How to convert Single Phase into Three Phase? | सिंगल फेज को थ्री फेज में कैसे बदलें? | Electrical

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Still many work is done

will try to make video on this

Haan bhai, VFD (Variable Frequency Drive) kaam toh karega, lekin kuch limitations aur considerations hain:
VFD Rating: VFD ko motor ke rated horsepower ke hisaab se select karna padta hai. Agar aapka VFD 250 HP motor ke liye rated hai, toh vo 500 HP motor ko control nahi kar paayega. 500 HP motor ke liye aapko usi rating ka ya us se zyada rated VFD lena padega.
Overload Capacity: 250 HP ka VFD, 500 HP motor ki current aur torque demand ko pura nahi kar paayega. Yeh overload aur overheating ka reason ban sakta hai aur VFD fail ho sakta hai.
Safety: VFD aur motor dono ka protection alag rating ka hona chahiye, jise ki overcurrent aur voltage spikes se equipment safe rahe. 500 HP motor ke liye, specific VFD protection aur controls ki zaroorat hoti hai jo 250 HP wale VFD mein nahi milte.
Efficiency aur Performance: Agar aap under-rated VFD use karenge toh efficiency aur performance compromise ho sakti hai aur motor smoothly operate nahi karegi.
Isliye, best practice ye hi hogi ki aap 500 HP motor ke liye 500 HP ka ya usse upar ka VFD hi use karein taaki vo effectively aur safely work kare.

ट्रांसफार्मर में से तीन अलग-अलग वाइंडिंग निकालने से थ्री-फेज़ सर्किट बनेगा, लेकिन RGB (Red, Green, Blue) आउटपुट की बात इस संदर्भ में समझने की ज़रूरत है। चलिए इसे विस्तार से समझते हैं:
ट्रांसफार्मर और थ्री-फेज़ सर्किट
थ्री-फेज़ ट्रांसफार्मर:
एक थ्री-फेज़ ट्रांसफार्मर में तीन अलग-अलग वाइंडिंग्स (या फेज़) होते हैं जो एक निश्चित फेज़ शिफ्ट पर आधारित होते हैं। जब इन तीन वाइंडिंग्स से आउटपुट प्राप्त होता है, तो यह एक संतुलित थ्री-फेज़ सर्किट देता है।
फेज़ वाइंडिंग्स:
यदि आप ट्रांसफार्मर के तीन अलग-अलग वाइंडिंग्स को अलग-अलग कर लेते हैं, तो आप एक थ्री-फेज़ आउटपुट प्राप्त कर सकते हैं। प्रत्येक वाइंडिंग एक अलग फेज़ प्रदान करती है। फेज़ का अंतर 120 डिग्री होता है।
फ़्रीक्वेंसी और RGB आउटपुट
फ़्रीक्वेंसी:
ट्रांसफार्मर का आउटपुट फ़्रीक्वेंसी (जैसे 50 Hz या 60 Hz) ट्रांसफार्मर के डिज़ाइन और इनपुट पर निर्भर करती है। अगर आप ट्रांसफार्मर के तीन वाइंडिंग्स को अलग-अलग करते हैं, तो भी फ़्रीक्वेंसी वही रहती है, क्योंकि यह ट्रांसफार्मर की प्राथमिक (प्राइमरी) और द्वितीयक (सेकंडरी) वाइंडिंग्स से निर्धारित होती है।
RGB (Red, Green, Blue) आउटपुट:
RGB एक रंग मॉडल है जिसका उपयोग आमतौर पर डिस्प्ले स्क्रीन पर रंगों को बनाने के लिए किया जाता है। थ्री-फेज़ पावर सर्किट में RGB आउटपुट का कोई सीधा संबंध नहीं होता। RGB रंगों की बात डिस्प्ले तकनीक से संबंधित होती है, जबकि थ्री-फेज़ पावर सर्किट पावर ट्रांसफर और वितरण से संबंधित होता है।
संक्षेप में:
थ्री-फेज़ सर्किट: यदि आप ट्रांसफार्मर से तीन अलग-अलग वाइंडिंग्स निकालते हैं, तो आप थ्री-फेज़ सर्किट प्राप्त कर सकते हैं। यह एक सही और संतुलित थ्री-फेज़ सर्किट होगा।
फ़्रीक्वेंसी: फ़्रीक्वेंसी वही रहेगी जो ट्रांसफार्मर के डिज़ाइन के अनुसार है।
RGB: RGB आउटपुट का थ्री-फेज़ सर्किट से कोई संबंध नहीं है। RGB रंग मॉडल का उपयोग डिस्प्ले और लाइटिंग में किया जाता है, न कि पावर ट्रांसफार्मर में।
उम्मीद है कि इससे आपके प्रश्न का उत्तर मिल गया होगा!

Using a 132 kW Variable Frequency Drive (VFD) involves a number of considerations, especially in terms of its application, sizing, installation, and operational parameters. Here’s a detailed overview:
Application:
A 132 kW VFD is typically used in industrial settings to control large motors, such as those found in pumps, fans, conveyors, compressors, or other heavy machinery. The primary purpose of the VFD is to adjust the speed and torque of the motor to match the demands of the application, leading to energy savings and more precise control.

