Star Delta Contactor Sizing Calculator

Star Delta Contactor Sizing Calculator

Estimate three-phase motor full-load current, main contactor current, delta contactor current, star contactor current, overload setting, transition timer, and starting current reduction for star-delta starter planning.

Star-delta motor presets

📋Motor and starter inputs

Use the motor nameplate when available. Star-delta starters are normally used on motors built for delta running at the selected line voltage, with six motor leads brought to the starter.

Switches the power input between metric motor kW and hp.
Rated shaft output power. FLA is calculated from output power, efficiency, and power factor.
Three-phase line-to-line voltage used in the FLA formula.
Use nameplate efficiency. Higher efficiency lowers calculated input current.
Typical loaded induction motors range from about 0.78 to 0.90.
Used as an upper check for overload dial setting, not as the base FLA formula.
Applied to calculated contactor current before choosing the next AC-3 rating.
In-line overloads are set near FLA; in-delta overloads are set near 0.58 x FLA.
Estimated direct-on-line start current in multiples of full-load current.
Used to recommend the star timer setting before open-transition transfer.
Adjusts the timer estimate for fan wheels, blowers, and other slow-starting loads.
Star-to-delta transfer is usually after the motor reaches most of running speed.
Mechanical and electrical interlock gap between opening star and closing delta.
Adds extra sizing allowance for warm enclosures or dense MCC sections.

Star-delta sizing result

Calculated motor FLA and contactor currents will appear here.

Ready
Motor FLA 0 A Full-load current
Main contactor 0 A Line contactor AC-3 rating
Delta contactor 0 A Delta contactor AC-3 rating
Star contactor 0 A Star contactor AC-3 rating
Motor FLA formula-
Main or line contactor current-
Delta contactor current-
Star contactor current-
Overload relay position sizing-
Transition timer estimate-
Starting current reduction-
Design note-

🔧Contactor and timer spec grid

0 A Overload setting
0 s Star timer setting
0 A Star starting current
0% Start current reduction

📐Star-delta formulas used

Item Formula What it means Common sizing use
Motor FLA W output / (sqrt(3) x V x PF x efficiency) Estimated running line current from nameplate data Base current for the starter worksheet
Main contactor FLA x margin factor The line contactor carries motor line current in run Choose next AC-3 rating at selected voltage
Delta contactor FLA / sqrt(3) Delta contactor carries winding phase current About 58% of line FLA before margins
Star contactor FLA / 3 Star contactor carries reduced phase current during start About 33% of line FLA before margins
Starting current DOL start current / 3 Star connection reduces line starting current to one third Rough 67% reduction compared with DOL

🔌Contactor current reference

Motor line FLA Main contactor Delta contactor Star contactor
10 A 10 A base, next AC-3 size with margin 5.8 A base winding current 3.3 A base starting contactor current
25 A 25 A base, often 32 A with margin 14.4 A base winding current 8.3 A base starting contactor current
50 A 50 A base, often 65 A with margin 28.9 A base winding current 16.7 A base starting contactor current
100 A 100 A base, often 115 A with margin 57.7 A base winding current 33.3 A base starting contactor current

Timer and transition reference

Load type Typical star time Transfer target Timer check
Centrifugal pump 4 to 8 seconds Near stable acceleration current Short enough to avoid stalled heating
Compressor 6 to 10 seconds Motor mostly accelerated Confirm unloaded start condition
Fan or blower 8 to 18 seconds High speed before delta close Watch long acceleration thermal limit
Conveyor or machine 5 to 12 seconds Smooth transfer without drop-out Validate under loaded start conditions

🛡Overload relay position table

Overload location Setting formula Current measured Planning note
In line with supply FLA x setting factor Motor line current Most familiar setting method for many panels
Inside delta circuit FLA / sqrt(3) x setting factor Winding phase current Common in compact star-delta assemblies
Electronic overload Use device manual and CT location Depends on sensor placement Check whether the relay expects line or phase current
Thermal overload Use motor nameplate FLA basis Heat model of selected relay Ambient and enclosure conditions can affect selection

