China Custom CNC Horizontal Gear Hobbing Machine CZPT Cutting Machine with Good Price gear box

Product Description

2571 Hot Sales

CNC High Efficient Horizontal Spline Shaft Milling Machine

Our company specializes in producing CNC screw milling machines with over 10 years of experience. Our main products: various plastic machinery, such as extrusion machines, granulators, injection molding machines, film blowing machines, and other dedicated 3-4 axis screw CNC milling machines, 5-axis vacuum pump dedicated screw CNC milling machines, compressor screw dedicated CNC milling machines, CNC spline milling machines, and so on. In addition, our company also produces multi-position dedicated CNC screw machines, mainly used for the processing of multi-process workpieces such as pump bodies and valve bodies. One clamping can complete the processing of multiple end faces (flanges, drilling, etc.). High processing efficiency can effectively save costs and improve processing efficiency.

CNC spline milling machine is developed by our company, specially designed for processing all kinds of screw shaft end spline and special machine

Maximum milling diameter ф 450

Maximum machining modulus 10

Overall high strength casting bed, 3 guide rail layout, guide rail surface high-frequency quenching, good rigidity, high precision.

The milling head is driven by servo spindle motor, which can make the hob achieve infinitely variable speed and wide speed range. The Angle of milling head is adjusted by worm gear transmission with variable tooth thickness.

Feed axis [Z axis, X axis] adopts precision ball screw through servo motor direct drive, high transmission accuracy, good positioning accuracy.

Headstock spindle adopts servo motor directly connected precise wear-resistant worm gear and worm

The tailstock is mechanical, flexible and reliable.

The machine is equipped with a wide range of 218 control system.

the machine is equipped with a chip discharging machine, the iron filings generated in the milling process directly into the chip discharging machine, to ensure the clean working environment.

2571 Hot Sales

CNC High Efficient Horizontal Spline Shaft Milling Machine

 

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Model No.: Lgxm350X6000
Condition: Condition
No. of Spindles: 1
No. of Guide Rails: 3-4
No. of Axis: 3-5
Spindle: C Axis
Customization:
Available

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Customized Request

gear pump

How do gear pumps contribute to reliable and continuous fluid transfer?

Gear pumps play a crucial role in achieving reliable and continuous fluid transfer in various applications. Here’s a detailed explanation:

1. Positive Displacement Operation:

One of the key factors contributing to the reliability of gear pumps is their positive displacement operation. Gear pumps trap and displace a fixed volume of fluid with each revolution of the gears. This ensures a consistent flow rate and accurate fluid delivery, making gear pumps reliable for applications that require precise and continuous transfer of fluids.

2. Minimal Slippage:

Gear pumps have tight tolerances between the gears and the pump housing, resulting in minimal slippage of fluid during operation. The close clearance between the gears and the housing prevents fluid from bypassing the gears, ensuring efficient transfer without significant leakage. This minimizes fluid loss and contributes to continuous and reliable fluid transfer.

3. Self-Priming Capability:

Many gear pumps have self-priming capability, allowing them to draw fluid into the pump without the need for external priming mechanisms. This feature is particularly beneficial when starting or restarting the pump after a period of inactivity or when dealing with fluids that may have air pockets or low inlet pressures. The self-priming capability helps ensure uninterrupted fluid transfer and enhances the reliability of the system.

4. Versatility:

Gear pumps are versatile and can handle a wide range of fluids, including liquids with varying viscosities. They can efficiently transfer low-viscosity fluids as well as more viscous substances. This versatility makes gear pumps suitable for diverse applications, such as chemical processing, lubrication systems, fuel transfer, and hydraulic systems, contributing to reliable and continuous fluid transfer in different industries.

5. Robust Construction:

Gear pumps are typically manufactured with robust materials such as cast iron, stainless steel, or bronze. These materials provide excellent durability and resistance to wear, corrosion, and high pressures. The sturdy construction of gear pumps enables them to withstand demanding operating conditions and ensures long-term reliability in fluid transfer applications.

6. Ease of Maintenance:

Gear pumps are relatively simple in design, consisting of few moving parts. This simplicity makes maintenance and repair procedures straightforward. Routine maintenance tasks such as lubrication, inspection, and seal replacement can be easily performed, minimizing downtime and contributing to continuous fluid transfer.

In summary, gear pumps contribute to reliable and continuous fluid transfer through their positive displacement operation, minimal slippage, self-priming capability, versatility, robust construction, and ease of maintenance. These features make gear pumps a dependable choice for a wide range of applications where consistent and uninterrupted fluid transfer is essential.

gear pump

Can gear pumps handle abrasive and corrosive fluids effectively?

Gear pumps are generally not the most suitable choice for handling abrasive and corrosive fluids effectively. Here’s a detailed explanation:

1. Abrasive Fluids:

Abrasive fluids contain solid particles that can cause wear and damage to pump components. Gear pumps have tight clearances between the gear teeth and the pump housing, and the presence of abrasive particles can lead to accelerated wear and reduced pump efficiency. The abrasive particles can cause erosion of the gears, housing, and other internal surfaces, leading to increased clearances and decreased pump performance over time. While gear pumps may be able to handle some mildly abrasive fluids, they are not designed for heavy-duty abrasive applications.

2. Corrosive Fluids:

Corrosive fluids can chemically attack and degrade the materials used in gear pumps. Many gear pumps are constructed using materials such as cast iron, stainless steel, or bronze, which offer good resistance to corrosion in a wide range of fluids. However, highly corrosive fluids, such as strong acids or alkalis, can still cause damage to these materials over time, leading to leaks, reduced performance, or even pump failure. In corrosive fluid applications, it is often necessary to use specialized materials or corrosion-resistant coatings to protect the pump components.

3. Alternative Options:

For handling abrasive and corrosive fluids effectively, alternative pump technologies are often preferred. Some options include:

  • Diaphragm Pumps: Diaphragm pumps use a flexible diaphragm to handle abrasive and corrosive fluids. The diaphragm separates the fluid from the pump components, protecting them from direct contact with the fluid.
  • Peristaltic Pumps: Peristaltic pumps use a flexible tube or hose to transport fluids. The fluid only comes into contact with the tube, which can be made from materials resistant to abrasion and corrosion.
  • Centrifugal Pumps: Centrifugal pumps are often used for abrasive and corrosive fluids. They rely on the centrifugal force generated by a rotating impeller to move the fluid, and they can be constructed with materials that withstand the corrosive effects of the fluid.
  • Progressive Cavity Pumps: Progressive cavity pumps use a rotating screw-like rotor inside a rubber stator to transfer fluids. The design allows for gentle handling of abrasive and corrosive fluids without significant wear or damage.

In summary, while gear pumps can handle some mildly abrasive fluids and certain corrosive fluids, they are not typically the most effective choice for handling highly abrasive or corrosive fluids. For such applications, alternative pump technologies that are specifically designed to handle abrasive or corrosive fluids should be considered to ensure optimal performance, longevity, and reliability.

gear pump

How does a gear pump differ from other types of pumps?

A gear pump differs from other types of pumps in several ways. Here’s a detailed explanation of the differences:

1. Operating Principle:

A gear pump operates based on the principle of positive displacement. It uses rotating gears to trap and transfer fluid, delivering a fixed volume of fluid for each revolution of the gears. In contrast, other types of pumps, such as centrifugal pumps, operate based on dynamic principles, using impellers or rotors to impart velocity and convert it into pressure to move the fluid.

2. Flow Characteristics:

Gear pumps provide a relatively constant and uniform flow rate, thanks to their positive displacement nature. The flow rate is directly proportional to the speed of the gears, making it easier to control and measure. In contrast, centrifugal pumps typically exhibit a nonlinear flow rate that varies with the pump’s head (pressure) and system resistance.

3. Pressure Capability:

Gear pumps generally have lower pressure capabilities compared to centrifugal pumps. They are more suitable for applications with moderate pressure requirements. Centrifugal pumps, on the other hand, can handle higher pressures by efficiently converting velocity into pressure using the impeller.

4. Viscosity Range:

Gear pumps are well-suited for a wide range of fluid viscosities, making them versatile for handling both low-viscosity and higher-viscosity fluids. They can handle fluids with viscosities ranging from thin liquids to thicker oils. Centrifugal pumps are generally more effective at moving low-viscosity fluids efficiently.

5. Efficiency:

Gear pumps tend to have higher efficiencies at lower flow rates and higher pressures. They are more efficient in applications where there is a need for precise flow control. Centrifugal pumps, on the other hand, are more efficient at higher flow rates and lower pressures.

6. Size and Compactness:

Gear pumps are relatively compact and have a simple design, consisting of fewer components compared to centrifugal pumps. This makes them suitable for applications with space constraints or where portability is important. Centrifugal pumps tend to be larger and more complex due to the impeller design and the need for additional components like volutes or diffusers.

7. Noise and Vibration:

Gear pumps can generate more noise and vibration compared to centrifugal pumps. The meshing action of the gears can produce sound and mechanical vibrations. Centrifugal pumps, especially those with well-balanced impellers, generally operate with less noise and vibration.

8. Applications:

Due to their positive displacement nature and ability to handle a wide range of viscosities, gear pumps are commonly used in applications such as hydraulic systems, lubrication systems, fuel transfer, chemical processing, and metering applications. Centrifugal pumps find extensive use in applications like water supply, irrigation, HVAC systems, wastewater treatment, and industrial processes.

It’s important to consider these differences when selecting a pump for a specific application, as each pump type has its strengths and limitations. Factors such as desired flow rate, pressure requirements, fluid characteristics, and system design considerations play a significant role in determining the most suitable pump type.

China Custom CNC Horizontal Gear Hobbing Machine CZPT Cutting Machine with Good Price gear boxChina Custom CNC Horizontal Gear Hobbing Machine CZPT Cutting Machine with Good Price gear box
editor by Dream 2024-05-14

gear pump

As one of leading gear pump manufacturers, suppliers and exporters of products, We offer gear pump and many other products.

Please contact us for details.

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