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Coil Gun

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Bruno Diaz
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Circuits 1 Bruno Diaz & George Rosenbaum April 29, 2013 Coil Gun For our project we chose to build and analyze a coil gun with the schematic shown in Figure 1-A: Figure 1-A This design was chosen because it incorporated the zener voltage regulation and transistor switches discussed in class, while also simple enough for our group to fully analyze. We also took advantage of Multisim to simulate the circuit’s operation. A coil gun is a device that pushes a high current through a coil for a couple of milliseconds to induce a magnetic field onto a ferromagnetic projectile. Electromagnetic theory states that an electric field creates a magnetic field. This circuit takes advantage of this property by using a strong current to create a powerful magnetic attraction between the field in the coil and a ferromagnetic materiel. This attraction will create a strong force for an instant that will accelerate the material out of the firing chamber as a projectile. Tests show that this device is not very energy efficient, but still works as a proof of concept. The coil's main components are the 36V power source which powers the entire unit, the 37.6 mF capacitor bank which holds the charge, and the coil which induces the magnetic field.
Circuits 1 Bruno Diaz & George Rosenbaum April 29, 2013 The user controls the operation of the device with a DPDT switch, a physical switch that controls the operation of the circuit as shown in Figure 1-B: Figure 1-B (DPDT Switch) The component divides the operation of the circuit into three stages. The first stage, called the charging stage, connects the voltage source to two branches to move current into the capacitor bank and the indicator. The next stage is the holding stage, which disconnects the capacitor bank from the rest of the circuit and holds the stored bank voltage until the user is ready to fire. The final stage is the firing stage, which connects 9 volts to the Silicon Controlled Rectifier (SCR) thyristor, which shorts across the coil to the capacitor bank and releases the capacitor bank’s built up charge as current through the coil. The 36 V power source can be achieved through four 9 V batteries, but testing shows the batteries will need to be replaced after a few shots. Alternatively, a combination of wall adapters that achieve a combined 36 volts can be used instead so battery replacement will not be an issue. Because the capacitors are rated at 35 V, and the voltage supplied by both wall adapters and batteries tend vary several volts above and below what they are rated, a certain amount of voltage needs to dropped between the capacitor bank and the voltage source for safe operation. A first intuitive response to do this would be to use a resistor to drop the voltage, but Figures 1-C and 1-D show that as voltage across the capacitors increases, the voltage difference between the bank and source will decrease over time, causing the current across the resistors to fall.
Circuits 1 Bruno Diaz & George Rosenbaum April 29, 2013 Recall that Ohm’s Law states that the voltage dropped across a resistor is dependent on the current through it. This means that if the current in the resistor is decreasing, the voltage being dropped over it will also decrease until it becomes so negligible that eventually the source voltage will equal the voltage in the capacitors. The circuit needs a constant voltage regulator that is unaffected by the changing current between the source and bank. The most reasonable solution is to use a zener diode which drops a constant 5 V in series with the four 9 volt sources giving us a safe capacitor voltage range of 31 to 35 volts at full charge. The process of moving current from the source to the capacitors is split into two branches, one through the 100 Ohm resistor and another through the LED (with an estimated operation current of 5 mA) and a 2.7k Ohm resistor. The added resistors prevent excessive heat from a short and control the current so the LED will not be damaged. The 100 Ohm
Circuits 1 Bruno Diaz & George Rosenbaum April 29, 2013 branch just charges the capacitor, the one with the 2.7K and LED powers our indicator. The indicator moves a small amount of current through the LED, indicating that the capacitors are still charging. As the voltage between the capacitor bank and the voltage source decreases, the current will be so small that it can no longer turn on the LED. The light turning off indicates that the capacitors are fully charged, thus completing the charging stage. The stored electrical energy previously collected from the charging stage will eventually be transferred into the projectile as kinetic energy. The charge is stored within eight 4700 mF dielectric (must be used in accordance to polarity) capacitors for a total capacitance of 37.6 mF. At 31 volts these capacitors deliver 1.1656 coulombs of charge and 18 joules of stored energy. Not all this is turned into kinetic energy as a projectile. According to the Multisim simulations as shown in Figure 1-E , the total time of discharge would be 5 milliseconds with a peak amperage of about 510 A. All this will pass through the SCR and coil. We use a Silicon Controlled Rectifier to direct when current will flow through the coil. An SCR thyristor is a 4 layer semiconductor, and can be logically represented as two BJT transistors, with their bases and emitters hooked together. Note how in Figure 1-F, the top transistor is a pnp and the bottom transistor is a npn, though outside of design under specifically frequencies it can be the other way around without affecting its function.
