Claims
- 1. A method for electromagnetic acceleration of a cylindrical object comprising:
- a) forming a minimum of one magnetic ring around said object using a minimum of one induction coil;
- b) providing a D.C. source and a plurality of linearly arranged doughnut shaped accelerator coils with an interior diameter of said coils being larger than the diameter of said cylindrical object to allow said object to pass through;
- c) connecting a capacitor across charging lines from said D.C. source to each of said accelerator coils; each of said capacitors to each of said accelerator coils having a lesser capacity than a preceding one of said capacitors;
- d) connecting a nano-second switch in one of said charging lines to each of said accelerator coils between said D.C. source and each of said capacitors;
- e) forming an accelerator barrel by arranging and reinforcing said accelerator coils and spacers between said accelerator coils with each of said spacers containing a means to detect a beginning end of said cylindrical object and progressively open said nano-second switches in preceding ones of said accelerator coils thereby forming in each of said coils a ringing circuit, with each ringing circuit having an increasing frequency as said cylindrical object moves through said accelerator barrel;
- f) propelling said cylindrical object into a beginning end of said accelerator barrel whereby interaction of magnetic forces produced by a ringing circuit formed by opening said nano-second switches in each of said coils interacts with magnetic forces on said cylindrical object to progressively accelerate said cylindrical object.
- 2. A method for electromagnetic acceleration of a cylindrical object comprising steps of:
- a) forming a minimum of one magnetic ring around said object with said minimum of one magnetic ring being formed by heating and cooling junctions of two dissimilar metals forming said magnetic ring and wherein the magnetic field strength of said magnetic ring is increased by opening a nano-second switch in a line between a charging source and an induction coil as said magnetic ring passes through a central opening in said induction coil;
- b) propelling said object into an accelerator barrel; said accelerator barrel comprising:
- 1) a multiplicity of linearly arranged doughnut shaped accelerator coils with openings to admit said cylindrical object and with each of said coils being separated by a doughnut shaped spacer ring;
- 2) a means for detecting entrance of said object into said spacer ring and activating a nano-second switch;
- 3) a D.C. current source connected to charging circuitry with a capacitor across charging lines to each of said accelerator coils and with one of said nano-second switches in one of said charging lines between said D.C. current source and said capacitor for each of said accelerator coils; starting with a first of said capacitors each of said capacitors thereafter having a smaller capacity than a preceding one of said capacitors in order to form a ringing circuit of increasing frequency in each of said coils by opening said nano-second switches as said object proceeds through said accelerator barrel.
- 3. A method for electromagnetic acceleration of a cylindrical object as in claim 2 wherein said object is propelled into said accelerator barrel using compressed air.
- 4. A method for electromagnetic acceleration of a cylindrical object comprising:
- a) forming a minimum of two magnetic rings around said object;
- b) propelling said object into an accelerator barrel; said accelerator barrel comprising:
- 1) a multiplicity of doughnut shaped accelerator coils linearly arranged;
- 2) a D.C. source, capacitor, and a nano-second switch in circuitry arranged to allow formation of a ringing circuit in each of said accelerator coils with opening of said nano-second switch;
- 3) a spacer ring between each pair of said accelerator coils with means to detect said object as it enters said spacer ring and open said nano-second switch;
- 4) a frequency control means to control frequency in said ringing circuit to allow maximum electromagnetic propellant interaction between said magnetic rings around said object and magnetic fields from said ringing circuit in each of said accelerator coils.
- 5. A method for electromagnetic acceleration of a cylindrical object as in claim 4 wherein said frequency control means is achieved by starting with a first of said capacitors and decreasing the capacity of each succeeding one of said capacitors to give an increasing frequency in said ringing circuit formed in each of said accelerator coils; said increasing frequency being adjusted by capacitance of said capacitors to provide maximum acceleration from each of said coils as the velocity of said object increases.
Parent Case Info
This is a continuation-in-part of my application, Ser. No. 07/435,616 entitled "A Fuel Assisted Electromagnetic Launcher," filing date Nov. 13, 1989, now U.S. Pat. No. 5,024,137.
US Referenced Citations (9)
Foreign Referenced Citations (2)
Number |
Date |
Country |
1365497 |
May 1964 |
FRX |
2211589 |
Jul 1989 |
GBX |
Continuation in Parts (1)
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Number |
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435616 |
Nov 1989 |
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