thankx.. do share this video with others

Thanks and welcome.. do share this video with others

To hum kya kry

Thanks 🤗 do share this video with others

Motor ka stator aur rotor ka measurement karte waqt aapko kuch specific dimensions aur parameters ko measure karna padta hai, jo motor ki speed aur power par prabhavit karte hain. Yeh measurement speed aur power ko directly influence karte hain. 1. Stator aur Rotor ke Measurement: Stator Bore Diameter: Stator ka inner diameter measure karte hain jahan rotor fit hota hai. Yeh diameter directly rotor ke size ko affect karta hai. Stator Outer Diameter: Stator ka outer diameter bhi important hai kyunki yeh motor ke overall size ko determine karta hai. Stack Length (or Core Length): Stator aur rotor ka core length measure karte hain. Yeh length motor ke power output aur torque generation ko influence karti hai. Slot Dimensions: Stator aur rotor slots ka dimension (width, depth) measure karte hain, jahan winding hoti hai. Yeh winding ka area aur motor ke efficiency ko affect karta hai. Rotor Shaft Diameter: Rotor ke shaft ka diameter bhi measure karte hain, jo rotor ke stability aur performance ko impact karta hai. 2. Motor Speed aur Power par Farq: Speed: Rotor Size: Agar rotor ka size bada hota hai (bada rotor diameter), to motor ki speed generally kam hoti hai kyunki torque zyada generate hota hai. Slot Dimensions: Agar stator slots ke dimensions badal diye jaaye, to motor ki speed par bhi prabhav pad sakta hai. Number of Poles: Stator aur rotor ke poles ka count bhi speed ko affect karta hai. Jitne zyada poles, utni hi kam speed. Power: Stator and Rotor Size: Agar stator aur rotor ka size zyada hoga, to motor zyada power generate kar sakti hai kyunki zyada space hota hai winding aur magnetic field ke liye. Stack Length: Agar stack length zyada hoti hai, to motor ka power capacity bhi zyada hoti hai, kyunki winding ka length badhta hai. Magnetic Field: Rotor aur stator ke dimensions ke basis par magnetic flux generate hota hai, jo power output ko influence karta hai. Summary: Speed: Speed ko rotor aur stator ke dimensions, poles, aur slot design se control kiya jaata hai. Power: Power stator aur rotor ke size, stack length, aur winding design se affect hoti hai.

ok will try sure.. do share this video with others

To determine the start lead (starting winding) of a single-phase motor, you typically don't need to rely on phase difference calculations. Instead, you can identify the start, run, and common leads using a multimeter or by understanding the motor's wiring. However, if you're trying to understand or calculate the phase difference between the start and run windings, it usually relates to the capacitor in capacitor-start motors, where the capacitor creates a phase shift to generate a rotating magnetic field. Identifying Start, Run, and Common Leads Without Phase Difference Calculation: Visual Inspection: Color Coding: Many motors use standard color codes (like black, red, and blue) to distinguish between start, run, and common leads. Refer to the motor's wiring diagram or nameplate if available. Capacitor: The start winding is typically connected to a capacitor, so tracing the wires from the capacitor can help identify the start lead. Using a Multimeter: Resistance Measurement: The resistance between the common and start winding is usually higher than between the common and run winding. The resistance between the start and run windings is the sum of the two. Common to Run: Lowest resistance. Common to Start: Higher resistance. Start to Run: The sum of the two resistances above. Procedure: Label the wires as A, B, and C. Measure the resistance between each pair: AB, AC, and BC. Identify the common lead (C): The pair with the highest resistance (BC) involves the start and run leads. The common lead (C) will have the lower resistances (AB and AC). The start winding will be the one with the highest resistance from the common lead.

@@NiketShahPlus sir yeh 3 phase winding hai toh phase difference aap nahi nikale hai toh esh prakar se winding kare toh RPM me difference aaye ga ki nahi 👍