Circuits 1 Bruno Diaz & George Rosenbaum April 29, 2013 (c) The SCR thyristor works as voltage controlled current gate, which allows current to flow between the anode and cathode when a voltage is applied to the gate and cathode. When the voltage is applied, the diodes turn on and current is allowed. Even if this trigger voltage is removed from the gate and cathode, the current is still allowed through until the current goes back to zero Ampere. We use an SCR instead of a physical switch or BJT because of it’s ability to handle the tremendous current, which could cause a regular transistor or switch to be severely damaged. The SCR of our design calls for it to be specifically rated to handle the very high voltages and currents within our design. As shown in Figure 1-G its datasheet lists its peak surge current for a 10 milisecond pulse, comparing this to our Multisim simulation seen in figure we can see that it is within the specifications the design. Figure 1-G The SCR has three relevant pins for operation, an anode, a gate, and a cathode. The SCR thyristor is rated to turn on when gate-cathode voltage is 9V, and must be switched on to allowed the stored charge in the capacitor bank to flow through the solenoid. The power
Circuits 1 Bruno Diaz & George Rosenbaum April 29, 2013 source is divided so that 9V of the 36V source can be applied to the SCR, throwing the circuit into the firing position. This discharges all 31V our capacitor bank over 5 milliseconds through our thyristor and into the coil. The SCR will stay shorted until current no longer flows through the anode and cathode, so even if the trigger voltage is applied for less than 5 milliseconds, the SCR will still say on until the capacitors are fully discharged. This is useful for creating an energy efficient firing stage. The coil uses the resulting current spike from our SCR to induce a strong magnetic field onto out projectile. The coil is made of four meters of 22 AWG copper wire with the estimated wrapped turns being 181 and the length of the coil being two cm. The coil is effectively an inductor with an inductance of 68 µH. This coil converts the electrical energy from the capacitor bank into kinetic energy. However, the process is not nearly 100% efficient. If we take the amount of energy in the capacitor bank (18 Joules) and use it to solve backwards with the kinetic energy equation (18 J = 1 2 mv2) with the estimated mass of the nail being one gram we would find that nail would travel at 189 meters per second, which goes far beyond what testing the actual circuit indicates. Possible ways we can improve upon the current coil design would be to use a smaller diameter barrel and a shorter coil with a thinner wire with more turns in order to increase the density of the field generated. In conclusion the coil we analyzed was a simple yet effective design that utilized the zener diode and semiconductor switches that we learned about in class. Though we did not necessarily cover the thyristor in class we were easily able to adapt concepts taught in class to analyze its function. With this project we can prove our skill with circuitry outside of the classroom which will carry with us through our careers.
Circuits 1 Bruno Diaz & George Rosenbaum April 29, 2013 Works Cited • "Capacitance." Hyper Physics. N.p.. Web. 26 Apr 2013. <http://hyperphysics.phy- astr.gsu.edu/hbase/electric/capac.html>. • "Faraday’s Law." Hyper Physics. N.p.. Web. 26 Apr 2013. <http://hyperphysics.phy- astr.gsu.edu/hbase/electric/farlaw.html>. • <http://datasheet-found.com/Datasheet.jsp?pn=1MD5T1B1M1RE> “1MD5T1B1M1RE Datasheet” • <http://www.mhprofessional.com/downloads/products/0071755675/675-monk- 01.pdf> “Coil Gun” • <http://www.vishay.com/docs/94388/40tpsapb.pdf > “High Voltage Phase Control Thyristor, 40A” • "Inductance." Hyper Physics. N.p.. Web. 26 Apr 2013. <http://hyperphysics.phy- astr.gsu.edu/hbase/electric/induct.html • Serda, Adel, and Kenneth Smith. Microelectronic Circuits. 6th. New York: Oxford University Press, Print. • "Thyristors." All About Circuits. N.p.. Web. 26 Apr 2013. http://www.allaboutcircuits.com/vol_3/chpt_2/11.html

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Coil Gun

  • 1. Circuits 1 Bruno Diaz & George Rosenbaum April 29, 2013 Coil Gun For our project we chose to build and analyze a coil gun with the schematic shown in Figure 1-A: Figure 1-A This design was chosen because it incorporated the zener voltage regulation and transistor switches discussed in class, while also simple enough for our group to fully analyze. We also took advantage of Multisim to simulate the circuit’s operation. A coil gun is a device that pushes a high current through a coil for a couple of milliseconds to induce a magnetic field onto a ferromagnetic projectile. Electromagnetic theory states that an electric field creates a magnetic field. This circuit takes advantage of this property by using a strong current to create a powerful magnetic attraction between the field in the coil and a ferromagnetic materiel. This attraction will create a strong force for an instant that will accelerate the material out of the firing chamber as a projectile. Tests show that this device is not very energy efficient, but still works as a proof of concept. The coil's main components are the 36V power source which powers the entire unit, the 37.6 mF capacitor bank which holds the charge, and the coil which induces the magnetic field.