बिल्कुल सही समझा आपने! सिंगल फेज मोटर में केपेसिटर का मुख्य काम यही होता है कि वह सिंगल फेज इनपुट को एक ऐसा आर्टिफिशियल "तीसरा फेज" प्रदान करे, जिससे मोटर में घुमाव शुरू हो सके। इसका कारण यह है कि सिंगल फेज पर मोटर खुद-ब-खुद स्टार्ट नहीं हो सकती, इसलिए केपेसिटर की मदद से मोटर में स्टार्टिंग टॉर्क उत्पन्न किया जाता है।
सिंगल फेज मोटर में केपेसिटर का काम कैसे करता है:
फेज शिफ्टिंग: केपेसिटर का काम फेज शिफ्टिंग करना होता है। यह सिंगल फेज इनपुट से करंट लेकर उसे 90 डिग्री शिफ्ट करता है, जिससे एक दूसरा "फेज" जैसा करंट बनता है। यह शिफ्टेड करंट मोटर के स्टार्टिंग वाइंडिंग को प्रदान किया जाता है, जिससे मोटर घूमना शुरू करती है।
तीन तारों का सेटअप:
एक तार मुख्य वाइंडिंग (Main winding) के लिए होता है।
दूसरा तार स्टार्टिंग वाइंडिंग (Starting winding) के लिए होता है, जो कि केपेसिटर के साथ जुड़ा होता है।
तीसरा तार न्यूट्रल होता है।
इस सेटअप में मुख्य वाइंडिंग और स्टार्टिंग वाइंडिंग में करंट आता है, जिससे मोटर का घूमना संभव हो पाता है।
स्टार्ट और रन केपेसिटर: कुछ मोटरों में दो प्रकार के केपेसिटर होते हैं - स्टार्ट केपेसिटर और रन केपेसिटर। स्टार्ट केपेसिटर मोटर को स्टार्ट करने में मदद करता है, जबकि रन केपेसिटर मोटर को चालू अवस्था में चलाने में मदद करता है।
संक्षेप में
केपेसिटर सिंगल फेज इनपुट से दो अलग-अलग करंट उत्पन्न करता है जो 90 डिग्री के फेज शिफ्ट पर होते हैं। यह फेज अंतर मोटर को घूमने के लिए आवश्यक टॉर्क प्रदान करता है।

Ji, 40 HP ki motor ke liye aapko ek appropriate automatic transfer switch (ATS) chahiye hoga jo 65 Amp load ko handle kar sake. Yeh kuch steps aur considerations hain jo aapko ATS select karte waqt dhyan mein rakhni chahiye:
ATS Selection:
Current Rating:
Aapko 65 Amp load handle karne ke liye ATS ki current rating minimum 65 Amp honi chahiye.
General recommendation yeh hota hai ki thoda higher rating (safety margin ke liye) ka ATS select karein, jaise 70-80 Amp.
Voltage Rating:
Aapko ATS ki voltage rating apni motor ke voltage rating ke according select karni hogi (e.g., 230V single-phase ya 415V three-phase).
Type of ATS:
Manual Transfer Switch (MTS): Agar aap manual switching prefer karte hain.
Automatic Transfer Switch (ATS): Agar aap automatic switching prefer karte hain. ATS aapke requirement ke according zyada convenient hota hai.
Cost Estimation:
ATS ka cost brand, specifications aur features ke upar depend karta hai. Estimated cost range aapko ek idea dene ke liye provide kiya ja raha hai:
Basic Manual Transfer Switch (MTS):
Cost: ₹10,000 - ₹20,000 (approx.)
Automatic Transfer Switch (ATS):
Basic Models: ₹20,000 - ₹50,000 (approx.)
Advanced Models with More Features: ₹50,000 - ₹1,00,000 (approx.)

Thank uu sir ​@@NiketShahPlus

जी हमारे 3फेस लाइट में एक फेस में 70 v लाइट रहती हैं तो 7.5hp की ट्यू वेल की मोटर इससे चल जायेगी क्या लोड 6-7 amp का होता है

Same as in normal mode.. do share this video with others also

Three-phase generators typically produce three-phase power, but you can obtain single-phase output from them by using various methods. Here are a few common ways to achieve single-phase output from a three-phase generator:
Using a Transformer:
You can use a transformer to step down the three-phase voltage to a single-phase voltage. This involves connecting two of the three phases to the primary side of a transformer and taking the output from one of the secondary windings.
Using Two Phases:
You can connect the load across any two of the three phases. This will give you a single-phase supply, but the voltage will be higher than that of a standard single-phase connection (typically √3 times the phase voltage).
Phase Converter:
If you need to operate single-phase loads using a three-phase generator, you can use a phase converter. This device can convert three-phase power to single-phase power, allowing you to run single-phase equipment effectively.
Using Capacitors:
In some cases, you can use capacitors to create a synthetic phase, effectively converting three-phase power to single-phase. This method is more common in smaller applications or for specific types of motors.
Static Phase Converter:
This converter allows a three-phase motor to operate on single-phase power, providing sufficient starting torque for the motor. It's suitable for small loads but may not be efficient for all applications.
When implementing any of these methods, it's essential to consider the load requirements, as well as the generator's capacity, to ensure safe and effective operation.

That's a clear and concise explanation of capacitors! Capacitors indeed play a vital role in electronic circuits due to their ability to store and release energy. Here's a bit more detail on their functions:
Energy Storage: Capacitors can store energy when connected to a power source and release it when needed, making them essential in circuits that require a temporary power boost, like in camera flashes or for maintaining power during brief interruptions.
Filtering: In power supplies, capacitors smooth out voltage fluctuations by filtering out noise, ensuring a steady output voltage. They are also used in audio and radio frequency circuits to filter specific frequencies.
Timing Circuits: Capacitors are key components in timing circuits, where they work with resistors to create delays or oscillations. This is common in clocks, timers, and pulse generators.
Coupling and Decoupling: In signal processing, capacitors are used to couple AC signals between different stages of a circuit while blocking DC components. They are also used to decouple or bypass AC noise from power supplies, ensuring that sensitive parts of the circuit remain unaffected by fluctuations.

