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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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 gear pumps be used in hydraulic systems?
Yes, gear pumps can be used in hydraulic systems. Here’s a detailed explanation:
1. Positive Displacement Operation:
Gear pumps operate on the principle of positive displacement, which makes them suitable for hydraulic applications. In hydraulic systems, a pump is required to deliver a consistent flow of fluid to actuate various components such as cylinders or motors. Gear pumps provide a steady and predictable flow rate, ensuring reliable operation of hydraulic systems.
2. Compact and Lightweight:
Gear pumps are often compact and lightweight compared to other types of hydraulic pumps. This makes them suitable for applications where space is limited or weight needs to be minimized. Gear pumps can be easily incorporated into hydraulic systems without adding excessive bulk or weight.
3. Cost-Effective:
Gear pumps are generally more cost-effective compared to other types of hydraulic pumps. They have a simple design with fewer components, which makes them easier to manufacture and maintain. This cost-effectiveness makes gear pumps a popular choice for a wide range of hydraulic applications.
4. Reliability:
Gear pumps are known for their reliability and durability. They have a robust construction with fewer moving parts, which reduces the chances of mechanical failure. Gear pumps can withstand high pressures and provide consistent performance over a long service life, making them well-suited for demanding hydraulic systems.
5. Viscosity Range:
Hydraulic systems may involve fluids with varying viscosities. Gear pumps are capable of handling a wide range of fluid viscosities, from low-viscosity hydraulic oils to more viscous fluids. The positive displacement action of gear pumps ensures a consistent flow rate regardless of the fluid viscosity, allowing them to adapt to different hydraulic fluid requirements.
6. Limitations:
While gear pumps offer several advantages, they also have some limitations in hydraulic systems. Gear pumps are generally not suitable for high-pressure applications where more precise flow control is required. They may produce higher levels of noise and have lower overall efficiency compared to some other types of hydraulic pumps.
In summary, gear pumps can be effectively used in hydraulic systems due to their positive displacement operation, compactness, cost-effectiveness, reliability, and ability to handle a range of fluid viscosities. However, for specific high-pressure or precision flow control requirements, alternative hydraulic pump technologies may be more suitable.
How do gear pumps contribute to accurate and consistent fluid delivery?
Gear pumps play a crucial role in ensuring accurate and consistent fluid delivery in various applications. Here’s a detailed explanation:
1. Positive Displacement Operation:
One of the key factors that contribute to accurate and consistent fluid delivery is the positive displacement operation of gear pumps. Gear pumps trap and displace a fixed volume of fluid with each revolution of the gears. This means that the pump delivers a consistent flow rate regardless of changes in pressure or viscosity. The positive displacement action ensures that the same amount of fluid is moved with each rotation, resulting in accurate and consistent fluid delivery.
2. Tight Clearances:
Gear pumps have tight clearances between the gear teeth and the pump housing, which helps minimize leakage and ensures precise fluid delivery. The close tolerances reduce the amount of fluid bypassing the gears, resulting in minimal slippage and accurate volumetric output. These tight clearances also contribute to the pump’s ability to handle high pressures and maintain consistent flow rates under varying conditions.
3. Low Pulsation:
Gear pumps are known for their low pulsation characteristics, which further enhance accurate and consistent fluid delivery. The meshing of gears creates a continuous and smooth flow of fluid, minimizing pressure fluctuations or pulsations in the system. This low pulsation flow is particularly important in applications where precise control, metering, or dosing of fluids is required.
4. Viscosity Handling:
Gear pumps are capable of handling fluids with a wide range of viscosities, from low-viscosity liquids to highly viscous fluids. This versatility in viscosity handling contributes to accurate and consistent fluid delivery. The positive displacement operation of gear pumps ensures that the pump can effectively move fluids of different viscosities without significant variations in flow rate or delivery accuracy.
5. Material Selection:
The choice of materials used in the construction of gear pumps can also impact accurate and consistent fluid delivery. The materials should be selected to minimize wear, corrosion, or contamination that could affect the pump’s performance or compromise the quality of the delivered fluid. Proper material selection ensures that the pump maintains its dimensional integrity and tight clearances over time, allowing for reliable and consistent fluid delivery.
6. System Integration:
Proper integration of gear pumps into the overall fluid system is essential for accurate and consistent fluid delivery. The system should include appropriate components such as filters, valves, and flow control devices to regulate and control the flow rate, pressure, and other parameters. By ensuring proper system integration, gear pumps can contribute to accurate and consistent fluid delivery throughout the entire system.
In summary, gear pumps contribute to accurate and consistent fluid delivery through their positive displacement operation, tight clearances, low pulsation characteristics, viscosity handling capabilities, appropriate material selection, and proper system integration. These features make gear pumps reliable and efficient in applications where precise fluid delivery is essential, including metering, dosing, lubrication, and other industrial processes.
Can you explain the design and components of a gear pump?
The design of a gear pump involves several components that work together to facilitate fluid transfer. Here’s an explanation of the design and components:
1. Casing or Housing:
The casing or housing of a gear pump is the outer shell that encloses the internal components. It provides structural support and contains the fluid being pumped.
2. Gears:
The primary components of a gear pump are the gears. Gear pumps typically consist of two or more meshing gears that rotate within the casing. The gears may have cylindrical or helical shapes and are precision-machined to ensure accurate meshing and fluid sealing.
3. Inlet and Outlet Ports:
A gear pump has separate inlet and outlet ports to allow fluid to enter and exit the pump. The inlet port is where the fluid enters the pump, while the outlet port is where the pumped fluid is discharged.
4. Gear Teeth:
The gears of a gear pump have teeth that mesh together as they rotate. The gear teeth create chambers or cavities between the gear teeth and the casing walls. These chambers vary in volume as the gears rotate, facilitating fluid transfer.
5. Sealing Mechanism:
To ensure efficient pumping and prevent fluid leakage, gear pumps incorporate sealing mechanisms. These mechanisms may include clearance gaps, sealing strips, or O-rings between the gears and the casing walls.
6. Drive Shaft:
A gear pump is driven by a drive shaft connected to one of the gears. The rotation of the drive shaft imparts motion to the gears, causing them to rotate within the casing.
7. Bearings:
Bearings are used to support the rotating shaft and reduce friction. They help maintain the alignment and stability of the gears, ensuring smooth and efficient operation.
8. Mounting Base:
A gear pump may include a mounting base or flanges for secure installation and connection to the system or equipment.
9. Optional Components:
Depending on the specific application and requirements, gear pumps may incorporate additional components such as pressure relief valves, filters, gauges, or temperature sensors to enhance performance, control, and safety.
The design of a gear pump focuses on creating a positive displacement mechanism using meshing gears to trap and transfer fluid. The precise engineering and integration of these components ensure reliable and efficient fluid transfer in various industrial applications.
editor by CX 2024-03-28