  • 2. Circuits 1 Bruno Diaz & George Rosenbaum April 29, 2013 The user controls the operation of the device with a DPDT switch, a physical switch that controls the operation of the circuit as shown in Figure 1-B: Figure 1-B (DPDT Switch) The component divides the operation of the circuit into three stages. The first stage, called the charging stage, connects the voltage source to two branches to move current into the capacitor bank and the indicator. The next stage is the holding stage, which disconnects the capacitor bank from the rest of the circuit and holds the stored bank voltage until the user is ready to fire. The final stage is the firing stage, which connects 9 volts to the Silicon Controlled Rectifier (SCR) thyristor, which shorts across the coil to the capacitor bank and releases the capacitor bank’s built up charge as current through the coil. The 36 V power source can be achieved through four 9 V batteries, but testing shows the batteries will need to be replaced after a few shots. Alternatively, a combination of wall adapters that achieve a combined 36 volts can be used instead so battery replacement will not be an issue. Because the capacitors are rated at 35 V, and the voltage supplied by both wall adapters and batteries tend vary several volts above and below what they are rated, a certain amount of voltage needs to dropped between the capacitor bank and the voltage source for safe operation. A first intuitive response to do this would be to use a resistor to drop the voltage, but Figures 1-C and 1-D show that as voltage across the capacitors increases, the voltage difference between the bank and source will decrease over time, causing the current across the resistors to fall.
  • 3. Circuits 1 Bruno Diaz & George Rosenbaum April 29, 2013 Recall that Ohm’s Law states that the voltage dropped across a resistor is dependent on the current through it. This means that if the current in the resistor is decreasing, the voltage being dropped over it will also decrease until it becomes so negligible that eventually the source voltage will equal the voltage in the capacitors. The circuit needs a constant voltage regulator that is unaffected by the changing current between the source and bank. The most reasonable solution is to use a zener diode which drops a constant 5 V in series with the four 9 volt sources giving us a safe capacitor voltage range of 31 to 35 volts at full charge. The process of moving current from the source to the capacitors is split into two branches, one through the 100 Ohm resistor and another through the LED (with an estimated operation current of 5 mA) and a 2.7k Ohm resistor. The added resistors prevent excessive heat from a short and control the current so the LED will not be damaged. The 100 Ohm
  • 4. Circuits 1 Bruno Diaz & George Rosenbaum April 29, 2013 branch just charges the capacitor, the one with the 2.7K and LED powers our indicator. The indicator moves a small amount of current through the LED, indicating that the capacitors are still charging. As the voltage between the capacitor bank and the voltage source decreases, the current will be so small that it can no longer turn on the LED. The light turning off indicates that the capacitors are fully charged, thus completing the charging stage. The stored electrical energy previously collected from the charging stage will eventually be transferred into the projectile as kinetic energy. The charge is stored within eight 4700 mF dielectric (must be used in accordance to polarity) capacitors for a total capacitance of 37.6 mF. At 31 volts these capacitors deliver 1.1656 coulombs of charge and 18 joules of stored energy. Not all this is turned into kinetic energy as a projectile. According to the Multisim simulations as shown in Figure 1-E , the total time of discharge would be 5 milliseconds with a peak amperage of about 510 A. All this will pass through the SCR and coil. We use a Silicon Controlled Rectifier to direct when current will flow through the coil. An SCR thyristor is a 4 layer semiconductor, and can be logically represented as two BJT transistors, with their bases and emitters hooked together. Note how in Figure 1-F, the top transistor is a pnp and the bottom transistor is a npn, though outside of design under specifically frequencies it can be the other way around without affecting its function.
