Operating Machine
- 8 tons Electro-hydraulic Hammer with Operating Machine
- 5 tons Electro-hydraulic Hammer with Operating Machine
- 20 tons Loader
- 5 tons Loader
- Natural Gas Pre-forging Heating Furnace
- Heat Treatment Electric Furnace
- There are 5 heat treatment electric furnaces with loading capacities of 5 tons, 15 tons, 50 tons, 60 tons and 60 tons respectively.
- Various Machining Equipment
- The machining center has multiple high-precision machining equipment such as CNC vertical lathes, CNC horizontal lathes, horizontal milling machines, radial drilling machines, ordinary horizontal lathes, sawing machines, etc
Main Mateirals: Carbon Steel, Stainless Steel and Alloy steels;
International Standards: ASME, JIS, DIN, GB, BS, EN, AS, SABS, etc.
Standardization and Customization are both our advantages.
Application:
Our parts are widely used in Chemical Industry, Wind power generator, Large machinery parts Chemical industry,Agricultural machinery parts ship shaft fittings. Wind Power gearbox Transmission system.
HangZhou Port, HangZhou automatic Port, ZheJiang Yang shan Port, Italy Vado port. ZheJiang Tailway crane, Egypt hanging bridge, Sri Lanka railway crane, Thailand port bridge. South Korea railway crane, Hongkong island bridge, Singapore railway crane, Russia oil & mining machines and some miltary project. etc.
Customized solutions
Our modular process allows us to design solutions various industrial application requiring free-forged and open-die-forged parts. Our modularity means flexibility, wide choice, faster delivery and, above all, competitiveness.
All Tiangong Forging, products and production processes are designed to ensure exceptional, reliable and long-lasting unique mechanical properties, thereby reducing operating costs and extending service life.
With an extensive product range and extensive experience gained in most industrial applications, we can also provide engineering advice to our customers.
Welcome to visit our factory! Welcome to send inquiry to us.
Welcom Trading compamy to co-operate.
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| Processing Object: | Metal |
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| Molding Style: | Forging |
| Molding Technics: | Free Forging |
| Samples: |
US$ 1000/Ton
1 Ton(Min.Order) | Order Sample |
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| Customization: |
Available
| Customized Request |
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.shipping-cost-tm .tm-status-off{background: none;padding:0;color: #1470cc}
| Shipping Cost:
Estimated freight per unit. |
about shipping cost and estimated delivery time. |
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| Payment Method: |
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|
Initial Payment Full Payment |
| Currency: | US$ |
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| Return&refunds: | You can apply for a refund up to 30 days after receipt of the products. |
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Can you explain the impact of gear shaft misalignment on gear performance?
Gear shaft misalignment can have a significant impact on the performance of gears within a system. When gear shafts are not properly aligned, several issues can arise, affecting the overall functionality and reliability of the gears. Let’s explore the impact of gear shaft misalignment in detail:
- Reduced Efficiency:
Misalignment causes a loss of efficiency in gear systems. When gear shafts are misaligned, the teeth of the gears do not mesh correctly, leading to increased friction and energy losses. This results in reduced power transmission efficiency, as a portion of the input power is dissipated as heat instead of being effectively transferred through the gears.
- Increased Wear and Fatigue:
Misalignment can lead to uneven contact and loading between gear teeth. This uneven distribution of forces causes localized high-stress areas on the gear teeth, leading to accelerated wear and fatigue. The concentrated stress on specific areas of the teeth can result in pitting, wear, and even tooth breakage over time. Increased wear and fatigue significantly reduce the lifespan of gears and can lead to unexpected failures.
- Noise and Vibration:
Gear shaft misalignment often results in increased noise and vibration levels within the gear system. As the misaligned teeth engage, they generate excessive noise due to impact and increased friction. The vibrations caused by the misalignment can propagate through the gear assembly and the surrounding components, causing additional noise and potentially affecting the performance and lifespan of the entire system.
- Loss of Tooth Contact:
Misalignment can cause a loss of proper tooth contact between the gears. Insufficient tooth contact reduces the load-carrying capacity of the gears and compromises the transmission of torque. The reduced contact area also increases the likelihood of localized stress concentrations, leading to premature wear and failure.
- Overloading and Unbalanced Loads:
Gear shaft misalignment can result in overloading and unbalanced loads on the gears. Misalignment can cause uneven distribution of forces, with some teeth bearing a higher load than others. This can lead to excessive stress on specific gear teeth, potentially exceeding their load-carrying capacity. Over time, the overloading of certain teeth can result in accelerated wear, tooth breakage, and even catastrophic gear failure.
- Seal and Bearing Issues:
Misalignment can also affect the performance of seals and bearings within the gear system. Misaligned gear shafts can create additional radial or axial loads on the bearings, reducing their lifespan and causing premature failure. Seal integrity can also be compromised, leading to leaks and contamination of the gear system, further exacerbating the issues associated with misalignment.
In summary, gear shaft misalignment has a detrimental impact on gear performance. It reduces efficiency, increases wear and fatigue, generates noise and vibration, causes loss of tooth contact, leads to overloading and unbalanced loads, and affects the performance of seals and bearings. Proper alignment of gear shafts is crucial to ensure optimal gear performance, longevity, and reliable power transmission within the gear system.
