Parts of a Motor Branch Circuit
CIRCUIT FOR MOTOR LOAD
just a few of the situations that can be protected against with the careful choice of protective devices. If left unprotected, motors will continue to operate even under abnormal conditions. The excessive current causes the motor to overheat, which in turn causes the motor winding insulation to deteriorate and ultimately fail. Good motor overload protection can greatly extend the useful life of a motor. Because of a motor’s characteristics, many common overcurrent devices actually offer limited or no protection.
Motor Starting Currents
When an AC motor is energized, a high inrush current occurs. Typically, during the initial half cycle, the inrush current is often higher than 20 times the normal full load current. After the first halfcycle the motor begins to rotate and the starting current subsides to 4 to 8 times the normal current for several seconds. As a motor reaches running speed, the current subsides to its normal running level. Typical motor starting characteristics are shown in Curve 1.
Because of this inrush, motors require special overload protective devices that can withstand the temporary overloads associated with starting currents and yet protect the motor from sustained overloads. There are four major types. Each offers varying degrees of protection.
Fast Acting Fuses
To offer overload protection, a protective device, depending on its application and the motor’s service factor (S.F.), should be sized at 115% or less of motor F.L.A. for 1.0 S.F. or 125% or less of motor F.L.A. for 1.15 or greater S.F. However, as shown in Curve 2, when fast-acting, non-time-delay fuses are sized to the recommended level the motors inrush will cause nuisance openings.
A fast-acting, non-time-delay fuse sized at 300% will allow the motor to start but sacrifices the overload protection of the motor. As shown by Curve 3 below, a sustained overload will damage the motor before the fuse can open.
A - Motor circuit conductor 125 % of current full load
B' - Motor disconnecting means
B - Motor Branch Circuit; over current protection usually 300% of full load current for safety switch (SS) or 250% of full load current for air circuit breaker (ACB)
NOTE: These values are for general purposes motor only, values of B will depend on type and class of motor. The range is from 150% to 300% of the full load current, and shall in no case exceed 400% of full load current.
C - Motor Controller - rated according to motor horsepower
D - Motor Running Over current and overload protection: setting is from 115% to 125% of full load current. Value of 1.15 nd 1.25 is called service factor (SF)
1. Circuit Conductor - for the size of conductor having a maximum ampacity greater than the calculated value to protect the conductor from burning due to overheating. Faulty wiring is caused by the undersized conductor wire.
2. Branch Circuit Over current Protection - for protection against short circuit ground fault which cause over current flow. It should be capable of carrying the starting current of the motor.
3. Motor - controller ( magnetic contactor ) - used to start and stop the motor. It includes any switch or device capable of interrupting the stalled rotor current of motor.
4. Running Over current and Overload Protection - used to protect motor controller and motor against excessive heating due to motor overload and failure to start.
B' - Motor disconnecting means
B - Motor Branch Circuit; over current protection usually 300% of full load current for safety switch (SS) or 250% of full load current for air circuit breaker (ACB)
NOTE: These values are for general purposes motor only, values of B will depend on type and class of motor. The range is from 150% to 300% of the full load current, and shall in no case exceed 400% of full load current.
C - Motor Controller - rated according to motor horsepower
D - Motor Running Over current and overload protection: setting is from 115% to 125% of full load current. Value of 1.15 nd 1.25 is called service factor (SF)
1. Circuit Conductor - for the size of conductor having a maximum ampacity greater than the calculated value to protect the conductor from burning due to overheating. Faulty wiring is caused by the undersized conductor wire.
2. Branch Circuit Over current Protection - for protection against short circuit ground fault which cause over current flow. It should be capable of carrying the starting current of the motor.
3. Motor - controller ( magnetic contactor ) - used to start and stop the motor. It includes any switch or device capable of interrupting the stalled rotor current of motor.
4. Running Over current and Overload Protection - used to protect motor controller and motor against excessive heating due to motor overload and failure to start.
CIRCUIT FOR MOTOR LOAD
Name plate of the motor
25 hp,220 volts, 3 phase; 3 wires
60 Hz, 0.84 power factor 90.5% efficiency
3. Determine the main over current protection. The National Electrical Code provides that:
" The protection rating or setting of a motor shall be 250 % percent (maximum) of the full load current of the biggest motor being served plus the sum of the full load current of the other motors."
