Centrifugal pumps are one of the most commonly used types in industry today. They transport fluid by converting rotational kinetic energy to the fluid’s hydrodynamic energy. This energy typically comes from an engine or electric motor.
These pumps move fluid by transferring rotational energy from one or more driven rotors called impellers. Well, in this reading, we’ll explore what a centrifugal pump is, its applications functions, parts, diagram, classification types, and how it works. We’ll also explore its advantages and disadvantages.
Let’s get started!
What is a Centrifugal Pump?
A centrifugal pump is a mechanical device that is designed to transport fluid. This is achieved by transferring rotational energy from one or more driven rotors called impellers. In the working, the fluid enters a rapidly rotating impeller along its axis.
This fluid then expells by centrifugal force along the circumference of the blade tips of the impeller. The action of this impeller increases the speed and pressure of the liquid which also directs it to the pump outlet.
Centrifugal pumps are a sub-class of dynamic axisymmetric work-absorbing turbomachinery. Fluid enters the rotating impeller along its axis and it is cast out by centrifugal force along its circumference through the impeller’s vane tips. The effectiveness of the impeller increases the fluid’s velocity and pressure which also directs it toward the pump outlet.
In the design of a centrifugal pump, the casing is capable of constricting fluid from the pump inlet. It will direct it into the impeller and then slow and control the fluid before discharging.
The first machine considered a centrifugal pump was designed for lifting mud. It appeared in early 1475 in a treatise by the Italian Renaissance engineer. The true centrifugal pump was developed in the late 17th century when Denis Papin built one using straight vanes.
In 1851 John Appold who was a British inventor introduced the curved vane version. This is a brief history of a centrifugal pump.
The function of a centrifugal pump is specified for higher flows and pumping of lower-viscosity liquids. It does this down to 0.1 cP. in most chemical
Applications of Centrifugal Pump
In most chemical plants, 90% of pumps used are centrifugal pumps. Although there is a number of applications for which positive displacement pumps are preferred. Below are some applications of centrifugal pumps.
- Centrifugal pump is often used in oil and energy factories. It is used for pumping crude oil, slurry, mud, etc. It is also used by refineries and power generation plants.
- The fire protection industry also makes good use of this pump in heating and ventilation, and boiler feed applications. it is used in pressure boosting, and fire protection sprinkler systems.
- Applications of a centrifugal pump are vast in waste management, agriculture, and manufacturing. Wastewater processing plants, municipal industry, drainage, gas processing, irrigation, and flood protection.
- Pharmaceutical, chemical, and food industries also used this pump. It works on paints, hydrocarbons, petrochemicals, sugar refining, food and beverage production, and cellulose.
- Finally, various industries including manufacturing, industrial, chemicals, pharmaceutical, food production, aerospace, etc. make use of centrifugal pumps for the purpose of cryogenics and refrigerants.
Related: What is a Pump? its Diagram and How it Works
Major components of Centrifugal Pump
Below are the major components of a centrifugal pump.
Impeller
The diagram below shows a full diagram of different impellers including Open, Semi Enclosed, and Enclosed Impeller. It is a wheel or rotor that is designed with a series of backward curved blades or vanes. It is mounted on a shaft that is powered by an external source of energy.
This external source imparts the liquid energy to the impeller which thereby makes it rotate.
Casing
The casing is another major part of a centrifugal pump. It is a pipe that is connected at the upper end to the inlet of the pump towards the center of the impeller. This part is also known as the eye. In double end reaction pump two suction pipe is connected to the eye from both sides. The liquid is lifted through the lower end as it’s dipped into it.
This lower end is fitted into the foot valve and strainer. The three types of casing commonly used in centrifugal pumps are volute casing, vortex casing, and casing with guide blades.
Delivery Pipe
A delivery pipe is mounted at the lower end of the outlet of the pump. It delivers the liquid to the required height. There is a valve close to the outlet of the pump on the delivery pipe. This valve controls the flow from the pump into the delivery pipe.
Suction Pipe with Foot Valve and Strainer
The suction pipe is connected with the inlet of the impeller while the other end is dipped into the source of liquid. At the end of the pipe, there is a foot valve and strainer. This foot valve is a one-way valve that opens in an upward direction. The strainer is used to filter the unwanted particles present in the liquid to prevent the centrifugal pump from blockage.