  • 5. Circuits 1 Bruno Diaz & George Rosenbaum April 29, 2013 (c) The SCR thyristor works as voltage controlled current gate, which allows current to flow between the anode and cathode when a voltage is applied to the gate and cathode. When the voltage is applied, the diodes turn on and current is allowed. Even if this trigger voltage is removed from the gate and cathode, the current is still allowed through until the current goes back to zero Ampere. We use an SCR instead of a physical switch or BJT because of it’s ability to handle the tremendous current, which could cause a regular transistor or switch to be severely damaged. The SCR of our design calls for it to be specifically rated to handle the very high voltages and currents within our design. As shown in Figure 1-G its datasheet lists its peak surge current for a 10 milisecond pulse, comparing this to our Multisim simulation seen in figure we can see that it is within the specifications the design. Figure 1-G The SCR has three relevant pins for operation, an anode, a gate, and a cathode. The SCR thyristor is rated to turn on when gate-cathode voltage is 9V, and must be switched on to allowed the stored charge in the capacitor bank to flow through the solenoid. The power
  • 6. Circuits 1 Bruno Diaz & George Rosenbaum April 29, 2013 source is divided so that 9V of the 36V source can be applied to the SCR, throwing the circuit into the firing position. This discharges all 31V our capacitor bank over 5 milliseconds through our thyristor and into the coil. The SCR will stay shorted until current no longer flows through the anode and cathode, so even if the trigger voltage is applied for less than 5 milliseconds, the SCR will still say on until the capacitors are fully discharged. This is useful for creating an energy efficient firing stage. The coil uses the resulting current spike from our SCR to induce a strong magnetic field onto out projectile. The coil is made of four meters of 22 AWG copper wire with the estimated wrapped turns being 181 and the length of the coil being two cm. The coil is effectively an inductor with an inductance of 68 µH. This coil converts the electrical energy from the capacitor bank into kinetic energy. However, the process is not nearly 100% efficient. If we take the amount of energy in the capacitor bank (18 Joules) and use it to solve backwards with the kinetic energy equation (18 J = 1 2 mv2) with the estimated mass of the nail being one gram we would find that nail would travel at 189 meters per second, which goes far beyond what testing the actual circuit indicates. Possible ways we can improve upon the current coil design would be to use a smaller diameter barrel and a shorter coil with a thinner wire with more turns in order to increase the density of the field generated. In conclusion the coil we analyzed was a simple yet effective design that utilized the zener diode and semiconductor switches that we learned about in class. Though we did not necessarily cover the thyristor in class we were easily able to adapt concepts taught in class to analyze its function. With this project we can prove our skill with circuitry outside of the classroom which will carry with us through our careers.
  • 7. Circuits 1 Bruno Diaz & George Rosenbaum April 29, 2013 Works Cited • "Capacitance." Hyper Physics. N.p.. Web. 26 Apr 2013. <http://hyperphysics.phy- astr.gsu.edu/hbase/electric/capac.html>. • "Faraday’s Law." Hyper Physics. N.p.. Web. 26 Apr 2013. <http://hyperphysics.phy- astr.gsu.edu/hbase/electric/farlaw.html>. • <http://datasheet-found.com/Datasheet.jsp?pn=1MD5T1B1M1RE> “1MD5T1B1M1RE Datasheet” • <http://www.mhprofessional.com/downloads/products/0071755675/675-monk- 01.pdf> “Coil Gun” • <http://www.vishay.com/docs/94388/40tpsapb.pdf > “High Voltage Phase Control Thyristor, 40A” • "Inductance." Hyper Physics. N.p.. Web. 26 Apr 2013. <http://hyperphysics.phy- astr.gsu.edu/hbase/electric/induct.html • Serda, Adel, and Kenneth Smith. Microelectronic Circuits. 6th. New York: Oxford University Press, Print. • "Thyristors." All About Circuits. N.p.. Web. 26 Apr 2013. http://www.allaboutcircuits.com/vol_3/chpt_2/11.html