Motor Efficiency & improvement

Motor Efficiency & How to improve it?

Electric motor is a type of machine which converts electrical energy into mechanical energy using the interaction between magnetic field and current in its winding to produce/generate force in the motor. If we actually reverse this process then mechanical energy is converted into electrical energy and that is done by generators .Electromagnetism Is the main phenomenon that is used by motors.

Basic Parts of the Motor:

Coming to the parts of motors, major parts of motor are as follows

Rotor:
This is the moving and important part of the electric motor which rotate the shaft to produce mechanical energy.

Stator:
Stationary part of the motor is stator it either has few windings or has a fixed magnet. Its main core is made of multiple lamination or sheets of different metals to minimize the losses.

Air Gap: 
A minute gap between stator and rotor is called air gap. It is necessary to have gap between these two components but it is forced to be as small as it is possible otherwise will have adverse effects on motor Performance.

Commutator: 
It basically deals with the process of switching input to DC motor. It is comprised of slip rings that are insulated from each other and from shaft.

Basic Parts of the Motor

So there are multiple types of motors with their own importance.

Types of Motors and their Importance:

As you have seen now that there are many types of motors and we talk about our industries around 70% energy is used by these motors and a huge proportion this energy is wasted. By reducing this wastage, companies not only help the environment, but also cut their costs and improve profitability.

Self Commutated They can be Ac and Dc

Externally Commutated They are AC Motors

Mechanical Two types of motors present in this category which are ac and dc respectively .One is comprised of simple electronics other is Dc chopper or linear transistor.

ElectronicThey may have paramagnetic or ferromagnetic rotor.They have comprehensive use of electronics in it.

Asynchronous Three phase motors that has capacitors ,resistors split and shaded poles but they are not hybrid.

Synchronous They are three phase motors but they have permanent split capacitor and hysteresis and most importantly they are hybrid.

What is Motor Efficiency:

The ratio between motor Output and Input is called efficiency which is indicated by the symbol of “η” and represented in the “%”. or

This is the factor which tells about performance of the motor. It is the ratio between output and input power at shaft it can be written as efficiency (e) = output power / input power i.e.

Motor Efficiency = Motor _Eff = Motor Out Put Power / Motor Input Power

Motor efficiency is denoted by the symbol of eta= η.

Efficiency = η = (Output / Input) x 100

Or

Efficiency = η = Input – Losses / Input

Or

Efficiency = η = Output / Output + Losses.

There is no such a machine without losses. thus, the value of output of a machine is always less than the input. i.e.

Output = Input – Losses

In other words;

Input = Output + Losses

Therefore, we can write the efficiency formula as well.

Efficiency = η = Input – Losses / Input

Or

Efficiency = η = Output / Output + Losses.

Also read:

Transformer Losses

Condition for Maximum Efficiency of the Motor:

The motor efficiency would be maximum if Cu losses are equal to theconstant losses of the motor

Power Stages in DC Motors and their Efficiencies.

Losses occur during conversion of electrical energy into mechanical energy in electrical motor. These losses and conversion of energy in the motor is known as the power stages of a DC motor which is shown in the below diagram.

Explanation of Power stages and Different Efficiencies in the motor
When we provide input power to the DC Motor in the form of VI watts, then copper losses occur in armature winding and field windings.

Now, Input power minus copper losses is equal to the driving power (E_bI_a in Watts) which is produced in the motor armature (also known as Developed Power).

The remaining power is not the overall output power because, there are also iron and friction losses occur in DC Motor which is 10 – 20% of the total losses.

At last, the driving power minus iron and friction losses is equal to the overall output power (mechanical power) at motor shaft. Mathematically;
Copper losses = A – B
Iron and Friction losses = B – C

Overall or Commercial efficiency = η_c = C/A =

Types of Motor Efficiencies

Mechanical Efficiency = η_m = C/B =

Electrical Efficacy = η_e = B/A =

Overall or Commercial efficiency = η_c = C/A =

The above story is shown in the below fig.

How to improve the Motor Efficiency?

This efficiency of motor is affected by few losses which include resistance losses, mechanical losses due to friction, losses due to dissipation of magnetic energy in core and different losses depending upon type of material used. In order to make a motor more efficient we have to reduce losses in the motor. Here are some methods or tips that can be adopted to improve the factor of efficiency in motors.