Welcome.. do share this video with others also

Not recommended

हाँ, आप एक मोटर-जेनरेटर सेटअप का उपयोग करके सिंगल फेज पावर को थ्री फेज पावर में बदल सकते हैं। इसे मोटर-जेनरेटर यूनिट (MGU) या रोटरी फेज कनवर्टर भी कहा जाता है। यह तरीका एक विश्वसनीय और सामान्य रूप से उपयोग किया जाने वाला समाधान है, विशेषकर उन स्थानों पर जहां केवल सिंगल फेज पावर उपलब्ध होती है और थ्री फेज पावर की आवश्यकता होती है।
मोटर-जेनरेटर सेटअप की कार्यप्रणाली:
मोटर: सिंगल फेज एसी सप्लाई से चलने वाली एक इलेक्ट्रिक मोटर।
जेनरेटर: एक थ्री फेज एसी जेनरेटर जो मोटर से मैकेनिकली कनेक्टेड होता है।
प्रक्रिया:
सिंगल फेज मोटर: सिंगल फेज पावर सप्लाई से मोटर को चलाया जाता है।
जेनरेटर का संचालन: मोटर, जेनरेटर को घुमाती है, जिससे जेनरेटर तीन फेज एसी पावर उत्पन्न करता है।
लाभ:
विश्वसनीयता: यह सेटअप बहुत विश्वसनीय होता है और लंबे समय तक चल सकता है।
लचीलेपन: विभिन्न प्रकार के थ्री फेज उपकरणों को सिंगल फेज पावर से संचालित किया जा सकता है।
स्थिर वोल्टेज और फ्रीक्वेंसी: यह एक स्थिर थ्री फेज वोल्टेज और फ्रीक्वेंसी प्रदान करता है।
नुकसान:
प्रारंभिक लागत: सेटअप की प्रारंभिक लागत अधिक हो सकती है।
ऊर्जा दक्षता: कुछ ऊर्जा का नुकसान होता है क्योंकि मोटर और जेनरेटर दोनों में ऊर्जा की खपत होती है।
रखरखाव: मोटर और जेनरेटर की नियमित देखभाल और रखरखाव की आवश्यकता होती है।
वैकल्पिक विकल्प:
स्टेटिक फेज कनवर्टर: यह उपकरण इलेक्ट्रॉनिक घटकों का उपयोग करके सिंगल फेज पावर को थ्री फेज पावर में बदलते हैं।
वैरिएबल फ्रीक्वेंसी ड्राइव (VFD): यह डिवाइस सिंगल फेज इनपुट पावर को थ्री फेज आउटपुट पावर में कन्वर्ट करता है और मोटर की स्पीड को भी कंट्रोल करता है।

​@@NiketShahPlushindi language nahi ata hain ..hindi ko English mein lekheyega sir

Aapka sawal bilkul sahi hai aur bahut hi achha hai. Chaliye, isse samajhne ki koshish karte hain.
Jab bijli ghar se bijli generate ki jaati hai, to bijli banane ka cost do cheezon par depend karta hai:
Fixed cost: Jaise bijli banane ki machines (generators), power plant ke employees, plant ka maintenance, etc. Yeh cost hamesha hota hai, chahe bijli kitni bhi bani ho.
Variable cost: Yeh cost bijli banane ke liye lagti hai, jaise fuel cost (coal, gas, diesel), ya renewable energy sources (solar, wind). Bijli jitni zyada bani, fuel ya energy source ka use utna hi zyada hoga, to yeh cost badh jaayegi.
Agar 50 ghar bijli ka istemal karte hain, to power plant ko jitni bijli ki zarurat hai, utni produce karni padti hai. Uske liye fuel ya energy sources ka use zyada hota hai, isliye variable cost badh jaati hai.
Agar sirf 10 ghar bijli ka use karte hain aur baaki 40 ghar nahi karte, to bijli ki demand kam ho jaati hai. Isliye power plant ko kam bijli generate karni padti hai, aur is wajah se fuel ya energy source ka use bhi kam hoga, to variable cost kam ho jaayegi. Lekin fixed cost wahi rahegi, kyunki machines, employees, aur maintenance ka kharcha hamesha lagta rahega, chahe demand ho ya na ho.
Toh conclusion yeh hai:
Fixed cost hamesha same rahega, chahe 10 ghar bijli use karein ya 50 ghar.
Variable cost kam ya zyada ho sakta hai, jo bijli ke use ke hisaab se badhta ya ghata hai.
Isliye agar kam log bijli use kar rahe hain, to bijli banane ka total kharcha kam hoga kyunki variable cost kam ho jaayegi, lekin fixed cost wahi rahegi.

You are wrong understand yes I know Vfd are working 800+ kw but it's 3 phase Vfd. He says single phase Vfd. Single phase Vfd only small motors running or small machines load motors running limit only not heavy motors run. I think you understand.

Who uses a single phase motor for heavy duty application?Go and clear your concepts first.

You are correct

Yes, your understanding is correct. Railways often use Variable Frequency Drives (VFDs) to convert single-phase power into three-phase power. Here's how it works:
Railway Power System Overview:
Single-Phase Power Supply: The overhead lines (via the pantograph) in electric trains typically provide single-phase AC power. This is because transmitting high-voltage single-phase power is more efficient over long distances.
Three-Phase Motors: The traction motors that drive the train are typically three-phase AC motors. Three-phase motors are preferred due to their efficiency, smooth operation, and better power distribution.
Conversion Process:
Rectification: The single-phase AC power collected from the overhead lines is first converted to DC power using a rectifier. This step is necessary because a VFD typically operates by first converting incoming AC power to DC.
Inversion: The DC power is then converted back to three-phase AC power using an inverter. The inverter generates three-phase power at the required frequency and voltage to drive the traction motors.
Control: The VFD controls the frequency and voltage of the output power, allowing for smooth acceleration and deceleration of the train, as well as precise control over speed and torque.
Benefits:
Efficiency: Converting single-phase power to three-phase allows for the use of more efficient three-phase motors.
Control: VFDs provide precise control over motor speed and torque, which is crucial for railway applications.
Flexibility: The system can adapt to different power supply conditions and still provide the necessary power to the traction motors.

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1. Direct Single-Phase Connection
Agar aapke paas three-phase supply hai, to aap usme se ek single-phase (do wires) directly le sakte hain.
Connection: Ek phase aur neutral le kar load ko connect karte hain.
Example: Agar three-phase supply R (Red), Y (Yellow), aur B (Blue) hai, to aap R aur neutral (N) use kar sakte hain.
Limitation: Aapko load balance karna padega, taki har phase par equal load aaye.
**2. Phase Converter (Static or Rotary)
Static Phase Converter:
Is device ka use karke three-phase ko single-phase mein convert kiya ja sakta hai.
Mostly motor applications ke liye use hota hai.
Rotary Phase Converter:
Ye ek motor aur generator system hota hai jo single-phase supply produce karta hai.
Zyada reliable aur efficient hota hai.
**3. Transformer-based Method
Agar high voltage ko single-phase chahiye, to step-down transformer ka use karke ek single-phase system banaya ja sakta hai.
Connection: Three-phase ka ek ya do phase use karke transformer input mein diya jata hai aur output single-phase mein liya jata hai.
**4. VFD (Variable Frequency Drive)
VFD ka use karke three-phase input ko single-phase output mein convert kiya ja sakta hai.
Mostly motor speed control applications ke liye use hota hai.
Ye voltage aur frequency control kar sakta hai.

1horse power hp =33.000 foot.pounfs ft-ibpermin=550fb per sec =746 watts =2545 british thermsl units btu per hour (h

1horse power hp =33.000 foot.pounfs ft-ibpermin=550fb per sec =746 watts =2545 british thermsl units btu per hour (h

1horse power hp =33.000 foot.pounfs ft-ibpermin=550fb per sec =746 watts =2545 british thermsl units btu per hour (h

Hr.. one horse power -hour hp -hr =1hp for 1hr.

=746 watthours (whr)=2545btu1kilowattkw)=1.000watts =1.000watts==1.34hp. 1kilowatt-hour kwhr.=1kwfor 1hr...=1.000whr.=1.34hp-hr.=3415btu1british ther unit btu =778ft-lbok thix allpoint baicsl ok ac

Yes, capacitors and inductors have different properties and are used in various applications based on these properties. Here’s a brief overview of the advantages and disadvantages of using capacitors versus inductors:
Inductors:
Advantages:
Energy Storage: Inductors store energy in the form of a magnetic field, which can be useful in applications like transformers and inductive power transfer.
Filtering: Inductors can be used in filters to block high-frequency signals and allow low-frequency signals to pass (low-pass filters).
Current Smoothing: Inductors smooth out fluctuations in current, which is beneficial in power supplies.
Disadvantages:
Size and Weight: Inductors can be bulky and heavy, especially for high-power applications.
Magnetic Interference: Inductors can generate magnetic fields that may interfere with other nearby electronic components.
Lagging Power Factor: Inductors cause a lagging power factor, which can be a disadvantage in AC power systems because it reduces the efficiency of power transmission.
Capacitors:
Advantages:
Size and Weight: Capacitors are generally lighter and more compact compared to inductors.
Leading Power Factor: Capacitors cause a leading power factor, which can help to correct a lagging power factor in AC power systems, improving the overall efficiency.
Energy Storage: Capacitors store energy in the form of an electric field, which is useful in applications like power conditioning, signal coupling, and decoupling.
Disadvantages:
Voltage Lead: While the leading power factor can be an advantage, it can also be a disadvantage in certain applications where precise phase alignment is required.
Limited Energy Storage: Capacitors typically store less energy than inductors of comparable size.
Frequency Sensitivity: Capacitors can block DC signals while allowing AC signals to pass, which might not be desirable in all applications.

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single phase for home use..3 phase according to your motor HP

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correct.. check the comments section for more details.. do share this video with others

yes but need to check its capacity first

kya?

A rotary phase converter is typically used to convert single-phase power (like the standard 220V supply) into three-phase power. In single-phase systems, you have L1 (live) and N (neutral), which together provide 220V. But in a rotary phase converter system, two legs, typically referred to as L1 and L2, represent the two-phase output, but it's not the same as a true single-phase system (L1 and N).
Here's how it works:
In a single-phase system, you have L1 and Neutral (N), which together give you 220V.
In a rotary phase converter, it generates a third phase (L3) in addition to the two input phases (L1 and L2), which allows it to supply three-phase power (L1, L2, L3).
So, when you say L1 and L2 are available but not single-phase, it might mean the rotary converter is giving you a two-phase supply without neutral, which is part of a three-phase system. To get back to true single-phase 220V, you would need an L1 and Neutral (N) connection, which rotary converters usually don't supply directly because their purpose is to provide three-phase power.
In short:
Single-phase 220V: L1 and N (Live and Neutral).
Rotary phase converter: Produces L1, L2, and L3 for three-phase power, but doesn't use Neutral (N) as in a typical single-phase system.
If you need single-phase power, you'd need to connect L1 to Neutral (N), but this setup isn't typically what a rotary phase converter is designed for.

