Energy-Efficient Motors Motors

Energy-Efficient Motors

Efficiency is an important factor to consider when buying or rewinding an electric motor. This Technical Brief answers some frequently asked questions about how to obtain the most efficient motor at the lowest price while avoiding some common problems.
More


Energy Savings by means of Energy Efficient Electric Motors
Abstract
The electric motors consume a significant amount of
electricity in the industrial and in the tertiary sectors of
the European Union. Because of its simplicity and
robustness the three-phase squirrel-cage induction motor
is the prime mover of the modern industry. The electricmotor
manufacturers are seeking methods for improving
the motor efficiencies, which resulted in a new
generation of electric motors that are known as energyefficient
motors.

This paper deals with energy conservation by
installing energy efficient motor (EEM) instead of
standard efficiency motor. This transition becomes a
necessity as a direct result of limitation in energy sources
and escalating energy prices. In the end of this analysis,
there are different practical cases in where EEM is
compared with standard motors and rewound motor. In
all these cases energy savings can be achieved and the
simple payback is less of five years. So, it is very
interesting the implementation of EEM in the industry.

more

A Novel Analysis of Energy Efficiency Motors and Power Controllers

Author: s.sankar

A novel analysis of energy efficiency motors and power controllers

Voltage Control

Voltage alone can be used as a source of intelligence when the switched capacitors are applied at point where the circuit voltage decreases as circuit load increases. Generally, where they are applied the voltage should decrease as circuit load increases and the drop in voltage should be around 4 – 5 % with increasing load.

Voltage is the most common type of intelligence used in substation applications, when maintaining a particular voltage is of prime importance. This type of control is independent of load cycle. During light load time and low source voltage, this may give leading PF at the substation, which is to be taken note of. KILOVAR Control

Automatic Power Factor Control Relay

It controls the power factor of the installation by giving signals to switch on or off power factor correction capacitors. Relay is the brain of control circuit and needs contactors of appropriate rating for switching on/off the capacitors.

There is a built-in power factor transducer, which measures the power factor of the installation and converts it to a DC voltage of appropriate polarity. This is compared with a reference voltage, which can be set by means of a knob calibrated in terms of power factor.

When the power factor falls below setting, the capacitors are switched on in sequence. The relays are provided with First in First out (FIFO) and First in Last Out (FILO) sequence. The capacitors controlled by the relay must be of the same rating and they are switched on/off in linear sequence. To prevent over correction hunting, a dead band is provided. This setting determines the range of phase angle over which the relay does not respond; only when the PF goes beyond this range, the relay acts. When the load is low, the effect of the capacitors is more pronounced and may lead to hunting. Under current blocking (low current cut out) shuts off the relay, switching off all capacitors one by one in sequence, when load current is below setting. Special timing sequences ensure that capacitors are fully discharged before they are switched in. This avoids dangerous over voltage transient. The solid state indicating lamps (LEDS) display various functions that the operator should know and also and indicate each capacitor switching stage.

Intelligent Power Factor Controller (IPFC)

This controller determines the rating of capacitance connected in each step during the first hour of its operation and stores them in memory. Based on this measurement, the IPFC switches on the most appropriate steps, thus eliminating the hunting problems normally associated with capacitor switching.

Energy Efficient Motors
Minimising Watts Loss in Motors

Improvements in motor efficiency can be achieved without compromising motor performance - at higher cost - within the limits of existing design and manufacturing technology.

From the Table .1, it can be seen that any improvement in motor efficiency must result from reducing the Watts losses. In terms of the existing state of electric motor technology, a reduction in watts losses can be achieved in various ways.

All of these changes to reduce motor losses are possible with existing motor design and manufacturing technology. They would, however, require additional materials and/or the use of higher quality materials and improved manufacturing processes resulting in increased motor cost.

Energy Efficient Motor

Table 1

Thus energy-efficient electric motors reduce energy losses through improved design, better materials, and improved manufacturing techniques. Replacing a motor may be justifiable solely on the electricity cost savings derived from an energy-efficient replacement. This is true if the motor runs continuously, power rates are high, the motor is oversized for the application, or its nominal efficiency has been reduced by damage or previous rewinds. Efficiency comparison for standard and high efficiency motors is shown in Figure 2.

