difference between centrifugal and reciprocating pump|indicator diagram of reciprocating pump : trader When we talk about pumps first definition that comes to mind is that it delivers water or other liquid from one place to another place. A pump is a device that is used for lifting the liquid from the ground surface and delivering it to the topmost upper surface. The pump converts mechanical energy into hydraulic … See more How Degassing Vacuum Pump Work. Degassing of a liquid is achieved by exposing the largest possible surface area of the liquid to a vacuum or low pressure environment. Typical CDP vacuum ranges are 50 to 0.01 mbar, (40 – 0.0075 Torr) Vacuum degassing can greatly reduce capital costs in low pressure processes.
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When it comes to pumping systems, two common types of pumps are often used: centrifugal pumps and reciprocating pumps. Each type has its own set of advantages and disadvantages, making them suitable for different applications. In this article, we will explore the key differences between centrifugal pumps and reciprocating pumps across various categories.
When we talk about pumps first definition that comes to mind is that it delivers water or other liquid from one place to another place. A pump is a device that is used for lifting the liquid from the ground surface and delivering it to the topmost upper surface. The pump converts mechanical energy into hydraulic
Positive Displacement Pumps Diagram
1. **Centrifugal Pump**: Centrifugal pumps are dynamic pumps that work on the principle of centrifugal force to transfer fluid. They have a simple design with fewer moving parts.
2. **Reciprocating Pump**: Reciprocating pumps are positive displacement pumps that use a piston or diaphragm to displace a specific volume of fluid with each stroke.
Centrifugal Pump vs Reciprocating Pump
3. **Efficiency**: Centrifugal pumps are more efficient in transferring large volumes of fluid at high flow rates, while reciprocating pumps are better suited for high-pressure applications with lower flow rates.
4. **Maintenance**: Centrifugal pumps require less maintenance due to their simpler design, whereas reciprocating pumps need regular maintenance to ensure proper functioning of pistons and valves.
5. **Cost**: Centrifugal pumps are generally more cost-effective for handling large volumes of fluid, while reciprocating pumps are preferred for applications where precise control and high pressure are required.
Indicator Diagram of Reciprocating Pump
6. **Reciprocating pumps produce an indicator diagram that shows the pressure variations during the pumping cycle. This diagram helps in analyzing the performance and efficiency of the pump.
Single Acting Reciprocating Pump Working
7. **In a single-acting reciprocating pump, the piston moves in only one direction, either up or down, to displace the fluid. This design is simpler and more economical compared to double-acting reciprocating pumps.
Characteristic Curve of Reciprocating Pump
8. **The characteristic curve of a reciprocating pump shows the relationship between the flow rate and the discharge pressure. It helps in determining the operating range and efficiency of the pump.
Characteristics of Reciprocating Pump
9. **Reciprocating pumps are known for their high efficiency and ability to handle high-pressure applications. They are commonly used in industries such as oil and gas, chemical processing, and water treatment.
API 675 vs 674
10. **API 675 and API 674 are standards set by the American Petroleum Institute for reciprocating pumps used in the oil and gas industry. These standards define the design, construction, and performance requirements for such pumps.
Reciprocating Pump Calculation
11. **Calculating the performance of a reciprocating pump involves factors such as piston diameter, stroke length, speed of operation, and fluid properties. These calculations help in determining the pump's efficiency and capacity.
12. **Flow Rate**: Centrifugal pumps have a relatively constant flow rate, while reciprocating pumps can provide variable flow rates based on the speed and stroke length.
13. **Pressure Handling**: Reciprocating pumps are better suited for handling high-pressure applications, while centrifugal pumps are more suitable for low to moderate pressure systems.
14. **Noise Level**: Reciprocating pumps tend to produce more noise during operation compared to centrifugal pumps, which operate more quietly.
15. **Size and Weight**: Centrifugal pumps are typically smaller and lighter than reciprocating pumps, making them easier to install and transport.
16. **Suction Lift**: Centrifugal pumps are better at handling suction lift applications, where the pump is located above the fluid level, compared to reciprocating pumps.
17. **Cavitation**: Centrifugal pumps are more prone to cavitation, a phenomenon that can damage the pump and reduce efficiency, while reciprocating pumps are less susceptible to cavitation.
18. **Viscosity Handling**: Reciprocating pumps are better at handling high-viscosity fluids compared to centrifugal pumps, which are more suitable for low-viscosity liquids.
19. **Control**: Centrifugal pumps offer limited control over flow rate and pressure, while reciprocating pumps allow for precise control and adjustment of these parameters.
It is a positive displacement type pump where a certain volume of liquid is entered in closed volume and discharged using pressure to the
Vacuum degassing Vacuum degassing is an important secondary steel making process. This process was originally used . The vacuum chamber is equipped with a hopper so as to make additions of elements as and when it is needed. For effective degassing of fully killed steel, it is necessary to purge argon through the bottom of the ladle. .
difference between centrifugal and reciprocating pump|indicator diagram of reciprocating pump