[:en]Star-Delta starting[:ro]Pornirea stea-triunghi[:]

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Protection with thermal overload relay

Operating mode: When the Start button is pressed star contactor Q2 coil is energized. It closes and by means of normally open contact of Q1 the voltage is applied to main contactor Q1. Q1 closes and supplies the voltage to motor M1 in star connection. Q1 and Q2 are maintained via normally open contacts. Once main contactor Q1 is energized time ON delay timer T1 is supplied as well, this has two contacts one normally open (NO) and one normally closed (NC). After the set time elapsed , T1 timer opens the Q2 circuit by means of NC contact and by means of NO contact closes the circuit of Q3. Star contactor Q2 is opened and Q3 delta contactor coil is energized and the full voltage is applied to motor M1. At the same time the normally closed (NC) contact of Q3 cuts off the Q2 circuit and create an interlock, so we avoid simultaneous operation of Q2, Q3 while the motor is running.
A new start is possible only after pressing Stop button or an overload occur, in this case normally closed contact 97-98 of the motor protection relay TF1 is opened.

Calculation of fuses, contactors and thermal overload relay

Before starting any type of calculation it is important to respect the following rules:

Rule no. 1: Refer to the motor plate , there are found important information such as motor power, voltage, current drawn, the power factor, motor yield, etc; information that the manufacturer has obtained as a result of a large number of calculations and tests.

Rule No. 2: If you don’t have the informations listed in Rule no.1, use the following formula for calculation, which is the active power of the motor:

**$P=\sqrt{3}UI*cos\varphi$** (1)

P-active power [W]

U- voltage [V]

I- current drawn [A]

cosⱷ- power factor

Calculation example:

We take for example a three phase motor which we know that has the power of 22 kW. So we have initial data:

Power $P=22kW$

Supply voltage $U=400 V$ being a three phase motor, or your supply voltage(460, 690 V)

Power factor $cos\varphi=0.8$ in general $cos\varphi$ = (0.6-0.95), so chose a mean of 0.8 unless we know the real value.

From equation (1) we obtain the full load current (FLC) of the motor :

$I_{FLC}=\frac{P}{\sqrt{3}Ucos\varphi}=\frac{22000}{1.7324000.8}=39.69[A]$

Now for star contactor Q2 the current will be calculated as follow:

$I=\frac{1}{3}I_{FLC}=0.33I_{FLC}=\frac{39.69}{3}=13.23[A]$ for thermal overload relay TF1, main Q1 and delta Q3 contactors:

$I=\frac{1}{\sqrt{3}}I_{FLC}=0.58I_{FLC}=\frac{39.69}{1.732}=22.91[A]$

For F1 fuse:

$I=(2.5\div 3)I_{FLC}=39.693\cong 120[A]$

F2 and F3 fuses for control circuit will be 1[A]

This product looks like on the next pictures and can be bought using this link: https://automation-electric.com/ro/shop/three-phase-motor-starters/star-delta-starters/

[:ro]Protectie cu releu termic

Modul de operare: La apasarea butonului Start se energizeaza bobina contactorului stea Q2. Acesta anclanseaza si prin contactul normal deschis al Q1 aplica tensiune pe contactorul de retea Q1. Q1 anclanseaza si alimenteaza motorul M1 cu tensiunea retelei în conexiune stea. Q1 si Q2 se automentin prin contactele normal deschise . Odata cu contactorul de retea Q1 este alimentat si releul de timp T1, care are doua contacte unul normal deschis(NO) si unul normal inchis(NC). Corespunzator timpului de comutare reglat, T1 deschide circuitul lui Q2 prin contactul NC , iar prin contactul NO, închide circuitul lui Q3. Contactorul stea Q2 cade. Contactorul triunghi Q3 anclanseaza si aplica motorului M1 întreaga tensiune a retelei. În acelasi timp contactul normal închis al Q3 întrerupe circuitul lui Q2 si interblocheaza o noua conectare a acestuia în timpul functionarii motorului.
O noua pornire este posibila numai dupa apasarea butonului Stop sau daca s-a produs declansarea la suprasarcina prin contactul normal închis 97-98 al relelului de protectie a motorului TF1.

Calculul sigurantelor fuzibile, contactoarelor si a releului termic

Înainte de a începe orice tip de calcul este important să se respecte următoarele reguli:

Regula nr. 1: Consultați plăcuța motorului, aici se gasesc informatii importante, cum ar fi puterea motorului, tensiune, curent absorbit, factorul de putere, randament, etc; informații pe care producătorul le-a obținut ca urmare a unui număr important de calcule si teste.

Regula nr. 2: Dacă nu aveți informatiile enumerate la regula nr.1, utilizați următoarea formulă de calcul, care este puterea activă a motorului:

$P=\sqrt{3}*U*I*cos\varphi$ (1)

P- putere activa [W]

U- tensiune alimentare [V]

I- curent absorbit [A]

$cos\varphi$ – factor de putere

Exemplu de calcul:

Luam ca exemplu un motor trifazat despre care știm că are puterea de 22 kW. Deci, avem urmatoarele date inițiale:

Putere motor $P=22kW$

Tensiunea de alimentare $U=400 V$ fiind un motor trifazic , sau alta tensiunea de alimentare (460, 690 V)

Factorul de putere $cos\varphi=0.8$ in general $cos\varphi$ = (0.6-0.90), in cazul in care nu stim valoarea exacta alegem o.8.