Fig.2

Technical aspect of energy efficiency motors

Energy-efficient motors last longer, and may require less maintenance. At lower temperatures, bearing grease lasts longer; required time between re-greasing increases. Lower temperatures translate to long lasting insulation. Generally, motor life doubles for each 10°C reduction in operating temperature.

Select energy-efficient motors with a 1.15 service factor, and design for operation at 85% of the rated motor load.

Electrical power problems, especially poor incoming power quality can affect the operation of energy-efficient motors.

Speed control is crucial in some applications. In polyphase induction motors, slip is a measure of motor winding losses. The lower the slip, the higher the efficiency. Less slippage in energy efficient motors results in speeds about 1% faster than in standard counterparts.

Starting torque for efficient motors may be lower than for standard motors. Facility managers should be careful when applying efficient motors to high torque applications.

Soft Starter

When starting, AC Induction motor develops more torque than is required at full speed. This stress is transferred to the mechanical transmission system resulting in excessive wear and premature failure of chains, belts, gears, mechanical seals, etc. Additionally, rapid acceleration also has a massive impact on electricity supply charges with high inrush currents drawing +600% of the normal run current.

Soft Starter

The use of Star Delta only provides a partial solution to the problem. Should the motor slow down during the transition period, the high peaks can be repeated and can even exceed direct on line current. Soft starter (see Figure 10.5) provides a reliable and economical solution to these problems by delivering a controlled release of power to the motor, thereby providing smooth, stepless acceleration and deceleration. Motor life will be extended as damage to windings and bearings is reduced. Soft Start & Soft Stop is built into 3 phase units, providing controlled starting and stopping with a selection of ramp times and current limit settings to suit all applications

Soft Starter: Starting current, Stress profile during starting

Advantages of Soft Start –

Less mechanical stress

Improved power factor

Lower maximum demand

Less mechanical maintenance

About the Author:

Assistant professor in lord venkateswara engineering college.I am doing phd in sathyabama university, Tamil Nadu,India.

Article Source: http://www.articlesbase.com/electronics-articles/a-novel-analysis-of-energy-efficiency-motors-and-power-controllers-770964.html

What is an Energy-Efficient Motor?

Motor efficiency is the ratio of mechanical power output to the electrical power input, usually expressed as a percentage. Energy-efficient motors use less energy. Because they are manufactured with higher quality materials and techniques, they usually have higher service factors and bearing lives, less waste heat output, and less vibration, all of which increase reliability. This is often reflected by longer manufacturer’s warranties.
To be considered energy-efficient, a motor’s performance must equal or exceed the nominal full-load efficiency values provided by the National Electrical Manufacturer’s Association (NEMA) in their publication MG-1. The Energy Policy Act of 1992 (EPACT) required most general purpose motors between 1 and 200 horsepower for sale in the U.S. to meet these NEMA standards by October 24, 1997.

What Efficiency Value Should I Use?
When comparing two motors, be sure to use a consistent measure of efficiency. "Nominal" efficiency is best. This value is obtained through standardized testing. "Minimum" or "guaranteed" efficiency is slightly lower to take into account typical variations in efficiency within a population of motors.

When Should I Consider an Energy-Efficient Motor?
Assuming 6 cents per kWh electricity cost and a payback criteria of 2 years, most motors should be replaced with an energy-efficient model if they operate over 4,000 hours per year. In general, energy-efficient motors should be considered in the following circumstances:
New installations, both separate and as part of packages such as HVAC systems
When major modifications are made to a facility or a process
Instead of rewinding older, standard-efficiency motors
As part of a preventive maintenance or energy conservation plan
More

AC Motor Calculation

AC Motor Calculation

Calculate the Full Load Current of AC Motor

INDUCTION MOTORS ANALYSIS

Equivalent circuits of three-phase induction motor

Estimation of Induction Motor Parameters

Estimation of Induction Motor Parameters Program

Power and Efficiency

Power flow in an Induction motor

Losses and Efficiency of Induction Motor

Program

Calculation Equivalent of induction motors program

Losses and Efficiency of Induction Motor

A. Definition of energy efficiency

Efficiency is the ratio of mechanical energy output divided by
the electrical energy input. There are different efficiency definitions
that describe the relationship between a motor’s rating and
efficiency test results:

- Tested. This refers to the efficiency measured by testing that
specific motor.