Centrifugal Pump Diagram
Classifications and Types of Centrifugal Pump
Below are the classifications of centrifugal pump and their types:
Classification based on the number of impellers in the pump:
- Single-stage pump
- Two-stage pump
- Multi-stage pump
Based on the orientation of case-split:
- Axial split Pump
- Radial split Pump
Based on the type of impeller design
- Single suction Pump
- Double suction Pump
Based on the type of volute
- Single volute Pump
- Double volute Pump
Based on where the bearing support
- Overhung
- Between-bearing
Based on shaft orientation
- Horizontal Pump
- Vertical Pump
Based on the basis compliance with industry standards
- ANSI pump – (American National Standards Institute)
- API pump – (American Petroleum Institute)
- DIN pump – DIN 24256 specifications
- ISO pump – ISO 2858, 5199 specifications
- Nuclear pump – ASME (American Society of Mechanical Engineers) specifications
How Does Centrifugal Pump Work?
Just as earlier mentioned, centrifugal pumps are used to induce flow or raise liquid from a low to a high level. Its working is very simple and can be easily understood because it has a very simple mechanism. A centrifugal pump converts rotational energy that often got its power from the motor. This energy is then used to move the fluid.
There are two important parts in the centrifugal pump responsible for the conversion of energy. These parts are the impeller and casing. The impeller was earlier explained as a rotating part of the pump and the airtight passage surrounding the impeller.
In the working of a centrifugal pump, fluid enters into the casing and then falls on the impeller blades. The fluid drops at the eye of the impeller. The impeller is powered whirled tangentially and radially outward until it leaves the impeller to the diffuser part of the casing. As the fluid passes through the impeller, it gains both pressure and velocity.
Factors That Affect the Performance of a Centrifugal Pump
The following are factors that can affect the performance of a centrifugal pump. These factors must be considered while selecting or choosing a centrifugal pump.
Working Fluid Viscosity
This can be defined as resistance to shear when energy is applied. Generally, centrifugal pumps are suitable for low-viscosity fluids because the pumping action creates high liquid shear.
Net Positive Suction Head (NPSH) and Cavitation
The term NPSH refers to the pressure of a fluid on the suction side of a pump. This helps to determine if the pressure is high enough to avoid cavitation. Cavitation is the formation of bubbles or cavities in a liquid, which are developed in areas of relatively low pressure around an impeller.
This can cause serious damage to the impeller and lead to decreased flow/pressure rates. The net positive suction head available (NPSHA) must be greater than the pump’s net positive suction head required (NPSHR).
Vapor Pressure of the Working Fluid
The word vapor pressure of the working fluid means the pressure at a given temperature. That is the pressure at which a fluid will change to a vapor. This must be determined so that cavitation must be avoided. Also, bearing damage is caused by dry running when the fluid has evaporated.
Operating Temperature and Pressure
This is another factor to be considered in pumping operations. For example, high-temperature pumping may require special gaskets, seals, and mounting designs. Also, a properly designed pressure-retaining casing may be needed for high-pressure conditions.
Specific Density and Gravity of Working Fluid
The density of a fluid is determined by its mass per unit of volume. So, a fluid’s mass per unit volume and gravity of a fluid is the ratio of a fluid’s density to the density of water. This directly affects the input power needed to pump a particular liquid.
When a centrifugal pump is to be used with a fluid other than water, one must consider the specific density and gravity. This is because the weight directly affects the amount of work performed by the pump.
Related: What Is Oil Pump? Its Types and How it Works
Advantages and Disadvantages of Centrifugal Pump
Advantages:
Below are the benefits of centrifugal pumps in their various applications.
- Centrifugal pumps work well with large volumes of fluid transfer – this is why it is often used for transferring water, chemicals, and light fuels. This is because a large amount is often transferred.
- Simplicity in design, working, and mechanism. The centrifugal pump does not require a valve and piston and their moving parts are minimal.
- Centrifugal pumps are comparatively compact. with this concept, the pump doesn’t take up a lot of space. I think this is one of the reasons centrifugal pump is widely used.
Disadvantages:
Despite the great advantages of centrifugal pumps, some limitations still occur. below are the disadvantages of centrifugal pumps in their various applications.
- The net positive suction head (NPSH) of the system is too low. This is known as cavitation.
- Wearing of the impeller, which can be worsened by suspended solids.
- Fluid properties can cause corrosion inside the pump.
- A low flow rate will cause overheating.
- Leakage along the rotating shaft.
- The centrifugal pump must be filled with fluid to pump in order to operate; else lack of prime occurs.
- Viscous fluid cannot be used
- Surge
- For a very high-head application, a centrifugal pump is not suitable.
Conclusion
Centrifugal pump is a great pump that is widely used today, it offers a variety of advantages even though some limitation still shows up. However, the pump is still the best choice for pumping in various fields. it works using a casing and impeller. In this article, we’ve examined the definition, applications, function, components, classifications, and types of centrifugal pumps. We’ve also examined the factors to be considered before choosing this pump. The advantages and disadvantages of the centrifugal pump were also discussed.