JPWO2020185951A5 - - Google Patents

Description

The foregoing and other advantages of the present disclosure will become apparent upon reading the following detailed description and upon reviewing the drawings.
[Invention 1001]
A system for plasma-based purification, comprising:
an engine including an exhaust port, said engine exhausting exhaust gases from said exhaust port, said exhaust gases comprising NO molecules and NO x molecules passing through said exhaust _port ;
A plasma reactor comprising a reactor tube and electrodes, wherein the reactor tube defines an internal chamber, the electrodes are at least partially disposed within the internal chamber inside the reactor tube, and wherein the internal a chamber fluidly coupled to the exhaust port of the diesel engine such that the exhaust gases flow from the exhaust port into the internal chamber of the plasma reactor; and,
a high voltage source electrically coupled to the electrodes of the plasma reactor comprising:
delivering an electrical pulse to the electrode, thereby forming a plasma from the exhaust gas and removing at least a portion of the NO molecules and the _NOx molecules from the exhaust gas;
the high voltage source, configured to
The system, comprising:
[Invention 1002]
1002. The system of invention 1001, wherein said electrodes are selected from the group comprising extruded electrodes, 3-wire electrodes, and 4-wire electrodes.
[Invention 1003]
1003. The system of present invention 1002, wherein said extruded electrode has a cross-section selected from the group comprising about 2.0 inches, about 2.25 inches, or about 2.5 inches.
[Invention 1004]
1003. The system of present invention 1002, wherein said extruded electrode has a cross-section of between about 1.0 inch and about 5.0 inch.
[Invention 1005]
1002. The system of invention 1001, wherein said electrode is a three wire electrode having a cross section of about 2 inches.
[Invention 1006]
1002. The system of Claim 1001, wherein said pulse source includes a bypass network electrically in parallel with the output of said pulse source.
[Invention 1007]
1007. The system of Claim 1006, wherein the bypass network is configured to absorb electrical energy reflected back to the pulse source to minimize electromagnetic interference from the pulse source.
[Invention 1008]
1007. The system of invention 1006, wherein said bypass network comprises a plurality of capacitors electrically connected in series.
[Invention 1009]
1002. The system of invention 1001, wherein said engine is a diesel engine.
[Invention 1010]
1009. The system of the invention 1009, wherein said diesel engine is from a merchant vessel.
[Invention 1011]
further comprising a high voltage connector coupled to said reactor tube;
the high voltage connector electrically couples the high voltage source to the electrode;
wherein the high voltage connector is configured to carry the electrical pulse from the high voltage source to the electrode;
The system of the invention 1001.
[Invention 1012]
said high voltage connector comprising a housing, an insulating member and a conductive member, said housing coupled to said reactor tube, said insulating member partially disposed within said housing; 1012. The system of Claim 1011, partially disposed within said reactor tube, said conductive member extending through said insulating member to said electrode disposed within said reactor tube.
[Invention 1013]
1013. The system of Claim 1012, wherein said high voltage connector comprises a cable electrically coupling said high voltage source to said conductive member.
[Invention 1014]
A plasma reactor for plasma-based purification, comprising:
a first reactor tube and a second reactor tube;
an inlet port coupled to a first end of the first reactor tube and a second end of the second reactor tube, the inlet port connecting an engine exhaust port to the first reactor tube; configured to be fluidly coupled to a reactor tube and the second reactor tube such that the exhaust gas can flow through the first reactor tube and the second reactor tube; said inlet port adapted to;
an outlet port coupled to the first end of the first reactor tube and the second end of the second reactor tube;
a first electrode disposed within the first reactor tube and a second electrode disposed within the second reactor tube;
A high voltage connector coupled to the first reactor tube and the second reactor tube, electrically connecting both the first electrode and the second electrode to a high voltage source. said high voltage connector, configured to:
with
The high voltage connector carries electrical pulses from the high voltage source to both the first electrode and the second electrode, thereby connecting the first reactor tube and the second reactor tube. configured to form a plasma from the exhaust gas flowing therethrough;
said plasma reactor.
[Invention 1015]
The first reactor tube and the second reactor tube extend in a first direction between the inlet port and the outlet port, and the high voltage connector connects the first reactor tube and the second reactor tube. 1014. The plasma reactor of present invention 1014 extending between the reactor tubes in a second direction perpendicular to said first direction.
[Invention 1016]
The high voltage connector is
a housing coupled to the first reactor tube and the second reactor tube;
a first insulating member extending from the housing of the high voltage connector into the first reactor tube;
a second insulating member extending from the housing of the high voltage connector into the second reactor tube;
1015. The plasma reactor of the present invention 1015, comprising:
[Invention 1017]
The high voltage connector is
a first conductive member extending through the interior of the first insulating member to the first electrode disposed within the first reactor tube;
a second conductive member extending through the interior of the second insulating member to the second electrode disposed within the second reactor tube;
The plasma reactor of the present invention 1016, comprising:
[Invention 1018]
The high voltage connector is
a first end disposed within the housing and electrically connected to the first conductive member and the second conductive member;
a second end configured to be electrically connected to the high voltage source;
1017. The plasma reactor of the present invention 1017, comprising a cable having
[Invention 1019]
the first conductive member electrically connecting the first electrode to the cable and the second conductive member electrically connecting the second electrode to the cable; The plasma reactor of the present invention 1018.
[Invention 1020]
1020. The plasma of Invention 1019, wherein said cable has an impedance of about 50 ohms, said first conductive member has an impedance of about 100 ohms, and said second conductive member has an impedance of about 100 ohms. reactor.
[Invention 1021]
a first spacer disposed within the first reactor tube and coupled to the first conductive member and the first electrode;
a second spacer disposed within the second reactor tube and coupled to the second conductive member and the second electrode;
further comprising
The first spacer is configured to maintain the position of the first electrode within the first reactor tube such that the first electrode is positioned against the inner surface of the first reactor tube. non-contacting, the second spacer is configured to maintain the position of the second electrode within the second reactor tube, whereby the second electrode is adapted to the kept out of contact with the inner surface of the second reactor tube,
The plasma reactor of the present invention 1017.
[Invention 1022]
1022. The plasma reactor of present invention 1021, wherein both said first spacer and said second spacer are formed from an insulating material.
[Invention 1023]
1014. The plasma reactor of Invention 1014, wherein said first electrode or said second electrode is a 3-wire electrode, a 4-wire electrode, or an extruded electrode.
[Invention 1024]
1024. The plasma reactor of Invention 1023, wherein said extruded electrode comprises a central portion and one or more arms extending from said central portion.
[Invention 1025]
1014. The plasma reactor of present invention 1014, wherein said engine is a diesel engine.
[Invention 1026]
1025. The plasma reactor of the invention 1025, wherein said diesel engine is from a merchant vessel.
[Invention 1027]
A system for plasma-based purification, comprising:
one or more pairs of reactor tubes, each reactor tube of each pair of reactor tubes having an electrode disposed therein;
an inlet port fluidly coupled to one or more pairs of said reactor tubes, said inlet port fluidly coupling an engine exhaust port to said one or more pairs of reactor tubes; the inlet port configured to allow the exhaust gas to flow through one or more pairs of the reactor tubes;
one or more high voltage connectors, each high voltage connector being coupled to each of said one or more pairs of reactor tubes, each high voltage connector being connected to one or more of said reactor tube pairs; the one or more high voltage connectors electrically connected to the electrodes of each of the respective reactor tubes of the pair of
with
Each high voltage connector carries an electrical pulse from a high voltage source to the electrodes of each of the respective one or more pairs of reactor tubes, thereby configured to form a plasma from the exhaust gas flowing through the pair;
said system.
[Invention 1028]
1027. The plasma reactor of the present invention 1027, wherein said engine is a diesel engine.
[Invention 1029]
1028. The plasma reactor of the present invention 1028, wherein said diesel engine is from a merchant vessel.