1. Functionality of frame of a motor is to provide mechanical protection to the winding. It is also responsible for the interface for installation through feet. The motor frame plays critical role in its thermal performance because it is responsible for transferring the heat generated inside the motor out to the frame surface where air blown by the fan will promote heat dissipation. This will reduce heat losses.
2. Another basic tip is to keep minimum gap between any walls positioned near the back of the fan cover to allow air intake. Keep motor surroundings clean and periodically check for any air blockage that can reduce the cooling system performance. So the more cool motor will be running, it will be having more life span.
3. Stator which is major component of the motor is cause of 60% losses so in order to reduce these losses mass of stator winding must be kept larger as this increase in mass will reduce electrical resistance. Motors that are highly efficient contains 25% extra copper as compare to motors that are designed for standard efficiency models.
4. Rotor losses are also considered as secondary source of losses that are largely caused by the degree slip displayed by motor. Slip is actually the difference in (RPM) of speed of the magnetic field and the actual RPM of the rotor and shaft at a given load. Where slip is obtained by subtracting speed of motor under load from speed of motor without load divided by speed by motor under load. So in order to reduce these losses slip must be reduced and that is done by making higher conductivity of rotor .Copper must be largely used because copper has high conductivity. But copper must be die cast as recently processes have developed for die casting of copper.
5. Core magnetic losses are originated from hysteresis,20% of total losses are caused by the eddy currents and saturation of magnetic core. By using good quality of materials and quality control, losses can be minimized to improve efficiency.
6. To reduce the effect of hysteresis and saturation steels containing small amount of silicon to be used in laminations instead of lower-cost carbon steels. In this way core losses can be removed. By reducing the thickness of lamination and increasing the length of lamination ,can minimize the flux density also and core losses.
7. Eddy current losses can be largely minimized by ensuring proper insulation between the sheets or laminations used.
8. The lubrication interval is a function of motor mounting rated speed, bearing size, type of grease and temperature rise. So always take care when applying lubricants. Don’t mix grease types, even if they use the same elements. If another grease will be used in the application this will directly affect the motor performance.
   Procedure:

Motor Efficiency Strategies

Motor efficiency strategy must be divided into three steps

1. Assessment
2. Improvement
3. Prolong life period

First step will be to continuously monitor and document that which motors are present under your supervision, how old are they, the horsepower they are providing and ratings, ,what is the controls level present in your facility and to identify the loads. Use some kind of efficiency calculator like motor master.

There are three important aspects that must be checked which are Voltage unbalance, and Power factor. Voltage and current unbalance is caused by difference in values in three phase system respectively. While Power factor (PF) is normally originated due to motors and other heavy accessories like transformers..

PF is actually percentage or a number, with 100%, or 1 when it is ideal. Power factor is the ratio of real (working) power (kW) to apparent (total) power that is in KVA and it is a combination of real power and reactive power (kilovars kVAR). Bad power factor can cause increase in utility bills so it must e controlled.

If any problem occurs with any of these variables, correcting those problems must be immediately removed, using software to estimate efficiency of a motor can be useful.

By concluding the articles it must be known that these all factors explained must be kept in mind while selecting a motor and making it operational. Moreover to increase the life span of the motor inspection on regular intervals must be carried out.

Fuse and Types of Fuses

 

What is a Fuse:

The fuse is an electronic device, which is used to protect circuits from over current, overload and make sure the protection of the circuit. There are many types of fuses available in the market, but function of all these fuses is same.

Fuse consists of a low resistance metallic wire enclosed in a non combustible material. Whenever a short circuit, over current or mismatched load connection occurs, then the thin wire inside the fuse melts because of the heat generated by the heavy current flowing through it. Therefore, it disconnects the power supply from the connected system. In normal operation of the circuit, fuse wire is just a very low resistance component and does not affect the normal operation of the system connected to the power supply.

Types of Fuses:

There are different types of fuses available in the market and they can be categories on the basis of Different aspects.Good to know: Fuses are used in AC as well as DC circuits.

Different Types of Fuses

Fuses can be divided into two main categories according to the type of input supply voltage.