(45 x 125%) x (250% +39 + 29 + 21)
140.625 + 89 = 229.625 A (maximum)
4. Refer to Table. Select a fuse or trip breaker that is nearest to standard rating that will not exceed 229.62 A. Use 200 A.
25 hp,220 volts, 3 phase; 3 wires
60 Hz, 0.84 power factor 90.5% efficiency
SOLUTION:
1. Solve for the current load:
1 horsepower = 746 watts
I = (load in hp x 746 w)/ (k x E x pf x n)
where:
k - 1.0 for 2 wire single phase DC
1.73 for 3 wire, 3 phase AC
2.0 for 3 wire single phase AC or DC
3.0 for 4 wires, 3 phase AC
E - voltage between the neutral and live wire or between two live wires if no neutral line exists
I - Current in any live wire except Neutral Line
pf - power factor
N - efficiency
2. Applying the formula
I = (25 hp x 746)/(1.73 x 220 volts x .84 x 90.5%)
= 64.45 A
3. Determine the Motor feeder. The current load of a motor multiplied by 125% (Code requirements)
4. Find the size of the conductor wire. Refer to Table, for 80.56 A, use any of the following:
3 - 38 mm2 THW or RHW copper wire
3 - 50 mm2 TW copper wire
3 - 80 mm2 TW aluminum or copper clad alum
3 - 50 mm2 THW or RHW aluminum or copper clad aluminum
The allowable ampacities of the above wires in Table was derated by 80% to carry the 80.56 A current load.
5. Solve for the size of conduit pipe. Refer to Table, use 50 mm diameter pipe.
6. Determine the size or rating of the over current protection. The Code provides "The maximum over current protection for a single motor or a combination of motors should be, 250% of the ampacity of the largest motor plus the sum of the full load current of the other motors.
Therefore:
64.45 A x 250% = 161.15 A minimum
7. Refer to Table. Use 150 A fuse or trip breaker. It is the nearest standard rating which does not exceed the 161.12 A current load as computed.
MATERIALS FOR MOTOR INSTALLATION:
1. 25 hp Induction motor 230 volts, 3 phase, 1800 rpm, 60 Hz at 40 degree temperature rise
2. Magnetic thermal overload control with contractors.
3. Service entrance cap 50 mm with locknut
4. 38 mm2 THW or RHW copper wire.
5. 50 mm2 diameter IMT or RSC conduit pipe
6. Conduit clamp with screw, 50 mm conduit pipe
7. TPST safety switch or circuit breaker 150 or 250 volts
The quantity of materials depends upon the area and choice of the designing Engineer
CALCULATION PROCEDURES IN FINDING THE SIZE OF FEEDER AND THE OVERLOAD CURRENT PROTECTION FOR A GROUP OF MOTORS
Four 3 - phase motor 220 volts squirrel cage induction motor designed for 40 degree Celsius temperature rise at 1800 rpm, 60 Hz
SOLUTION:
1. Determine the main feeder of the motors. Apply 25% of the biggest motor current load plus the sum of the other motors.
(45 x 1.25) + 39 + 29 +21
= 145.25 A
2. Refer to Table. For the 145.25 A current load use any of the following conductor wires:
3 - 80 mm2 THW or RHW copper wire
3 - 100 mm2 TW copper wire
3- 125 mm2 THW or RHW aluminum or copper clad aluminum
3 - 150 mm2 TW clad aluminum
1. Solve for the current load:
1 horsepower = 746 watts
I = (load in hp x 746 w)/ (k x E x pf x n)
where:
k - 1.0 for 2 wire single phase DC
1.73 for 3 wire, 3 phase AC
2.0 for 3 wire single phase AC or DC
3.0 for 4 wires, 3 phase AC
E - voltage between the neutral and live wire or between two live wires if no neutral line exists
I - Current in any live wire except Neutral Line
pf - power factor
N - efficiency
2. Applying the formula
I = (25 hp x 746)/(1.73 x 220 volts x .84 x 90.5%)
= 64.45 A
3. Determine the Motor feeder. The current load of a motor multiplied by 125% (Code requirements)
4. Find the size of the conductor wire. Refer to Table, for 80.56 A, use any of the following:
3 - 38 mm2 THW or RHW copper wire
3 - 50 mm2 TW copper wire
3 - 80 mm2 TW aluminum or copper clad alum
3 - 50 mm2 THW or RHW aluminum or copper clad aluminum
The allowable ampacities of the above wires in Table was derated by 80% to carry the 80.56 A current load.