already dala he hamare online courses me for details call : 9768871110

sure will try

Will try for video

Depends upon hp

hello... do share this video with others as well

sure will try

thankx for your love.. do share this video with others

cover in our online courses for details call: 9768871110

Dual Voltage 3-Phase Motor Winding Configuration Dual voltage 3-phase motors are designed to operate at two different voltages by configuring the winding connections in either series or parallel. For high voltage operation (typically 480V), the windings are connected in series, while for low voltage operation (typically 240V), the windings are connected in parallel. Here's a detailed explanation of the winding configurations: Winding Configuration High Voltage (480V) Configuration (Series Connection): In this configuration, the motor windings are connected in series to handle the higher voltage. Each phase of the motor has two windings, which are connected end-to-end (series). Low Voltage (240V) Configuration (Parallel Connection): In this configuration, the motor windings are connected in parallel to handle the lower voltage. Each phase of the motor has two windings, which are connected side-by-side (parallel). Winding Details Terminal Connections for Dual Voltage Motor T1, T2, T3: These are the primary terminals for connecting the motor to the power supply. T4, T5, T6: These are the secondary terminals that are used to change the winding configuration. High Voltage (480V) Series Connection In this configuration, the windings are connected in series as follows: Connect T1 to one end of winding 1A. Connect the other end of winding 1A to one end of winding 1B. Connect the other end of winding 1B to T4 (Series Connection). Repeat for phases 2 and 3: Connect T2 to one end of winding 2A. Connect the other end of winding 2A to one end of winding 2B. Connect the other end of winding 2B to T5. Connect T3 to one end of winding 3A. Connect the other end of winding 3A to one end of winding 3B. Connect the other end of winding 3B to T6. Low Voltage (240V) Parallel Connection In this configuration, the windings are connected in parallel as follows: Connect T1 to one end of winding 1A and T4 (Parallel Connection). Connect the other end of winding 1A to one end of winding 1B. Connect the other end of winding 1B to T7. Repeat for phases 2 and 3: Connect T2 to one end of winding 2A and T5. Connect the other end of winding 2A to one end of winding 2B. Connect the other end of winding 2B to T8. Connect T3 to one end of winding 3A and T6. Connect the other end of winding 3A to one end of winding 3B. Connect the other end of winding 3B to T9. Summary of Terminal Connections High Voltage (480V) Series Connection T1 to T4 T2 to T5 T3 to T6 Low Voltage (240V) Parallel Connection T1 to T4 and T7 T2 to T5 and T8 T3 to T6 and T9

ok.. call karo 9768871110 per

ok will try sure.. but do share this video with others

❤❤❤

In our online courses

need to take from company

9768871110

Dual Voltage 3-Phase Motor Winding Configuration Dual voltage 3-phase motors are designed to operate at two different voltages by configuring the winding connections in either series or parallel. For high voltage operation (typically 480V), the windings are connected in series, while for low voltage operation (typically 240V), the windings are connected in parallel. Here's a detailed explanation of the winding configurations: Winding Configuration High Voltage (480V) Configuration (Series Connection): In this configuration, the motor windings are connected in series to handle the higher voltage. Each phase of the motor has two windings, which are connected end-to-end (series). Low Voltage (240V) Configuration (Parallel Connection): In this configuration, the motor windings are connected in parallel to handle the lower voltage. Each phase of the motor has two windings, which are connected side-by-side (parallel). Winding Details Terminal Connections for Dual Voltage Motor T1, T2, T3: These are the primary terminals for connecting the motor to the power supply. T4, T5, T6: These are the secondary terminals that are used to change the winding configuration. High Voltage (480V) Series Connection In this configuration, the windings are connected in series as follows: Connect T1 to one end of winding 1A. Connect the other end of winding 1A to one end of winding 1B. Connect the other end of winding 1B to T4 (Series Connection). Repeat for phases 2 and 3: Connect T2 to one end of winding 2A. Connect the other end of winding 2A to one end of winding 2B. Connect the other end of winding 2B to T5. Connect T3 to one end of winding 3A. Connect the other end of winding 3A to one end of winding 3B. Connect the other end of winding 3B to T6. Low Voltage (240V) Parallel Connection In this configuration, the windings are connected in parallel as follows: Connect T1 to one end of winding 1A and T4 (Parallel Connection). Connect the other end of winding 1A to one end of winding 1B. Connect the other end of winding 1B to T7. Repeat for phases 2 and 3: Connect T2 to one end of winding 2A and T5. Connect the other end of winding 2A to one end of winding 2B. Connect the other end of winding 2B to T8. Connect T3 to one end of winding 3A and T6. Connect the other end of winding 3A to one end of winding 3B. Connect the other end of winding 3B to T9. Summary of Terminal Connections High Voltage (480V) Series Connection T1 to T4 T2 to T5 T3 to T6 Low Voltage (240V) Parallel Connection T1 to T4 and T7 T2 to T5 and T8 T3 to T6 and T9

@@NiketShahPlus thanks for reply. i want to know about winding digram. Does these low voltage and high voltage coils go in the same slot?