1. AC fuses
2. DC fuses

AC and DC Fuses

There is a little difference between AC and DC Fuses used in the AC and DC Systems.
In a DC system, when the metallic wire Melts because of the heat generated by the over current, then Arc is produced and it is very difficult to extinct this arc because of DC constant value. So in order to minimize the fuse arcing, DC fuse are little bigger than an AC fuse which increase the distance between the electrodes to reduce the arc in the Fuse. On the other hand, i.e. in the AC system, voltage with 60Hz or 50Hz frequency changes it amplitude from zero to 60 times every second, so arc can be extinct easily as compared to DC. Therefore, AC fuses are little bit small in sizes as compared to DC fuses.
Fuses can also be categorized based on one time or multiple Operations.
     

         1) One time use only Fuse                    2) Resettable Fuses

One time use only Fuse

One time use fuses contain a metallic wire, which burns out, when an over current, over load or mismatched load connect event occur, user has to manually replace these fuses, switch fuses are cheap and widely used in almost all the electronics and electrical systems.
Such types of fuses can be categories on the following basis.

• Current carrying Capacity of Fuse
• Breaking capacity
•  I²t value of Fuse
• Response Characteristic
• Rated voltage of Fuse
• Packaging Size

below is the brief explanation of the above categories.

Fuse Current Carrying Capacity:

Current carrying capacity is the amount of current which a fuse can easily conduct without interrupting the circuit.

Breaking capacity:

The value of maximum current that can safely be interrupted by the Fuse is called Breaking Capacity and should be higher than the prospective short circuit current.

 I²t value of Fuse

The I²t  terms related to fuse normally used in short circuit condition. it is the amount of energy which carry the fuse element when the electrical fault is cleared by fuse element.

Response Characteristic:

The speed at which fuse blows, depend on the amount of current flowing through its wire. The higher the current flowing through the wire, faster will be the response time.
Response characteristic shows the response time for over current event. Fuses which respond rapidly to the over current situation is called ultra fast fuses or Fast fuses. They are used in Many semiconductor devices because semiconductor devices damaged by over current very rapidly.
There is another fuse which Is called Slow burn fuse, switch fuses do not respond rapidly to the over current event, but blow after several seconds of over current occurrence. Such fuses found their application in motor control electronics systems because motor takes a lot more current at starting than running.

Rated Voltage of Fuse:

Each fuse has maximum allowed voltage rating, for example, if a fuse is designed for 32 volts it cannot be used with 220 volts, different amount of isolation is required in different fuses working on different voltage levels.

Packaging size:

As we have mentioned above that AC and DC fuses, have a little bit different packaging type, in the same way different application requires different packages to be used accurately in the circuit.

other factors and parameters are marking, temperature derating, voltage drop and speed etc.

Other Types of Fuses

Cartridge fuses

Cartridge fuses are used to protect electrical appliances such as motors air-conditions, refrigerator, pumps etc, where high voltage rating and currents required. They are available up to 600A and 600V AC and widely used in industries, commercial as well as home distribution panels.
There are two types of Cartridge fuses. 1. General purpose fuse with no time delay and 2. Heavy-duty cartridge fuses with time delay. Both are available in 250V AC to 600V AC and its rating can be found on the end cap or knife blade.

Cartridge Fuses

Blade Type fuses:

This type of fuses (also known as spade or plug-in fuses) comes in plastic body and two metal caps to fit in the socket. Mostly, they used in automobiles for wiring and short circuit protection.  to read more about Blade Type of HRC fuses, check this post. Types of HRC Fuses.

Blade Type fuses: used in automobiles

Other Types of Fuses like SMD Fuses , Axial Fuses, Thermal Fuses, HRC (High Rupturing Capacity) fuse and High Voltage fuses ( will discuss latter in detail)

SMD Fuse and Axial fuse

Resettable Fuses:

Resettable fuse is a device, which can be used as multiple times without replacing it. They open the circuit, when an over current event occurs and after some specific time they connect the circuit again. Polymeric positive temperature coefficient device (PPTC, commonly known as a resettable fuse, poly-switch or poly-fuse) is a passive electronic component used to protect against short current faults in electronic circuits.
Application of such fuses is overcome where manually replacing of fuses is difficult or almost impossible, e.g. fuse in the nuclear system or in aerospace system.

Resettable Fuses |Image Credit: Wikipedia

Typical Uses and Applications of fuses:

Electronic Fuses can be used in all types of electrical and electronic applications including:

• Motors
• Air-conditions
• Home distribution boards
• General electrical appliances and devices
• Laptops
• Cell phones
• Game systems
• Printers
• Digital cameras
• DVD players
• Portable Electronics
• LCD monitors
• Scanners
• Battery packs
• Hard disk drives
• Power convertors