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--- pm:prj2023:apredescu:teslacoilsecrets [2023/05/30 00:05]
maria.sapcaliu [Jurnal]
+++ pm:prj2023:apredescu:teslacoilsecrets [2023/05/30 15:43] (current)
maria.sapcaliu [Hardware Design]
@@ Line 94: / Line 94: @@
 //__Analog Input Signal__//
-{{:pm:prj2023:apredescu:electrical_schematic_2_sapcaliu_maria-viorica.jpg?800x400|}}
+{{:pm:prj2023:apredescu:electrical_schematic_2_sapcaliu.jpg?800x400|}}
@@ Line 106: / Line 106: @@
   - The circuit is initially powered on, and the transistor (Q1) is in the "on" position. This means that current can pass through the Tesla coil's primary coil.
-  - A magnetic field forms around the primary coil when current travels through it. This magnetic field causes a voltage to be generated in the secondary coil, which is wrapped around the primary coil.
+  - A magnetic field forms around the primary coil when current travels through it. This magnetic field causes a voltage to be generated in the secondary coil, where primary coil is wrapped around the secondary coil.
   - However, an unusual event occurs when the current in the secondary coil exceeds a particular threshold, often the breakdown current of an LED linked in series. The transistor's base is linked to ground, thus pulling it "down" and causing the transistor to reach a cutoff state.
   - When the transistor reaches cutoff mode, current is no longer conducted through the primary coil. This causes the magnetic field generated by the primary coil to collapse.
   - A high-voltage flyback voltage is induced in the primary coil as the magnetic field decreases. This flyback voltage discharges into the surrounding air, causing an electric arc or plasma to form.
-  - The interruption of current flow in the primary coil has an effect on the secondary coil as well. A voltage spike in the secondary coil is caused by the sudden shift in magnetic field, which might result in a high-voltage output.
+  - The interruption of current flow in the primary coil has an effect on the secondary coil as well. A voltage spike in the secondary coil is caused by the sudden shift in magnetic field, which results in a high-voltage output.
   - The process is repeated indefinitely. When the flyback voltage dissipates and the current in the secondary coil falls below the breakdown level of the LED connected in series, the voltage falls below the breakdown level of the LED. This permits the transistor to return to saturation mode, turning it "on" and commencing the magnetic field accumulation.
 </note>
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 {{:pm:prj2023:apredescu:teslacoilsecrets.zip|}}
-===== Jurnal =====
+===== Journal =====
-<note tip>
   * 26.04.2023
  I began to consider which project might pique my interest. I did some preliminary research on potential future projects.
@@ Line 253: / Line 252: @@
   * 18.05.2023
 Unfortunately, after numerous experiments and simulations of various circuits in LTSPICE, something was not right and I was unable to carry out a definitive solution for my slayer exciter circuit. My proposed slayer exciter circuit used a npn bjt (TIP31C) to drive the Mosfet (IRFP460) gate.
+{{:pm:prj2023:apredescu:teslacoil_ltpsice.png?700x500|}}
+{{:pm:prj2023:apredescu:teslacoil-ltpsice_2.png?700x500|}}
   * 19.05.2023
@@ Line 261: / Line 264: @@
   * 23.05.2023
 I began putting the software design into practice.
+ {{:pm:prj2023:apredescu:tesla-code1.jpg?700x400|}}
+ {{:pm:prj2023:apredescu:tesla-code2.jpg?700x400|}}
   * 26.05.2023
@@ Line 268: / Line 275: @@
   * 27.05.2023
 Begin assembling and testing the project for both situations with all necessary equipment (e.g., oscilloscope). They are effective!
+{{:pm:prj2023:apredescu:sapcaliu_t_a.jpeg?700x500|}}
+{{:pm:prj2023:apredescu:tesla_optocoupler.jpeg?200|}}
+{{:pm:prj2023:apredescu:tesla_withoutcoupler.jpeg?200|}}
   * 28.04.2023
@@ Line 275: / Line 288: @@
 The project is completed.
-===== Bibliografie/Resurse =====
+===== Bibliography/Resources =====
 <note>