- Nominal or Average Expected. Nominal values are the average
values obtained after testing a sample population of the motor model.

- Nameplate. This refers to the efficiency measured by a specific
standard.

- Minimum. These values are intended to represent the lowest point in
the bell curve of motor efficiency distribution.

- Apparent Efficiency. This is the product of a motor’s efficiency and
power factor.

Figure 2.1 – Typical energy flow of standard motors

B. Motor Losses
Energy losses are the determining factor in motor
efficiency. These losses can be divided in five classes:

Classes of Motor Energy Losses

The main difference between the standards emerges
from the way in which the additional load losses, is
treated. The IEC 34.2 standard assumes a standard value
for the additional load losses at rated load of 0.5% of the
input power. The new proposed IEC 61972 standard
gives two possibilities for the assessment of the
additional losses. The first one is a determination by
means of the measured output power, as in the IEEE 112-
B; the second one gives a fixed amount to every machine
of the same rated power. The Japanese JEC standard 37
completely neglects the additional load losses.

Source
http://www.icrepq.com/icrepq-08/352-mantilla.pdf

Paper

Genetic Algorithms in Induction Motor Efficiency

Determination

Many current techniques of calculating induction motor efficiency

are difficult, expensive, or inaccurate in the field. Induction motors

consume a large percentage of the electricity used in the US.

Accurate calculations of the efficiency of these motors would allow

savings in both energy and cost. One major obstacle in the

calculation of efficiency is that it is often difficult to measure the

output power accurately and safely while the motor is running,

say in a factory. It would be of interest to find a way to estimate

the output power using only easily measured quantities, such as

input current and voltage.

More

Effective Estimation of Induction Motor Field Efficiency

Based on On-site Measurements
ABSTRACT
This paper proposes the effective technique for
estimating efficiency of existing three-phase induction
motors in the field. This technique focuses on the
operating efficiency of motors without the need for
removing the motors and without the need for measuring
the output power or torque. This paper describes the use
of a few sets of data (voltage, current, power, speed)
measured from the motor (on-site) coupled with the
genetic algorithms for evaluating the motor parameters
instead of using the no-load and blocked rotor test results.
Once these parameters are known it is possible to obtain
the estimated efficiency of the motor. To illustrate how
well the estimated efficiency match that of the calculated
obtained from the standard evaluations, the results of
various induction motors rating 10 up to 100 hp are
presented. Test results indicate that this proposed
technique has a high accuracy, and then it could be
suitable for conducting on-site energy audits of existing
motors in order to support a decision to replace operating
motors with a higher-efficiency model.

more pdf

Power flow in an Induction motor

The exact equivalent circuit model of an Induction motor is

where

R1 is the stator resistance per phase

X1 is the stator reactance per phase

R2' is the equivalent rotor resistance referred to stator per phase

X2' is the equivalent rotor reactance referred to stator per phase

Rc is the resistance representing core losses

Xm is the magnetizing reactance per phase

V1 is the per phasesupply voltage to the stator
s is the slip of the motor

Power flow in an Induction motor

From the circuit, we see that the total power input to the rotor Pg is
The power flow diagram is-

Source
http://powerlearn.ece.vt.edu/modules/PE2/index.html

How the efficiency of induction motor is measured?

Abstract
The efficiency is of paramount importance nowadays due
to increasing electrical energy demand, increasing awareness of
environmental problems as greenhouse effects and increasing
fossil fuel prices.

This paper tries to show the different results between the
standards for efficiency evaluation and the necessity of
harmonization worldwide. Then, it is going to be explained the
different standards for measurement of efficiency, and the main
differences between the standards (IEEE 112, IEC 60034-2 and
JEC-37).

To complete this study, it is going to be described the steps
in order to estimate efficiency on the jobsite and expressed the
different efficiency labels motors.

Figure 2.1 – Typical Power flow of standard motors

More pdf