5. Solve for the size of conduit pipe. Refer to Table, use 50 mm diameter pipe.
6. Determine the size or rating of the over current protection. The Code provides "The maximum over current protection for a single motor or a combination of motors should be, 250% of the ampacity of the largest motor plus the sum of the full load current of the other motors.
Therefore:
64.45 A x 250% = 161.15 A minimum
7. Refer to Table. Use 150 A fuse or trip breaker. It is the nearest standard rating which does not exceed the 161.12 A current load as computed.
MATERIALS FOR MOTOR INSTALLATION:
1. 25 hp Induction motor 230 volts, 3 phase, 1800 rpm, 60 Hz at 40 degree temperature rise
2. Magnetic thermal overload control with contractors.
3. Service entrance cap 50 mm with locknut
4. 38 mm2 THW or RHW copper wire.
5. 50 mm2 diameter IMT or RSC conduit pipe
6. Conduit clamp with screw, 50 mm conduit pipe
7. TPST safety switch or circuit breaker 150 or 250 volts
The quantity of materials depends upon the area and choice of the designing Engineer
CALCULATION PROCEDURES IN FINDING THE SIZE OF FEEDER AND THE OVERLOAD CURRENT PROTECTION FOR A GROUP OF MOTORS
Four 3 - phase motor 220 volts squirrel cage induction motor designed for 40 degree Celsius temperature rise at 1800 rpm, 60 Hz
SOLUTION:
1. Determine the main feeder of the motors. Apply 25% of the biggest motor current load plus the sum of the other motors.
(45 x 1.25) + 39 + 29 +21
= 145.25 A
2. Refer to Table. For the 145.25 A current load use any of the following conductor wires:
3 - 80 mm2 THW or RHW copper wire
3 - 100 mm2 TW copper wire
3- 125 mm2 THW or RHW aluminum or copper clad aluminum
3 - 150 mm2 TW clad aluminum
3. Determine the main over current protection. The National Electrical Code provides that:
" The protection rating or setting of a motor shall be 250 % percent (maximum) of the full load current of the biggest motor being served plus the sum of the full load current of the other motors."
(45 x 125%) x (250% +39 + 29 + 21)
140.625 + 89 = 229.625 A (maximum)
4. Refer to Table. Select a fuse or trip breaker that is nearest to standard rating that will not exceed 229.62 A. Use 200 A.
OVERLOAD PROTECTION
Overcurrents
An overcurrent exists when the normal load current for a circuit is exceeded. It can be in the form of an overload or short-circuit. When applied to motor circuits an overload is any current, flowing within the normal circuit path, that is higher than the motor’s normal full load amperes (F.L.A.). A short-circuit is an overcurrent which greatly exceeds the normal full load current of the circuit. Also, as its name infers, a short-circuit leaves the normal current carrying path of the circuit and takes a “short cut” around the load and back to the power source. Motors can be damaged by both types of currents.Single-phasing, overworking and locked rotor conditions areOvercurrents
just a few of the situations that can be protected against with the careful choice of protective devices. If left unprotected, motors will continue to operate even under abnormal conditions. The excessive current causes the motor to overheat, which in turn causes the motor winding insulation to deteriorate and ultimately fail. Good motor overload protection can greatly extend the useful life of a motor. Because of a motor’s characteristics, many common overcurrent devices actually offer limited or no protection.
Motor Starting Currents
When an AC motor is energized, a high inrush current occurs. Typically, during the initial half cycle, the inrush current is often higher than 20 times the normal full load current. After the first halfcycle the motor begins to rotate and the starting current subsides to 4 to 8 times the normal current for several seconds. As a motor reaches running speed, the current subsides to its normal running level. Typical motor starting characteristics are shown in Curve 1.
Because of this inrush, motors require special overload protective devices that can withstand the temporary overloads associated with starting currents and yet protect the motor from sustained overloads. There are four major types. Each offers varying degrees of protection.