To address your issue of battery drainage in the evening and the inability to use your single-phase connection to charge your batteries through your three-phase inverter, here's a solution that could work for your setup:
Understanding the Setup:
Three-Phase Off-Grid Solar System: Your system is designed to generate and supply three-phase power, which is suitable for running heavy machinery.
Battery Drain: The batteries are getting drained by the evening because the solar power might not be sufficient to run your machines and charge the batteries simultaneously.
Single-Phase Grid Connection: You have a single-phase grid connection available, but you need to convert it to be usable with your three-phase inverter for battery charging.
Recommended Solution:
Single-Phase to Three-Phase Converter:
Purpose: This converter will take your single-phase input and convert it into three-phase output, which can then be supplied to your three-phase inverter.
Types of Converters:
Rotary Phase Converter: Suitable for heavy-duty applications where you need to convert single-phase power to three-phase power efficiently.
Static Phase Converter: More affordable but typically less efficient and not ideal for long-term heavy usage.
Digital Phase Converter: Modern solution that offers better efficiency, stability, and power quality compared to rotary and static converters.
Inverter Compatibility:
Before purchasing any converter, ensure that your inverter can accept a three-phase input generated by such a converter. Some inverters are sensitive to the quality of the input power, so it’s crucial to check the specifications or consult the inverter manufacturer.
VFD (Variable Frequency Drive):
Not Suitable for Your Case: As you correctly mentioned, a VFD is primarily used to control the speed of motors and is not intended for converting single-phase power to three-phase power for the purpose of feeding an inverter.
Implementation Steps:
Consult with an Electrician: Get a professional electrician to assess the power requirements of your inverter and help you select the appropriate single-phase to three-phase converter. They can ensure that the converter you choose is compatible with your inverter.
Install the Converter: Have the converter installed between your single-phase grid connection and the inverter’s input. Ensure all connections are properly made and safety protocols are followed.
Monitor Performance: After installation, monitor the system’s performance to ensure that the batteries are being charged effectively and that there are no issues with the inverter’s operation.
Alternative Solution:
If upgrading to a three-phase grid connection is feasible, this would eliminate the need for a converter altogether and provide a more stable and efficient power supply to your inverter for battery charging.

CNC machines ke turret motor me DPS (Direct Power Supply) power supply ka istemal ho sakta hai, lekin iske specifics depend karte hain machine ke design aur manufacturer pe. Turret motor ko accurately control karne ke liye stable aur precise power supply ki zarurat hoti hai, aur DPS power supply ek aisa option ho sakta hai.

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will try to make video on this topic

It’s different technique.. will try to make video on this also

@@NiketShahPlus ok

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Then why capacitors are not used in 3 phase motors to manage power factor ۔ basically they are used in single phase motors for phase shif to produce field lines in coil ۔ and capacitors also have a property to control power factor

यदि ह तो क्या मोटर या अन्य उपकरणों को phase चाहिए neutral नहीं चाहिए

यदि हम बल्ब को phase दे तो खराब हो जाएगा

मोटर तीन phase पर कैसे चलता है न्यूट्रल नहीं चाहिए इसे ।
क्या 3 फैंस में कोई different होता हैं

Example फ्रीक्वेंसी , voltage etc.

लो!
जी हां, अगर आपके पास T/F (ट्रांसफार्मर) से केवल दो वायर आ रहे हैं - एक फेज (Phase) और एक न्यूट्रल (Neutral) - तो इसे सिंगल फेज सप्लाई कहते हैं। सिंगल फेज सिस्टम में सिर्फ एक ही फेज होता है और इसे घरेलू उपकरणों में इस्तेमाल किया जाता है।
सिंगल फेज को 3-फेज में कन्वर्ट करने के लिए आमतौर पर एक फेज कन्वर्टर का उपयोग किया जाता है। फेज कन्वर्टर अलग-अलग प्रकार के होते हैं, जैसे कि:
रोटरी फेज कन्वर्टर - यह एक मोटर की तरह काम करता है और एक सिंगल फेज इनपुट से तीन फेज आउटपुट देता है।
स्टैटिक फेज कन्वर्टर - यह थोड़ी देर के लिए मोटर को चालू करने के लिए आवश्यक तीसरे फेज को उत्पन्न करता है, लेकिन यह हर समय तीन फेज आउटपुट नहीं देता।
वीएफडी (Variable Frequency Drive) - यह एक इलेक्ट्रॉनिक कन्वर्टर है जो इनपुट को बदलकर तीन फेज आउटपुट प्रदान करता है और गति भी नियंत्रित कर सकता है।
आपको किस प्रकार का फेज कन्वर्टर चाहिए, यह आपके उपयोग और आवश्यकताओं पर निर्भर करेगा।

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depends upon the product you have purchasesd