How do you select the appropriate material for constructing a gear shaft?
Selecting the appropriate material for constructing a gear shaft is crucial for ensuring its durability, strength, and overall performance within a mechanical system. Several factors need to be considered when choosing the material for a gear shaft. Let’s explore the process of selecting the appropriate material:
- Load and Torque Requirements:
The first step in material selection is assessing the load and torque requirements of the gear shaft. Consider the maximum load the gear shaft will experience during operation, as well as the torque it needs to transmit. These factors determine the material’s strength and fatigue resistance needed to withstand the applied forces without deformation or failure.
- Wear Resistance:
Gears undergo constant contact and sliding motion, which can lead to wear over time. Therefore, it is important to consider the wear resistance of the material for the gear shaft. Materials with high hardness, such as hardened steels or specific alloys, are often preferred due to their ability to resist wear and withstand the repetitive contact between gear teeth.
- Fatigue Resistance:
Gear shafts are subjected to cyclic loading, which can cause fatigue failure if the material is not able to withstand these repeated stress cycles. It is essential to choose a material with good fatigue resistance to ensure that the gear shaft can withstand the expected number of load cycles without premature failure. Steels with appropriate alloying elements or specialized alloys like nickel-chromium-molybdenum alloys are commonly used for their high fatigue resistance.
- Torsional Strength:
Torsional strength refers to a material’s ability to resist twisting or torsional forces. Gear shafts transmit torque, and therefore, the selected material should have sufficient torsional strength to handle the applied torque without excessive deformation or failure. Steels, particularly those with high carbon content, are often chosen for their excellent torsional strength.
- Heat Treatment Capability:
The ability to heat treat the material is an important consideration in gear shaft selection. Heat treatment processes like quenching and tempering can significantly enhance the mechanical properties of certain materials, such as steels. Heat treatment can improve hardness, strength, and toughness, allowing the gear shaft to withstand higher loads and provide better performance.
- Corrosion Resistance:
In applications where the gear shaft may be exposed to corrosive environments, selecting a material with good corrosion resistance is essential. Stainless steels or corrosion-resistant alloys like bronze or brass are often used to prevent degradation due to moisture, chemicals, or other corrosive agents.
- Manufacturability and Cost:
Considerations of manufacturability and cost are also important in material selection. The chosen material should be readily available, easily machinable, and cost-effective for the specific application. Balancing the desired material properties with manufacturing feasibility and cost constraints is crucial to achieve an optimal solution.
In summary, selecting the appropriate material for constructing a gear shaft involves considering factors such as load and torque requirements, wear resistance, fatigue resistance, torsional strength, heat treatment capability, corrosion resistance, manufacturability, and cost. Evaluating these factors enables the identification of a material that can provide the necessary strength, durability, and overall performance for the gear shaft within the specific mechanical system.
What is a gear shaft and how does it function in mechanical systems?
A gear shaft is a key component in mechanical systems that transmit rotational motion and power between gears. It acts as a mechanical linkage, connecting two or more gears and enabling the transfer of torque and rotational speed. Here’s how a gear shaft functions in mechanical systems:
- Power Transmission:
A gear shaft serves as a means of power transmission between gears. When one gear is rotated, either by an input source or another gear, the gear shaft transmits the rotational motion to the connected gear or gears. This allows for the transfer of power from one gear to another, resulting in the desired mechanical output.
- Support and Alignment:
A gear shaft provides support and alignment for the gears it connects. It is typically mounted on bearings or bushings within the mechanical system, allowing it to rotate smoothly. The bearings help reduce friction and wear, ensuring efficient power transmission and prolonging the lifespan of the gears and the shaft.
- Torque Transmission:
In addition to transmitting rotational motion, a gear shaft also transmits torque. Torque is the rotational force that causes an object to rotate. As a gear shaft connects gears with different sizes or numbers of teeth, it allows for torque multiplication or reduction, depending on the gear ratios. This enables mechanical systems to achieve the desired speed and torque requirements for specific applications.
- Speed Control:
The gear shaft, along with the gears it connects, plays a crucial role in controlling rotational speed. By using gears with different sizes or ratios, the gear shaft can increase or decrease the rotational speed of the output gear compared to the input gear. This speed control capability is essential in various applications, such as adjusting the speed of machinery or enabling different speed settings in vehicles.
- Directional Change:
Another function of a gear shaft is to change the direction of rotational motion. By using gears with specific tooth profiles and arrangements, the gear shaft can redirect the rotational motion by 90 degrees or any desired angle. This directional change allows mechanical systems to transmit motion and power efficiently in different orientations, enabling complex machinery and mechanisms.
- Load Distribution:
A gear shaft helps distribute the load evenly among the connected gears. As the gears engage with each other through their teeth, the gear shaft ensures that the force and torque applied to one gear are evenly transferred to the others. This load distribution minimizes excessive stress on individual gears, promotes smooth operation, and enhances the overall durability and reliability of the mechanical system.
In summary, a gear shaft is a critical component in mechanical systems that facilitates power transmission, torque transfer, speed control, directional change, load distribution, and alignment of gears. Its proper design, installation, and maintenance are essential for efficient and reliable operation of various machinery and mechanisms.
editor by Dream 2024-04-29