📊Preset motor worksheet table

Preset Voltage Expected FLA band Starter sizing focus
7.5 kW pump 400 V 13 to 16 A Basic starter and short star time
15 kW compressor 400 V 27 to 31 A Main contactor and overload check
30 kW blower 415 V 52 to 60 A Timer and high-inertia transfer
75 kW process pump 400 V 130 to 145 A Contactor margin and panel ambient
100 hp motor 480 V 115 to 130 A hp input with NEMA-style voltage

💡Calculation tips

Use the actual nameplate. Enter the motor kW or hp, voltage, efficiency, and power factor from the installed motor. If the nameplate gives FLA directly, compare it against the calculated FLA and use the nameplate value for final device settings.
Match the starter arrangement. Confirm whether the overload is in the line or inside the delta circuit before setting the relay. The correct current basis changes by a factor of sqrt(3).

Electrical safety note: This calculator is a planning worksheet. Final contactors, overloads, short-circuit protection, conductor sizes, interlocks, utilization category, coordination type, and code compliance must be verified from manufacturer data and by a qualified electrical professional.

Now that’s where working with a star delta starter panel presents its own problem, it has three contactors, one timer and one motor nameplate. If you’ve worked with one before, wiring is simple enough but it’s easy to get tripped up in sizing. You might size everything correctly to handle the full load current but size components for winding current, thus damaging main contactor on first start. It’s an engineer mistake as they thinks all three contactors are designed for the same amperage. Not true. The calculator above use your motor data to help you avoid this costly mistak.

So what’s the big idea with star delta? Well, reduce the voltage. When you crank up a big old induction motor directly on line, it pulls six to seven times rated current. This stresses mechanical couplings, dims lights and trips circuit breakers. By connecting the windings in star, you reduce the voltage on each winding by the square root of three, meaning the starting current decreases about two thirds.

How to Size Star Delta Starter Parts

It is a simple solution and good enough for many applications but there is a downside: you lose torque. Because torque is proportional to voltage squared, you’ll recieve only one third the starting torque. It is not a great way to try to start something like a conveyor belt carrying heavy load from a standstill. Compressors, pumps, and fans starts easily, running light then slowly ramping up, star delta is the ticket for these device.

To properly rate the contactors you need to know direction of flow. When running, current from the motor travels through the delta contactor connecting just two corner points of triangle. In a well-balanced three-phase system, the current through each leg of the delta winding are reduced by the square root of three compared to line current. Therefore, a delta contactor should of been rated at approximately 58 percent of the motor’s full load current. Because the star contactor only “sees” current for very short time when starting, it gets an even smaller rating; about one third of the full load current. Out of habit, engineers frequently oversize this equipment which wastes both money and precious panel space.

Balancing physics and intuition, you set the timer. You cannot switch to delta immediately, or motor will stall because it has not built up enough speed, but if you wait too long then you’ll run it at low torque and windings will get too hot. The calculator find this period for you given the load type and its inertia. If it’s a big industrial fan with lots of inertia, it may take ten or even fifteen seconds to spin up to point where the transfer shock won’t damage drive train. If it’s a centrifugal pump, which spins up quickly, you only give it brief start time (say four to six seconds).

Another item that trips folks up is where the overload relay is located. When positioned on line, set the overload at full load amps for motor. When the relay is within the delta circuit (common with compact starters), set the overload for the smaller current winding. This factor of root three can cause the overload protection to fail or trip nuisance faults and is something not to be forgotten. Always verify whether the overload is on the motor side or contactor side before adjusting setting.

Sizing is a matter of honoring the direction of flow rather than complicated math. The full load goes to main. The winding share goes to delta contactor, while star contactor performs momentarily and then gives way. Visualize it as three separate circuits with their own electrical demands, and sizing tables appear logical more than strange. Yes you should always check surrounding temps and thermal limitations for packed panels but for all practical applications, the proportional relationships remains the same. Respect the math, set timers conservatively, and position overloads based off direction of current.

Star Delta Contactor Sizing Calculator

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