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Unlocking the Secrets to Selecting the Perfect Hydraulic Pump! ( Part 2 )

Unlocking the Secrets to Selecting the Perfect Hydraulic Pump!  ( Part 2 )

Considerations and Features

When selecting a hydraulic pump, various factors must be taken into account, including power, noise levels, maximum pressure, and more. It is essential to assess your specific requirements and the intended operation of the pump. The following features merit consideration during your purchasing decision:

1.Hydraulic Fluid Viscosity

Hydraulic fluid viscosity is a crucial factor that determines the thickness and flow characteristics of the liquid within your hydraulic pump. The viscosity level plays a significant role in optimising the performance of hydraulic systems and selecting the appropriate pump for your application. Each hydraulic pump is designed with a specific maximum kinematic viscosity rating, which serves as a guideline to ensure optimal operation.

It is essential to adhere to this viscosity rating, as using a fluid that is too low in viscosity can lead to a decline in the pump’s efficiency while simultaneously increasing wear on the system components. Conversely, a fluid with excessive viscosity can hinder performance, resulting in decreased efficiency and potential mechanical complications.

In conclusion, understanding and managing hydraulic fluid viscosity is vital for maintaining the longevity and effectiveness of your hydraulic systems. Always consult the manufacturer's specifications to ensure you are using the right fluid for your pump to achieve peak performance.

 

2.Fluid Type

When selecting the appropriate fluid for your hydraulic system, it is crucial to ensure compatibility with the specifications of the pump in use. Generally, most hydraulic pumps function optimally with standard hydraulic fluid, which is predominantly based on mineral oil. This type of fluid is known for its excellent lubrication properties and possesses a boiling point that is significantly higher than that of water. However, there are various specialised fluids available for specific applications, including:

- Biodegradable Fluids: In environmentally sensitive operations, biodegradable hydraulic fluids are often preferred to mitigate the potential risks associated with spills. These fluids are typically derived from natural sources, such as soybean, sunflower, and rapeseed oils. They are characterised by high lubricity and inherent anticorrosive properties. Nevertheless, it is important to note that these fluids may oxidise rapidly and are susceptible to contamination by water. Alternative biodegradable options exist that address some of these limitations but may necessitate specific system requirements. Applications such as agricultural machinery and marine operations frequently require the use of biodegradable fluids.

- Phosphate Ester Fluids: This category of synthetic fluid is renowned for its exceptional thermal stability, lubrication, and antiwear characteristics. Phosphate esters are primarily employed in high-temperature environments where fire hazards are a concern. They feature elevated ignition temperatures, minimal oxidation, and low combustion heat, making them challenging to ignite and capable of self-extinguishing. However, it is essential to recognise that these fluids have lower viscosity and may exhibit chemical aggressiveness towards certain seals and coatings, leading to potentially higher maintenance costs for the associated systems.

- Water Glycol Fluids: Another viable option for fire resistance is the water glycol fluid, which is particularly beneficial in applications where fire risk is a significant factor. This fluid comprises a mixture of water, a high molecular weight polyglycol, and either ethylene or diethylene glycol, along with a package of additives. Typically, water glycol fluids contain 38-45% water. The additives incorporated into these fluids confer properties such as corrosion resistance, oxidation resistance, and antiwear capabilities.

It is imperative to understand that these fluids are not universally compatible with all pumps. Therefore, identifying a fluid that aligns with your operational requirements is essential for selecting the most suitable industrial hydraulic pump for your needs.

 

3. Flow Rate

The flow rate is a crucial parameter in assessing pump performance, and it is determined by several key factors:

- Pump speed, measured in revolutions per minute (RPM), indicates how fast the pump operates.

- Pump efficiency, expressed as a percentage, reflects the effectiveness of the pump in converting input power into hydraulic energy.

- Displacement value, which refers to the volume of fluid the pump can move with each cycle.

Typically, pumps are rated for maximum flow in gallons per minute (GPM) or litres per minute (LPM). These ratings are essential as they provide insight into the pump’s capability to handle specific fluid transfer tasks, ensuring it aligns with your operational requirements. Understanding the flow rate will enable you to select a pump that meets your needs effectively.

 

4.  Power Curves/Torque Ratings

Understanding the intricacies of power curves and torque ratings is essential when selecting the right pump for your specific needs. Let’s delve into the key aspects that will aid in your decision-making process.

Power is determined by the interplay between torque and rotational speed. Torque is a fundamental factor in assessing your power requirements. To simplify the selection of the appropriate torque, it is advisable to compare the new pump with an existing machine that performs a similar function. Evaluate the additional workload expected from the new pump and multiply it by the torque rating of the existing machine. In cases where no comparable machine is available, you will need to undertake calculations to determine the required torque.

Power curves serve as a valuable tool in this selection process, providing a visual representation of how power requirements fluctuate with varying specifications. These curves illustrate the power demands of the pump at different flow rates, enabling you to make informed choices based on your operational requirements.

It is crucial to note that there are distinctions between gasoline engines and electric motors, particularly concerning the torque-speed curve of internal combustion engines. Hydraulic pumps powered by gasoline engines generally necessitate a higher power capacity compared to those driven by electric motors. This difference underscores the importance of carefully considering the type of motor when assessing torque and power needs for your pump.

By understanding these dynamics, you can ensure that you select a pump that not only meets your requirements but also operates efficiently within your system.

 

5. Speed

The operating speed of a driveshaft is measured in revolutions per minute (RPM). Variations in design can result in differing operating speeds, with some configurations providing enhanced speed capabilities while others may operate at lower speeds.

 

6. Max Operating Pressure

When considering the performance of pumps, it's essential to understand the concept of maximum operating pressure. This critical parameter is typically expressed in bars or pounds per square inch (PSI). It’s important to note that pumps do not generate pressure themselves; rather, the pressure is a result of the load applied to the fluid being moved.

As the load increases, so does the pressure at the outlet, which ultimately defines the maximum pressure the pump can handle. This rating is crucial as it indicates the threshold beyond which the pump may experience leakage or damage to its components.

The maximum operating pressure can significantly differ across various pump designs, reflecting the unique engineering and materials used in their construction. Understanding this specification is vital for ensuring the pump's reliability and longevity in its intended application.

 

7. Fixed Displacement Vs. Variable Displacement

When considering hydraulic pumps, one encounters two primary configurations: fixed displacement and variable displacement. Understanding the distinctions between these two types is essential for selecting the appropriate pump for specific applications, as they differ fundamentally in their fluid displacement capabilities.

A fixed displacement pump operates on a straightforward principle. With each cycle, it consistently moves the same volume of fluid, making it ideal for tasks that require a uniform flow rate. This predictability is particularly advantageous in applications where the pump is tasked with performing the same operation repeatedly, such as in assembly lines or machinery that require steady hydraulic power.

On the other hand, variable displacement pumps introduce a layer of complexity and versatility. These pumps can adjust their displacement based on operational demands, allowing for changes in flow rate and outlet pressure. This adaptability makes variable displacement pumps suitable for a broader range of tools and projects, particularly those that require varying levels of hydraulic power at different stages of operation.

 

8. Maintenance Time and Costs

When considering the acquisition of a new hydraulic pump, it is essential to account for maintenance requirements and associated costs. Effective maintenance can significantly enhance the longevity and performance of your pump.

Variable displacement pumps typically incur higher maintenance expenses due to their intricate design. Conversely, some pumps possess features that enable better adaptability to wear. For instance, vane pumps are known for their reliability, as the vanes extend as needed when the casing experiences wear. External gear pumps are recognised for their durability, while internal gear pumps may lead to increased costs. Axial and bent-axis piston pumps, though more complex to repair, generally offer extended service life.

 

Popular Hydraulic Pump

 

1. Hydraulic Pump for John Deere

Hydraulic Pump AM875160 Fits for John Deere Compact Utility Tractor 655 755 756 855 856

Replace Part Number:
AM875160, GP1-C-5CH

Applications:
Fit For John Deere Compact Utility Tractor: 655, 755, 756, 855, 856

Hydraulic Pump AM875160, a precision-engineered component designed specifically for John Deere Compact Utility Tractors, including the 655, 755, 756, 855, and 856 models. This hydraulic pump plays a crucial role in ensuring optimal performance, delivering reliable power to your tractor's hydraulic system.

 

2. Hydraulic Pump for Volvo

Hydraulic Pump VOE14531853 14531853 for Volvo EC135B Excavator

Part Number: VOE 14531853, VOE14531853, 14531853

Applications: Volvo Excavator: EC135B

Hydraulic Pump VOE14531853, specifically designed for the Volvo EC135B Excavator. This essential component ensures optimal performance and reliability, making it a crucial addition for those who demand excellence in their machinery.

 

3. Hydraulic Pump for Komatsu

Hydraulic Pump 705-52-31070 Fits for Komatsu Engine SAA6D140E-3 Excavator PC750-6 PC750-7 PC800-6 PC800-7

Part number: 705-52-31070, 7055231070

Fit for Komatsu Engine: SAA6D140E, SAA6D140E-3, SAA6D140E-3 (TIER 2)

Applications: Fit for Komatsu Excavator: PC750-6, PC750-6-AM, PC750-7, PC750-7-M1, PC750LC-6, PC750LC-6K-01, PC750LC-7, PC750LC-7K, PC750SE-6, PC750SE-6-AM, PC750SE-6K, PC750SE-6K-01, PC750SE-6K-J, PC750SE-6K-LS, PC750SE-7, PC750SE-7K, PC750SE-7-M1, PC800-6, PC800-6-AM, PC800-7, PC800-7-M1, PC800SE-6, PC800SE-6-AM, PC800SE-7, PC800SE-7-M1

Hydraulic Pump 705-52-31070, the perfect fit for your Komatsu Excavator powered by the SAA6D140E-3 engine. This high-performance pump is expertly designed to enhance the efficiency and power of your machinery, ensuring you tackle the toughest jobs with ease.

 

4.  Hydraulic Pump for Hyundai

Hydraulic Pump 31N8-10010 31N810010 K3V140DT Fits For Hyundai 290 LC-7 R290LC7

Condition: new, aftermarket

Part Number: 31N8-10010, 31N810010, K3V140DT

Applications: Fits for Hyundai 290 LC-7, R290LC7

Hydraulic Pump 31N8-10010, a premium component designed to fit seamlessly with the Hyundai 290 LC-7 (R290LC7). This high-performance pump is engineered for reliability and efficiency, ensuring optimal operation for your machinery.

 

FAB Heavy Parts  Can Help With Your Needs

Welcome to Fab Heavy Parts' online catalog, where you can explore a delightful array of hydraulic pump.  We have a diverse selection to cater to your needs. Our knowledgeable parts team is at your disposal, ready to assist you every step of the way.

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