आपका सवाल बहुत दिलचस्प है! कैपेसिटर (capacitor) एक इलेक्ट्रॉनिक घटक है जो विद्युत ऊर्जा को स्टोर करने के लिए उपयोग किया जाता है। आइए इसे स्पष्ट रूप से समझते हैं:
ऊर्जा स्टोर करना: कैपेसिटर एक इलेक्ट्रिक चार्ज को स्टोर करता है। जब आप इसे बिजली के स्रोत से जोड़ते हैं, तो यह चार्ज को अपने दो ध्रुवों (plates) के बीच स्टोर करता है।
चार्ज छोड़ना: जब कैपेसिटर को किसी सर्किट में जोड़ा जाता है, तो यह स्टोर की गई ऊर्जा को रिलीज़ कर देता है। इससे विद्युत सर्किट में आवश्यकतानुसार ऊर्जा प्रवाहित होती है।
पुनरावृत्ति: कैपेसिटर का यह चार्ज और डिस्चार्ज प्रक्रिया अनवरत चलती रहती है, यानी जब तक कैपेसिटर चार्ज होता है, वह ऊर्जा स्टोर करता रहता है और जब डिस्चार्ज होता है, तो ऊर्जा सर्किट में प्रवाहित होती है।
संवेदनशीलता: कैपेसिटर की क्षमता (capacitance) बताती है कि वह कितनी ऊर्जा स्टोर कर सकता है। इसका मूल्य 'फैराड्स' (Farads) में मापा जाता है।
कैपेसिटर का उपयोग विभिन्न विद्युत सर्किट्स में किया जाता है, जैसे कि फिल्टर सर्किट्स, स्टेबलाइजर्स, और सिग्नल प्रोसेसिंग में। यह विद्युत ऊर्जा को नियंत्रित करने और स्थिरता बनाए रखने में सहायक होता है।

Ham Hindi classes nahi le rahe

We will try but do share this videos with others also

yes.. also other use as well

thanks .. do share this video with others..

will try to make video on this

5HP agriculture 3-phase submersible pump ke liye best option ka selection karte waqt aapko kai factors par dhyan dena chahiye:
1. Pump Type and Application:
Borewell Submersible Pump: Ye narrow bores ke liye hoti hai, jahan depth zyada hoti hai.
Openwell Submersible Pump: Ye shallow wells ya open water sources ke liye hoti hai.
2. Motor and Build Quality:
Copper Winding Motor: Copper winding motors zyada durable hote hain aur zyada efficient hote hain.
Stainless Steel Body: Stainless steel se bane pumps zyada durable hote hain aur corrosion-resistant hote hain, jo unhe long-lasting banata hai.
3. Brand and Service Support:
Renowned Brands: Kirloskar, Crompton, Texmo, V-Guard, CRI, Lubi, etc., reliable brands hain jo quality products aur after-sales service provide karte hain.
Warranty and Service Centers: Warranty period aur nearby service centers bhi check karna zaroori hai, taaki maintenance aur repairs aasani se ho sake.
4. Head and Flow Rate:
Total Head: Pump ki required head height dekhni chahiye, jo ki aapke well ya borewell ki depth par depend karegi.
Flow Rate: Pump ka flow rate bhi important hai, jo aapki irrigation ya water needs par depend karta hai.
5. Energy Efficiency:
Energy-Efficient Models: ISI mark ya 5-star rated pumps zyada energy efficient hote hain, jo aapki bijli ki khapat ko kam karte hain aur long-term mein cost-effective hote hain.
6. Voltage Fluctuation Handling:
Voltage Fluctuation Compatibility: Agricultural areas mein voltage fluctuation common hai, to aapko aisa pump select karna chahiye jo wide voltage range handle kar sake.
Recommendation:
Kirloskar KP4 Jalraaj-5010 5HP 3 Phase Borewell Submersible Pump aur CRI 5HP 3 Phase Submersible Pump acchi choices hain jo aapke liye kaam karengi. Yeh pumps reliable brands ke hain aur inki market reputation achchi hai.
Pump select karte waqt aap apni specific needs jaise well depth, water requirement, aur electricity conditions ko dhyan mein rakhkar final decision le sakte hain. Agar aapko aur details chahiye ya koi specific requirement hai, to batayiye, main aur madad karunga.

@@NiketShahPlus open well submersible, copper winding, no voltage fluctuations due to Special Transformer for Special motor(under maharashtra govt.scheme),motor head also good i think 72mm, main pipeline siZe 90mm, already i using capacitors 144mfd+50mfd, but flow of water half compare to real 3phase power flow. So I want increase voltage as well as water flow of pump.thanks

@@avinashsonawane6952 Check Electrical Connections: Ensure all electrical connections are secure and free from corrosion. Loose or damaged connections can reduce voltage and impact pump performance.
Verify Transformer Output: Confirm that the special transformer you're using is correctly rated for your pump. It should provide a stable and sufficient voltage output for your motor. If it's not delivering the right voltage, it might be worth having it tested or replaced.
Assess Capacitor Configuration: The capacitors you're using (144 µF + 50 µF) should match the specifications recommended for your motor. Ensure they are functioning properly. Sometimes, adjusting the capacitor values can help optimize performance. Consult the motor’s manual or a technician for the appropriate capacitor specifications.
Inspect Pump and Piping: Check the pump and piping for any blockages or damage. Even minor obstructions can significantly impact water flow. Ensure that the pump is fully submerged and the intake is clear.
Examine the Pump Head: A 72mm motor head size is relatively standard, but ensure it’s suitable for your specific pump and application. If the pump head is not designed for your requirements, it might affect performance.
Review Pipeline Size: The main pipeline size of 90mm should generally be sufficient for good flow, but ensure that the pipe is not partially blocked or damaged.
Check Voltage Supply: Measure the voltage supplied to the pump to confirm it's consistent with the pump’s requirements. Fluctuations or insufficient voltage can reduce performance.
Consult a Professional: If you've gone through these checks and are still experiencing issues, it might be best to consult a professional who can diagnose the problem in person. They can check for issues with the transformer, motor, or pump system more accurately.
Increasing the voltage alone may not solve the problem if there are underlying issues with the pump or system setup. Addressing the overall setup and ensuring everything is in proper working order is crucial for optimal performance.

will try to make video on this topic

many more things it can do check the comments

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ok will try to make video on this topic as well in future

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Ac dcenergy ower tables loredv whatis energy s in the simplest terms energy isthe ability to perform work it may exist in several froms such as heat energy ., maechanical energy ehemicsl energy or electricsl chemical energy in a storge battery become electrical energy flowing through a circuit that lights a lamp .light energy and heat energy .or from to anther .dnergy can not be creeated or de stroyed . So the same relation shipes of energy transformation slways apply

Table energy relation ships .