Din ecuatia (1) obtinem curentul nominal al motorului :

$I_{FLC}=\frac{P}{\sqrt{3}*U*cos\varphi}=\frac{22000}{1.732*400*0.8}=39.69[A]$

Asadar pentru contactorul stea Q2 curentul v-a fi calculat dupa cum urmeaza:

$I=\frac{1}{3}*I_{FLC}=0.33*I_{FLC}=\frac{39.69}{3}=13.23[A]$ pentru releul termic TF1, contactorul principal Q1 si contactorul triunghi Q3:

$I=\frac{1}{\sqrt{3}}*I_{FLC}=0.58*I_{FLC}=\frac{39.69}{1.732}=22.91[A]$

Siguranta F1 trebuie sa fie de 2.5 – 3 ori mai mare decat curentul nominal:

$I=(2.5\div 3)*I_{FLC}=39.69*3\cong 120[A]$

Sigurantele F2 si F3 pentru circuitul de comanda vor avea valoarea de 1[A]

Asa arata un produs pe care il fabricam noi, care poate fi achizitionat online folosind urmatorul link: https://automation-electric.com/ro/shop/three-phase-motor-starters/star-delta-starters/

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[:en]Star-Delta starting[:ro]Pornirea stea-triunghi[:] Leave a comment

Protection with thermal overload relay

Calculation of fuses, contactors and thermal overload relay

Before starting any type of calculation it is important to respect the following rules:

Rule no. 1: Refer to the motor plate , there are found important information such as motor power, voltage, current drawn, the power factor, motor yield, etc; information that the manufacturer has obtained as a result of a large number of calculations and tests.

Rule No. 2: If you don’t have the informations listed in Rule no.1, use the following formula for calculation, which is the active power of the motor:

**$P=\sqrt{3}UI*cos\varphi$** (1)

P-active power [W]

U- voltage [V]

I- current drawn [A]

cosⱷ- power factor

Calculation example:

We take for example a three phase motor which we know that has the power of 22 kW. So we have initial data:

Power $P=22kW$

Supply voltage $U=400 V$ being a three phase motor, or your supply voltage(460, 690 V)

Power factor $cos\varphi=0.8$ in general $cos\varphi$ = (0.6-0.95), so chose a mean of 0.8 unless we know the real value.

From equation (1) we obtain the full load current (FLC) of the motor :

$I_{FLC}=\frac{P}{\sqrt{3}Ucos\varphi}=\frac{22000}{1.7324000.8}=39.69[A]$

Now for star contactor Q2 the current will be calculated as follow:

$I=\frac{1}{3}I_{FLC}=0.33I_{FLC}=\frac{39.69}{3}=13.23[A]$ for thermal overload relay TF1, main Q1 and delta Q3 contactors:

$I=\frac{1}{\sqrt{3}}I_{FLC}=0.58I_{FLC}=\frac{39.69}{1.732}=22.91[A]$

For F1 fuse:

$I=(2.5\div 3)I_{FLC}=39.693\cong 120[A]$

F2 and F3 fuses for control circuit will be 1[A]

Dorinel Rus

Leave a Reply Cancel reply

Protection with thermal overload relay

Calculation of fuses, contactors and thermal overload relay

Before starting any type of calculation it is important to respect the following rules:

Rule no. 1: Refer to the motor plate , there are found important information such as motor power, voltage, current drawn, the power factor, motor yield, etc; information that the manufacturer has obtained as a result of a large number of calculations and tests.

Rule No. 2: If you don’t have the informations listed in Rule no.1, use the following formula for calculation, which is the active power of the motor:

(1)

P-active power [W]

U- voltage [V]

I- current drawn [A]

cosⱷ- power factor

Calculation example:

We take for example a three phase motor which we know that has the power of 22 kW. So we have initial data:

Power

Supply voltage being a three phase motor, or your supply voltage(460, 690 V)

Power factor in general = (0.6-0.95), so chose a mean of 0.8 unless we know the real value.

From equation (1) we obtain the full load current (FLC) of the motor :

Now for star contactor Q2 the current will be calculated as follow:

for thermal overload relay TF1, main Q1 and delta Q3 contactors:

For F1 fuse:

F2 and F3 fuses for control circuit will be 1[A]

Dorinel Rus

Leave a Reply Cancel reply

**$P=\sqrt{3}UI*cos\varphi$** (1)

Power $P=22kW$

Supply voltage $U=400 V$ being a three phase motor, or your supply voltage(460, 690 V)

Power factor $cos\varphi=0.8$ in general $cos\varphi$ = (0.6-0.95), so chose a mean of 0.8 unless we know the real value.

$I=\frac{1}{3}I_{FLC}=0.33I_{FLC}=\frac{39.69}{3}=13.23[A]$ for thermal overload relay TF1, main Q1 and delta Q3 contactors: