To provide an electromagnetic wave discharge emission device, a discharger in small size for causing a discharge only by an electromagnetic wave, that can significantly be reduced in length in a longitudinal direction, and configured to emit the electromagnetic wave into a target space based on an output of the supplied electromagnetic wave. The electromagnetic wave discharge emission device comprises an electromagnetic wave oscillator MW configured to oscillate an electromagnetic wave, a controller 2 configured to control the electromagnetic wave oscillator MW, a first substrate 10 provided with a plurality of discharge emission patterns 11 each having a power receiving end 11a on the main surface side, and a second substrate 20 provided with a feed pattern 22 having a power receiving port 21 configured to receive a power of the electromagnetic wave from the electromagnetic wave oscillator MW and a plurality of power feed ends 22a each connected through a via to one of the power receiving ends 11a, a distance on the feed pattern 22 from the power receiving port 21 to each power receiving end 11a of the corresponding discharge emission pattern 11 being equal to one another. Each of the discharge emission patterns 11 is formed in a spiral shape that has at a center thereof the corresponding power receiving end (s) 11a connected to the feed pattern 22 and has a length which corresponds to wavelength of the electromagnetic wavelength supplied to the feed pattern 22.

To provide an electromagnetic wave discharge emission device, a discharger in small size for causing a discharge only by an electromagnetic wave, that can significantly be reduced in length in a longitudinal direction, and configured to emit the electromagnetic wave into a target space based on an output of the supplied electromagnetic wave. The electromagnetic wave discharge emission device comprises an electromagnetic wave oscillator MW configured to oscillate an electromagnetic wave, a controller 2 configured to control the electromagnetic wave oscillator MW, a first substrate 10 provided with a plurality of discharge emission patterns 11 each having a power receiving end 11a on the main surface side, and a second substrate 20 provided with a feed pattern 22 having a power receiving port 21 configured to receive a power of the electromagnetic wave from the electromagnetic wave oscillator MW and a plurality of power feed ends 22a each connected through a via to one of the power receiving ends 11a, a distance on the feed pattern 22 from the power receiving port 21 to each power receiving end 11a of the corresponding discharge emission pattern 11 being equal to one another. Each of the discharge emission patterns 11 is formed in a spiral shape that has at a center thereof the corresponding power receiving end (s) 11a connected to the feed pattern 22 and has a length which corresponds to wavelength of the electromagnetic wavelength supplied to the feed pattern 22.

An ignition device ignites a mixture of air and fuel gas by plasma to generate an initial flame. The ignition device includes a spark plug having an inner conductor, a cylindrical outer conductor that holds the inner conductor inside, and a dielectric provided between the inner conductor and the outer conductor, and the spark plug configured to emit an electromagnetic wave to a plasma formation space between the inner conductor and the outer conductor to generate a plasma. The ignition device includes an electromagnetic wave power supply that generates the electromagnetic wave by inputting the electromagnetic wave power Ps to the spark plug and a power supply control unit that controls the electromagnetic wave power supply. The electromagnetic wave power supply is configured to generate high frequency power at a number of different frequencies. The power supply control unit outputs at least one of the plurality of high frequency powers generated by the electromagnetic wave power supply as the electromagnetic wave power.

An ignition device ignites a mixture of air and fuel gas by plasma to generate an initial flame. The ignition device includes a spark plug having an inner conductor, a cylindrical outer conductor that holds the inner conductor inside, and a dielectric provided between the inner conductor and the outer conductor, and the spark plug configured to emit an electromagnetic wave to a plasma formation space between the inner conductor and the outer conductor to generate a plasma. The ignition device includes an electromagnetic wave power supply that generates the electromagnetic wave by inputting the electromagnetic wave power Ps to the spark plug and a power supply control unit that controls the electromagnetic wave power supply. The electromagnetic wave power supply is configured to generate high frequency power at a number of different frequencies. The power supply control unit outputs at least one of the plurality of high frequency powers generated by the electromagnetic wave power supply as the electromagnetic wave power.