Fast Acting Fuses
To offer overload protection, a protective device, depending on its application and the motor’s service factor (S.F.), should be sized at 115% or less of motor F.L.A. for 1.0 S.F. or 125% or less of motor F.L.A. for 1.15 or greater S.F. However, as shown in Curve 2, when fast-acting, non-time-delay fuses are sized to the recommended level the motors inrush will cause nuisance openings.
A fast-acting, non-time-delay fuse sized at 300% will allow the motor to start but sacrifices the overload protection of the motor. As shown by Curve 3 below, a sustained overload will damage the motor before the fuse can open.
Thanks for this post very informative, I feel strongly about it and love learning more on this topic. If possible, as you gain expertise, would you mind updating your blog with more information? It is extremely helpful for me.
ReplyDeleteac maintenance Delray Beach
just wanted to point out that the comments on here are awful. You might want to clean these up at some point so casual browsers like me can actually have a conversation.updating your blog with more information? It is extremely helpful for me.
ReplyDeleteair conditioning service Lake Worth
Your articles and contents are encouraging. industrial electric motors
ReplyDeleteNice blog… Thanks for sharing very useful information about electrical circuits.
ReplyDeleteDesigning Electrical Circuits
I truly cherished perusing your online journal. It was extremely very much wrote and simple to undertand. Dissimilar to extra online journals I have perused which are truly not tht great. I likewise discovered your posts extremely fascinating. Truth be told in the wake of understanding, I needed to go demonstrat to it to my companion and he ejoyed it too! camping generators
ReplyDeleteI think there is a mistake in your computation (45 x 125%) x (250% +39 + 29 + 21)
ReplyDelete140.625 + 89 = 229.625 A (maximum)
This should be: (45x125%x250%)+(39+29+21)=
140.625 + 89 = 229.625 A
This was no doubth extracted from the book authored by Max and Leo Fajardo.
ReplyDeleteI had the pleasure of working closely with Benjamin lee for several years as business partners. During the time that Ben served as the Mortgage Representative for my home also for my business financing and he helped me closing off loans which really helped me in my business today, we were consistently far above goal and this can only be attributable to Ben hard work. I appreciate your hard work also big thanks to your team for helping me with a loan to grow my business. If you are looking for a loan in any such kindly contact Mr Ben on 247officedept@gmail.com or talk to him on whatsapp +1---989-394-3740 . Mr Ben is an honest loan officer working with a huge number of investors willing to finance any project.Thankfully, over time our relationship grew beyond wok and I’m still happy to call him a trusted friend.
ReplyDeleteI read your article that's really good. Your articles and contents are encouraging. keep sharing your efforts.
ReplyDeleteElectrical Building Design course
I am very grateful to Dr Dawn Acuna, for bringing back my husband who left me for another woman, that moment my husband Left me I thought I lost everything until a friend of my gave me Dr Dawn Acuna, WhatsApp contact, I messaged her and told her the pain I was going through so she told me that everything was going to be fine that if I have the faith and believe in her that the spell will surely work for me and my husband will surely come back home and she told me what to do, so those things were done and 48 hrs later my husband came back home begging for my forgiveness, am so happy and grateful to Dr Dawn Acuna, if you need her help contact her, she's accurate and sincere,
ReplyDelete* If you want spell to conceive.
*If you want to get pregnant.
* If you want to return your lover
*If you want to cure any kind of sickness
* If you need spell to get good job. *If you want to stop having miscarriage. And E.T.C. write her on email { dawnacuna314@gmail.com }
WhatsApp: +2348032246310
ICON Legal Services - Our lawyer’s assist you do the right thing and provide you guidance to report fraud against banks, financial institutions. Consult today!
ReplyDeleteFinancial disputes legal support in Chennai
Hi there, It is a nice blog. I really read it thoroughly, keep updating us with new one.
ReplyDeleteThank You such a lot for sharing this wonderful information with us.
Electrical Design
Thanks for sharing informative post. Moreover see
ReplyDeleteconstruction of DC Motor
This comment has been removed by the author.
ReplyDeleteThis is a very informative blog post that breaks down the process of selecting the right electrical components for a motor circuit very clearly. The explanations and calculations are well laid out and easy to follow.
ReplyDeleteI was particularly interested in the section on overload protection. You mentioned that fast-acting fuses may not be ideal due to nuisance openings during motor startup. Could you elaborate on the pros and cons of different types of overload protection devices, such as thermal overload relays, compared to fast-acting fuses?