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Oct 26, 2014 Transformator Tesla Taleh Ismayil. Unsubscribe from Taleh Ismayil? This feature is not available right now. Please try again later. Published on Oct 26, 2014.
This is my first Solid State Tesla Coils (SSTC) with 555 timer IC and single IRFP450 MOSFET (555 timer running an SSTC) Schematic by me: For the Connection or Power Supply: run at 70 Volts AC & spark is 8cm. This is a different SSTC!! I work with this almost 7 Months. I got a pop MOSFET (overload) because somes wrong coupling or over voltage input.
And i tune the 555 frequency and primary coil winding very details to get a best Resonant frequency. And i put somes gate driver with 2 MOSFET (in schematic is BDs transistor but in videos im using a IRFs MOSFET). Now i got great results. ------------------------------------------------------------------------------------------ data of coils: Frequency: 350 kHz (around) Secondary Coil: 6 X 18.5 cm with 0,12mm wire Primary Coil: 9 X 3.8 cm. 15 turns with 3cm upwards. 1mm wire with 2mm insulation Cable. Power Supply: 70V AC + Single 6A Diode + 940nF 250V MKP Capacitors (Half Wave Rectified) ------------------------------------------------------------------------------------------ songs: Facebook Group: My Facebook: @idhamabdulhadi.
The ‘NE555’ Timer Chip There is an exceptionally useful chip designated by the number 555. This chip is designed to be used in oscillator and timer circuits. Its use is so widespread that the chip price is very low for its capability.
It can operate with voltages from 5 Volts to 18 Volts and its output can handle 200 mA. It takes 1 mA when its output is low and 10 mA when its output is high. Shablon dlya oformleniya yubilejnogo adres. It comes in an 8-pin Dual-In-Line package and there is a 14-pin package version which contains two separate 555 circuits.
The pin connections are: This device can operate as a monostable or astable multivibrator, a Schmitt trigger or an inverting buffer (low current input, high current output). Here it is wired as a Schmitt trigger, and for variation, it is shown triggering a triac which will then stay on until the circuit is powered down (an SCR could be used just as well with this DC circuit): And here, a monostable: And here are two astables, the second of which has fixed, equal mark/space ratio and the first a high output voltage time determined by Ra + Rb and a low voltage output time determined by Rb (2:1 in this case): Note: The high leakage of large value electrolytic capacitors prevents them being used with high value resistors in timing circuits. Instead, use a smaller capacitor and follow the timing circuit with a “divide-by-N” chip to give accurately timed long periods. Not all 555 chips have a manufacturing quality sufficient for them to operate reliably above 20,000 Hz, so for the higher frequencies the chip needs to be selected after testing its actual performance. We can also wire the 555 to give a variable mark/space ratio while holding the frequency of the oscillation fixed: The output waveform changes drastically as the variable resistor is adjusted, but the frequency (or pitch of the note) of the output stays unaltered. A variable-frequency version of this circuit can be produced by changing the 33K resistor to a variable resistor as shown here: Here, the 33K resistor has been replaced by two variable resistors and one fixed resistor.
The main variable resistor is 47K in size (an almost arbitrary choice) and it feeds to a second variable resistor of 4.7K in size. The advantage of this second variable resistor is that it can be set to it’s mid point and the frequency tuning done with the 47K variable.
When the frequency is approximately correct, the 4.7K variable can be used to fine tune the frequency. This is convenient as the small variable will have ten times more knob movement compared to the main variable (being just 10% of its value). Obviously, it is not necessary to have the fine-tuning variable resistor, and it can be omitted without changing the operation of the circuit.
Oct 26, 2014 Transformator Tesla Taleh Ismayil. Unsubscribe from Taleh Ismayil? This feature is not available right now. Please try again later. Published on Oct 26, 2014.
This is my first Solid State Tesla Coils (SSTC) with 555 timer IC and single IRFP450 MOSFET (555 timer running an SSTC) Schematic by me: For the Connection or Power Supply: run at 70 Volts AC & spark is 8cm. This is a different SSTC!! I work with this almost 7 Months. I got a pop MOSFET (overload) because somes wrong coupling or over voltage input.
And i tune the 555 frequency and primary coil winding very details to get a best Resonant frequency. And i put somes gate driver with 2 MOSFET (in schematic is BDs transistor but in videos im using a IRFs MOSFET). Now i got great results. ------------------------------------------------------------------------------------------ data of coils: Frequency: 350 kHz (around) Secondary Coil: 6 X 18.5 cm with 0,12mm wire Primary Coil: 9 X 3.8 cm. 15 turns with 3cm upwards. 1mm wire with 2mm insulation Cable. Power Supply: 70V AC + Single 6A Diode + 940nF 250V MKP Capacitors (Half Wave Rectified) ------------------------------------------------------------------------------------------ songs: Facebook Group: My Facebook: @idhamabdulhadi.
The ‘NE555’ Timer Chip There is an exceptionally useful chip designated by the number 555. This chip is designed to be used in oscillator and timer circuits. Its use is so widespread that the chip price is very low for its capability.
It can operate with voltages from 5 Volts to 18 Volts and its output can handle 200 mA. It takes 1 mA when its output is low and 10 mA when its output is high. Shablon dlya oformleniya yubilejnogo adres. It comes in an 8-pin Dual-In-Line package and there is a 14-pin package version which contains two separate 555 circuits.
The pin connections are: This device can operate as a monostable or astable multivibrator, a Schmitt trigger or an inverting buffer (low current input, high current output). Here it is wired as a Schmitt trigger, and for variation, it is shown triggering a triac which will then stay on until the circuit is powered down (an SCR could be used just as well with this DC circuit): And here, a monostable: And here are two astables, the second of which has fixed, equal mark/space ratio and the first a high output voltage time determined by Ra + Rb and a low voltage output time determined by Rb (2:1 in this case): Note: The high leakage of large value electrolytic capacitors prevents them being used with high value resistors in timing circuits. Instead, use a smaller capacitor and follow the timing circuit with a “divide-by-N” chip to give accurately timed long periods. Not all 555 chips have a manufacturing quality sufficient for them to operate reliably above 20,000 Hz, so for the higher frequencies the chip needs to be selected after testing its actual performance. We can also wire the 555 to give a variable mark/space ratio while holding the frequency of the oscillation fixed: The output waveform changes drastically as the variable resistor is adjusted, but the frequency (or pitch of the note) of the output stays unaltered. A variable-frequency version of this circuit can be produced by changing the 33K resistor to a variable resistor as shown here: Here, the 33K resistor has been replaced by two variable resistors and one fixed resistor.
The main variable resistor is 47K in size (an almost arbitrary choice) and it feeds to a second variable resistor of 4.7K in size. The advantage of this second variable resistor is that it can be set to it’s mid point and the frequency tuning done with the 47K variable.
When the frequency is approximately correct, the 4.7K variable can be used to fine tune the frequency. This is convenient as the small variable will have ten times more knob movement compared to the main variable (being just 10% of its value). Obviously, it is not necessary to have the fine-tuning variable resistor, and it can be omitted without changing the operation of the circuit.
...'>Transformator Tesla Na Ne555(06.09.2018)Oct 26, 2014 Transformator Tesla Taleh Ismayil. Unsubscribe from Taleh Ismayil? This feature is not available right now. Please try again later. Published on Oct 26, 2014.
This is my first Solid State Tesla Coils (SSTC) with 555 timer IC and single IRFP450 MOSFET (555 timer running an SSTC) Schematic by me: For the Connection or Power Supply: run at 70 Volts AC & spark is 8cm. This is a different SSTC!! I work with this almost 7 Months. I got a pop MOSFET (overload) because somes wrong coupling or over voltage input.
And i tune the 555 frequency and primary coil winding very details to get a best Resonant frequency. And i put somes gate driver with 2 MOSFET (in schematic is BDs transistor but in videos im using a IRFs MOSFET). Now i got great results. ------------------------------------------------------------------------------------------ data of coils: Frequency: 350 kHz (around) Secondary Coil: 6 X 18.5 cm with 0,12mm wire Primary Coil: 9 X 3.8 cm. 15 turns with 3cm upwards. 1mm wire with 2mm insulation Cable. Power Supply: 70V AC + Single 6A Diode + 940nF 250V MKP Capacitors (Half Wave Rectified) ------------------------------------------------------------------------------------------ songs: Facebook Group: My Facebook: @idhamabdulhadi.
The ‘NE555’ Timer Chip There is an exceptionally useful chip designated by the number 555. This chip is designed to be used in oscillator and timer circuits. Its use is so widespread that the chip price is very low for its capability.
It can operate with voltages from 5 Volts to 18 Volts and its output can handle 200 mA. It takes 1 mA when its output is low and 10 mA when its output is high. Shablon dlya oformleniya yubilejnogo adres. It comes in an 8-pin Dual-In-Line package and there is a 14-pin package version which contains two separate 555 circuits.
The pin connections are: This device can operate as a monostable or astable multivibrator, a Schmitt trigger or an inverting buffer (low current input, high current output). Here it is wired as a Schmitt trigger, and for variation, it is shown triggering a triac which will then stay on until the circuit is powered down (an SCR could be used just as well with this DC circuit): And here, a monostable: And here are two astables, the second of which has fixed, equal mark/space ratio and the first a high output voltage time determined by Ra + Rb and a low voltage output time determined by Rb (2:1 in this case): Note: The high leakage of large value electrolytic capacitors prevents them being used with high value resistors in timing circuits. Instead, use a smaller capacitor and follow the timing circuit with a “divide-by-N” chip to give accurately timed long periods. Not all 555 chips have a manufacturing quality sufficient for them to operate reliably above 20,000 Hz, so for the higher frequencies the chip needs to be selected after testing its actual performance. We can also wire the 555 to give a variable mark/space ratio while holding the frequency of the oscillation fixed: The output waveform changes drastically as the variable resistor is adjusted, but the frequency (or pitch of the note) of the output stays unaltered. A variable-frequency version of this circuit can be produced by changing the 33K resistor to a variable resistor as shown here: Here, the 33K resistor has been replaced by two variable resistors and one fixed resistor.
The main variable resistor is 47K in size (an almost arbitrary choice) and it feeds to a second variable resistor of 4.7K in size. The advantage of this second variable resistor is that it can be set to it’s mid point and the frequency tuning done with the 47K variable.
When the frequency is approximately correct, the 4.7K variable can be used to fine tune the frequency. This is convenient as the small variable will have ten times more knob movement compared to the main variable (being just 10% of its value). Obviously, it is not necessary to have the fine-tuning variable resistor, and it can be omitted without changing the operation of the circuit.
...'>Transformator Tesla Na Ne555(06.09.2018)