A spark plug includes: a center electrode; an insulator having a through hole around a part of the center electrode; and a metal shell holding the insulator from an outer peripheral side thereof. The metal shell includes a shelf portion that projects radially inward. The insulator includes an engagement portion engaged with the shelf portion from the front side, and a front end portion at the front side with respect to a front end of the metal shell. The front end portion has an outer diameter larger than an inner diameter of the metal shell at the front side with respect to the shelf portion. The front end portion of the insulator has a diameter-enlarged portion at which a diameter of the through hole increases and which is spaced apart from an outer peripheral surface of the center electrode.

A spark plug includes: a center electrode; an insulator having a through hole around a part of the center electrode; and a metal shell holding the insulator from an outer peripheral side thereof. The metal shell includes a shelf portion that projects radially inward. The insulator includes an engagement portion engaged with the shelf portion from the front side, and a front end portion at the front side with respect to a front end of the metal shell. The front end portion has an outer diameter larger than an inner diameter of the metal shell at the front side with respect to the shelf portion. The front end portion of the insulator has a diameter-enlarged portion at which a diameter of the through hole increases and which is spaced apart from an outer peripheral surface of the center electrode.

A method, system and apparatus for plasma blasting comprises a borehole in soil, a blast probe comprising a high voltage electrode and a ground electrode separated by a dielectric separator, wherein the high voltage electrode and the dielectric separator constitute an adjustable probe tip, and an adjustment unit coupled to the adjustable probe tip, wherein the adjustment unit is configured to selectively extend or retract the adjustable probe tip relative to the ground electrode and a blasting media, wherein at least a portion of the high voltage electrode and the ground electrode are submerged in the blast media. The blasting media comprises wet concrete. The adjustable tip permits fine-tuning of the blast. The blast is used to force the wet concrete into a customized shape within the borehole.

A method, system and apparatus for plasma blasting comprises a borehole in soil, a blast probe comprising a high voltage electrode and a ground electrode separated by a dielectric separator, wherein the high voltage electrode and the dielectric separator constitute an adjustable probe tip, and an adjustment unit coupled to the adjustable probe tip, wherein the adjustment unit is configured to selectively extend or retract the adjustable probe tip relative to the ground electrode and a blasting media, wherein at least a portion of the high voltage electrode and the ground electrode are submerged in the blast media. The blasting media comprises wet concrete. The adjustable tip permits fine-tuning of the blast. The blast is used to force the wet concrete into a customized shape within the borehole.

A plasma assisted spark ignition system includes an ignitor and a power supply. The first ignitor includes: a casing having a first end, a second end that forms a first electrode, and a longitudinally extending passage, a second electrode which protrudes longitudinally outward from an opening at the second end of the casing and laterally spaced inwardly to form a spark gap, and an electrical insulator (dielectric) surrounding a portion of the second electrode, and which has a terminus that is at least closely spaced to an interior surface of the end of the casing. The power supply supplies a plurality of voltage pulses to the ignitor per ignition event to generate a flash over on the dielectric. Subsequent pulses in an ignition event may be at lower amplitude than an initial pulse in the ignition event. Pulses may, for example, have a duration on the order of a nanosecond.

This application is to protect the design and application of a remote assisted plasma ignition device for the use but not restricted to the oil & gas industry. Which consists of four (4) main components: Power Supply Assembly (Solar PV+Battery), Remote Control system, Electronic control circuit, Plasma generator, High voltage cables and/or electrodes

The first 3 components (apart from PV solar cells) are housed in a sealed box according to the oil & gas standards. The plasma generator would be housed separately where high voltage cables stem from it to produce multiple plasma sparks. This novel device is placed immediately above the impacted site requiring no projectile system or specialized personnel to operate.

During the event of an uncontrolled gas leak, authorized person in charge such as drilling supervisor (DSV) would initiate the spark remotely following evacuation of the impacted site. Multiple plasma sparks would be initiated after following a specific remote ignition sequence. The scattered plasma spark around the impacted site would result in the ignition of the flammable fluids.