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आपके सवाल से यह समझ आता है कि आप एक पुराने तरीके के बारे में पूछ रहे हैं जिसमें आपका दोस्त एक फेज से तीन फेज में वोल्टेज प्राप्त करता था लेकिन एम्पियर नहीं मिलते थे, और इसमें कैपेसिटर का उपयोग भी शामिल था।
ट्रांसफार्मर और कैपेसिटर का उपयोग
ट्रांसफार्मर और कैपेसिटर का उपयोग करके कुछ हद तक सिंगल फेज को तीन फेज में बदलना संभव है, लेकिन इसमें सीमित क्षमताएं होती हैं और यह पूरी तरह से प्रभावी नहीं होता है। आइए देखते हैं कैसे:
1. कैपेसिटर फेज कनवर्ज़न
कैपेसिटर का उपयोग: कैपेसिटर का उपयोग करके सिंगल फेज से तीन फेज मोटर को चालू किया जा सकता है। यह विधि मुख्य रूप से मोटर्स को चलाने के लिए होती है, जिसमें कैपेसिटर को सिंगल फेज सप्लाई में जोड़ा जाता है ताकि तीसरे फेज का सिमुलेशन किया जा सके।
सीमाएँ: यह तरीका लंबे समय तक भारी लोड पर काम नहीं कर पाता और यह केवल अस्थायी समाधान के रूप में उपयुक्त है। वोल्टेज मिल सकता है लेकिन करंट (एम्पियर) की सीमाएँ होती हैं।
2. फेज कन्वर्टर
रोटरी फेज कन्वर्टर: यह एक प्रकार का मोटर जनरेटर है जो सिंगल फेज को तीन फेज में बदलता है। इसमें एक सिंगल फेज मोटर और तीन फेज जनरेटर शामिल होते हैं। यह तरीका अधिक प्रभावी और भरोसेमंद है।
स्टेटिक फेज कन्वर्टर: इसमें कैपेसिटर और इलेक्ट्रॉनिक सर्किट का उपयोग होता है ताकि सिंगल फेज सप्लाई को तीन फेज में बदलने के लिए उपयोग किया जा सके।
3. वैरिएबल फ्रिक्वेंसी ड्राइव (VFD)
VFD का उपयोग: VFD सिंगल फेज इनपुट को तीन फेज आउटपुट में बदलता है। यह इलेक्ट्रॉनिक उपकरण है जो AC वोल्टेज को DC में कन्वर्ट करता है और फिर इसे तीन फेज AC वोल्टेज में इन्वर्ट करता है। यह तरीका सबसे अधिक प्रभावी और आधुनिक है।
कैपेसिटर का सही उपयोग
कैपेसिटर ऊर्जा को अस्थायी रूप से स्टोर करते हैं और इसे रिलीज करते हैं। जब कैपेसिटर का उपयोग किसी फेज कन्वर्ज़न सर्किट में होता है, तो यह महत्वपूर्ण होता है कि:
चार्जिंग और डिस्चार्जिंग: कैपेसिटर को उपयोग में लेने से पहले चार्ज और डिस्चार्ज करना आवश्यक होता है। अगर कैपेसिटर पूरी तरह चार्ज नहीं होता, तो इसका उपयोग प्रभावी नहीं होगा।
सुरक्षा: अगर कैपेसिटर में स्टोर ऊर्जा का ध्यान नहीं रखा गया, तो इलेक्ट्रिक शॉक का खतरा हो सकता है।
निष्कर्ष
सिंगल फेज से तीन फेज में कन्वर्ज़न के लिए केवल ट्रांसफार्मर का उपयोग पर्याप्त नहीं है। इसके लिए रोटरी या स्टेटिक फेज कन्वर्टर, या VFD जैसे उपकरण का उपयोग करना चाहिए। कैपेसिटर का उपयोग भी एक सीमा तक ही किया जा सकता है और सही तरीके से चार्ज और डिस्चार्ज करना जरूरी है ताकि सुरक्षा और प्रभावशीलता बनी रहे।

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do many work will try to make video on this topic

Capacitor frequency change and voltage control systems are related concepts in electrical engineering, especially in circuits where capacitors play a crucial role. However, they serve different functions and operate under different principles.
Capacitor and Frequency Relationship
Frequency Response:
Capacitors in a circuit affect how the circuit responds to different frequencies. The impedance (resistance to AC) of a capacitor is inversely proportional to the frequency of the signal passing through it, given by the formula:
ZC=12πfC
ZC​=2πfC1​
where ZCZC​ is the impedance, ff is the frequency, and CC is the capacitance.
At higher frequencies, the impedance of a capacitor decreases, allowing more current to pass through, and vice versa.
Resonant Frequency:
In LC (inductor-capacitor) circuits, capacitors contribute to determining the resonant frequency, where the circuit naturally oscillates. The resonant frequency f0f0​ is given by:
f0=12πLC
f0​=2πLC
​1​
where LL is the inductance and CC is the capacitance.
Voltage Control with Capacitors
Voltage Regulation:
Capacitors can be used in voltage control systems to smooth out voltage fluctuations. For example, in power supplies, capacitors are used to filter out AC ripples, providing a more stable DC output.
In AC circuits, capacitors can help control the voltage by providing reactive power, which can correct the power factor and improve voltage regulation.
Phase Shift and Power Factor Correction:
Capacitors can also be used to shift the phase of the voltage and current in AC circuits. This is particularly useful in power factor correction, where capacitors are added to improve the efficiency of power delivery in AC power systems.
Are They Equal?
Capacitor frequency change and voltage control systems are not equal but are interconnected. Capacitors influence the frequency response of circuits and can be used to control voltage in various applications. However, frequency change specifically refers to how capacitors affect the behavior of a circuit at different frequencies, while voltage control refers to how capacitors help maintain a stable voltage.
If you are asking about a specific application or circuit where both these concepts come into play, please provide more details, and I can give a more targeted explanation.

