General Components of Centrifugal Pumps

A centrifugal pump has two main components:
I. A rotating component comprised of an impeller and a shaft
II. A stationary component comprised of a casing, casing cover, and bearings.
The general components, both stationary and rotary, are depicted in Figure B.01.
The main components are discussed in brief below. Figure B.02 shows these parts on a
photograph of a pump in the field.

Conversion of Kinetic Energy to Pressure Energy

The key idea is that the energy created by the centrifugal force is kinetic energy.
The amount of energy given to the liquid is proportional to the velocity at the edge or
vane tip of the impeller. The faster the impeller revolves or the bigger the impeller is,
then the higher will be the velocity of the liquid at the vane tip and the greater the energy
imparted to the liquid.
This kinetic energy of a liquid coming out of an impeller is harnessed by creating
a resistance to the flow. The first resistance is created by the pump volute (casing) that
catches the liquid and slows it down. In the discharge nozzle, the liquid further
decelerates and its velocity is converted to pressure according to Bernoulli’s principle.
Therefore, the head (pressure in terms of height of liquid) developed is
approximately equal to the velocity energy at the periphery of the impeller expressed by
the following well-known formula:

This head can also be calculated from the readings on the pressure gauges
attached to the suction and discharge lines.
Pump curves relate flow rate and pressure (head)
developed by the pump at different impeller sizes
and rotational speeds. The centrifugal pump
operation should conform to the pump curves
supplied by the manufacturer. In order to read
and understand the pump curves, it is very
important to develop a clear understanding of the
terms used in the curves. This topic will be
covered later.

Generation of Centrifugal Force

The process liquid enters the suction nozzle and then into eye (center) of a
revolving device known as an impeller. When the impeller rotates, it spins the liquid
sitting in the cavities between the vanes outward and provides centrifugal acceleration.
As liquid leaves the eye of the impeller a low-pressure area is created causing more liquid to
flow toward the inlet. Because the impeller blades are curved, the fluid is pushed in a
tangential and radial direction by the centrifugal force. This force acting inside the pump
is the same one that keeps water inside a bucket that is rotating at the end of a string.
Figure A.01 below depicts a side cross-section of a centrifugal pump indicating the
movement of the liquid.

Working Mechanism of a Centrifugal Pump

A centrifugal pump is one of the simplest pieces of equipment in any process
plant. Its purpose is to convert energy of a prime mover (a electric motor or turbine) first
into velocity or kinetic energy and then into pressure energy of a fluid that is being
pumped. The energy changes occur by virtue of two main parts of the pump, the impeller
and the volute or diffuser. The impeller is the rotating part that converts driver energy into
the kinetic energy. The volute or diffuser is the stationary part that converts the kinetic
energy into pressure energy.
Note: All of the forms of energy involved in a liquid flow system are expressed in
terms of feet of liquid i.e. head.

problems mostly encountered with centrifugal pumps:

The fact of the matter is that there are three types of problems mostly encountered
with centrifugal pumps:
design errors
poor operation
poor maintenance practices
The present article is being presented in three parts, covering all aspects of operation,
maintenance, and troubleshooting of centrifugal pumps. The article has been written keeping
in mind the level and interests of students and the beginners in operation. Any comments or
queries are most welcome.

chemical engineering background importance

Any operating engineer, who typically has a chemical engineering background and
who desires to protect his pumps from frequent failures must develop not only a good
understanding of the process but also thorough knowledge of the mechanics of the pump.
Effective troubleshooting requires an ability to observe changes in performance over time,
and in the event of a failure, the capacity to thoroughly investigate the cause of the failure
and take measures to prevent the problem from re-occurring

Centrifugal Pumps: Basic Concepts

The list of pump failure conditions mentioned above is neither exhaustive nor are the
conditions mutually exclusive. Often the root causes of failure are the same but the
symptoms are different. A little care when first symptoms of a problem appear can save the
pumps from permanent failures. Thus the most important task in such situations is to find
out whether the pump has failed mechanically or if there is some process deficiency, or
both. Many times when the pumps are sent to the workshop, the maintenance people do not
find anything wrong on disassembling it. Thus the decision to pull a pump out of service for
maintenance / repair should be made after a detailed analysis of the symptoms and root
causes of the pump failure. Also, in case of any mechanical failure or physical damage of
pump internals, the operating engineer should be able to relate the failure to the process
unit’s operating problems

centrifugal pump Intro

The operating manual of any centrifugal pump often starts with a general statement,
“Your centrifugal pump will give you completely trouble free and satisfactory service only
on the condition that it is installed and operated with due care and is properly maintained.”
Despite all the care in operation and maintenance, engineers often face the statement
“the pump has failed i.e. it can no longer be kept in service”. Inability to deliver the desired
flow and head is just one of the most common conditions for taking a pump out of service.
There are other many conditions in which a pump, despite suffering no loss in flow or head,
is considered to have failed and has to be pulled out of service as soon as possible. These
include seal related problems (leakages, loss of flushing, cooling, quenching systems, etc),
pump and motor bearings related problems (loss of lubrication, cooling, contamination of
oil, abnormal noise, etc), leakages from pump casing, very high noise and vibration levels,
or driver (motor or turbine) related problems.