Variable Frequency Drives (VFDs) are typically used to control the speed and torque of three-phase AC motors by varying the frequency and voltage supplied to the motor. In the context of inverter model air conditioners (ACs) and refrigerators, VFDs play a crucial role in controlling the compressor motor, which is often connected via UVW terminals.
VFD in Inverter Model AC or Fridge:
Compressor Control: Inverter model air conditioners and refrigerators use a VFD to control the speed of the compressor motor. This allows the compressor to run at variable speeds, which is more energy-efficient compared to traditional systems that run at a fixed speed.
UVW Terminals: The UVW terminals on the compressor are the three-phase connections for the motor windings. The VFD generates a three-phase output with adjustable frequency and voltage that is supplied to these terminals, allowing for precise control of the compressor motor's operation.
How It Works:
Power Conversion: The VFD first converts the incoming AC power (usually single-phase or three-phase) into DC using a rectifier.
DC to Variable AC: This DC is then converted back to AC with variable frequency and voltage using an inverter circuit within the VFD.
Motor Control: The variable AC power is sent to the compressor motor's UVW terminals, enabling the motor to operate at different speeds. The speed is controlled based on the cooling demand, leading to more efficient operation and less wear on the compressor.

matlab?

Power factor improvement - System efficiency badhata hai aur electricity cost reduce karta hai.
Voltage regulation - Stable voltage maintain karta hai, especially heavy inductive loads ke saath.
Harmonic filtering - System ke harmonics ko filter karta hai aur equipment ki life badhata hai.
Motor starting - Three-phase motors ka starting torque improve karta hai.
Isliye, three-phase systems mein capacitor ka kaam bahut critical hota hai for smooth and efficient operation.

Yes, an inverter (often abbreviated as "Invt") that converts single-phase power to three-phase power is commonly used in various applications. These devices are especially useful for operating three-phase motors and equipment in environments where only single-phase power is available.

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Wrong ۔ then why capacitors are not used in heavy 3 phase motors ۔basically capacitors are used in AC systems to produce phase shif and in in power supply and inverters they are used to store energy

Pehle to energy store karenge na baad me shift hoga .wrong kaise hua

good.. check comments for more details

Motor ka neutral connection kaise aur kahaan se milega, ye motor ke type aur wiring scheme par depend karta hai. Yahan kuch common scenarios hain:
Single-Phase Motor:
Neutral Wire: Single-phase motors mein, neutral wire usually power supply se connected hota hai. Aapko motor ke terminal box ya junction box me neutral wire dhoondhna hoga, jo generally white ya blue color ka hota hai.
Three-Phase Motor:
Neutral Wire: Three-phase motors typically neutral ka use nahi karte, kyunki yeh balanced load ke saath operate karte hain. Lekin agar motor ek star connection me ho, toh neutral wire ka connection star point se hota hai.
Where to Find:
Motor Terminal Box: Motor ke terminal box me, usually motor ke wires (L1, L2, L3 aur Neutral) clearly labeled hote hain.
Wiring Diagram: Motor ke wiring diagram ko refer karein, jo aapko neutral wire location aur connections ke details provide karega.

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Using a transformer alone to convert single-phase power to three-phase power is not feasible due to the fundamental differences in the nature of single-phase and three-phase electrical power. Here are the key reasons why a transformer alone cannot achieve this conversion:
Nature of Single-Phase and Three-Phase Power:
Single-Phase Power: Consists of a single alternating voltage wave, with current flowing in one phase wire and returning through a neutral wire.
Three-Phase Power: Consists of three alternating voltage waves, each 120 degrees out of phase with the others, providing a more balanced and continuous power supply.
Phase Relationship:
A transformer cannot create the necessary 120-degree phase shift between the three phases needed for three-phase power from a single-phase input. Transformers only change voltage levels; they do not create additional phases or alter the phase relationship between input and output.
Balanced Load Distribution:
Three-phase power systems distribute the electrical load more evenly across the phases, reducing the load on any single phase and improving efficiency. Single-phase power cannot provide this balanced distribution.

2-phase power cannot be directly converted into 3-phase power, but there are methods to operate a 3-phase motor, like your 20 HP motor, using a 2-phase supply. Here are a few common methods:
1. Rotary Phase Converter:
A rotary phase converter is a device that converts single-phase or 2-phase power to 3-phase power. It uses a motor-generator setup to generate the third phase. This is a common solution for running large motors like a 20 HP motor.
2. Static Phase Converter:
A static phase converter can also be used, but it is less efficient and is typically used for smaller motors. It creates a third phase by using capacitors to provide a temporary boost during startup. However, it doesn’t provide true 3-phase power, and the motor will not run at full capacity.
3. Variable Frequency Drive (VFD):
A VFD is a solid-state device that converts single-phase or 2-phase power into 3-phase power and also allows you to control the motor speed. For a 20 HP motor, you would need a VFD that can handle the power requirements. VFDs are efficient and offer the added benefit of speed control.
4. Phase Converting Transformer:
Another option is to use a phase converting transformer, which is specially designed to convert 2-phase power into 3-phase power. This is less common but can be effective for specific setups.

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