Claims (20)

A plasma reactor for plasma-based purification, comprising:
a first reactor tube and a second reactor tube;
an inlet port coupled to a first end of the first reactor tube and a first end of the second reactor tube, the inlet port connecting the first reactor to an exhaust port of an engine; said inlet port configured to fluidly couple a reactor tube and said second reactor tube;
an outlet port coupled to a second end of the first reactor tube and a second end of the second reactor tube;
a first electrode at least partially disposed within the first reactor tube and a second electrode at least partially disposed within the second reactor tube;
A high voltage connector coupled to the first reactor tube and the second reactor tube, electrically connecting both the first electrode and the second electrode to a high voltage source. and the high voltage connector configured to
The first electrode and the second electrode receive electrical pulses from the high voltage source , thereby generating a plasma from exhaust gases flowing through the first reactor tube and the second reactor tube. configured to form a
said plasma reactor. 2. The plasma reactor of claim 1, further comprising a bypass network configured to be electrically connected in parallel with the output of said high voltage source and said high voltage connector . 3. The plasma reactor of claim 2 , wherein said bypass network is configured to absorb electrical energy reflected back to said high voltage source to minimize electromagnetic interference from said high voltage source. . 3. The plasma reactor of claim 2 , wherein said bypass network comprises a plurality of capacitors electrically connected in series. The first reactor tube and the second reactor tube extend in a first direction between the inlet port and the outlet port, and the high voltage connector connects the first reactor tube and the second reactor tube. 2. The plasma reactor of claim 1 extending between the reactor tubes in a second direction perpendicular to said first direction. The high voltage connector is
a housing coupled to the first reactor tube and the second reactor tube;
a first insulating member extending from the housing of the high voltage connector into the first reactor tube;
and a second insulating member extending from said housing of said high voltage connector into said second reactor tube. The high voltage connector is
a first conductive member extending through the interior of the first insulating member to the first electrode disposed within the first reactor tube;
and a second conductive member extending through the interior of said second insulating member to said second electrode disposed within said second reactor tube. . The high voltage connector is
a first end disposed within the housing and electrically connected to the first conductive member and the second conductive member;
8. The plasma reactor of claim 7 , comprising a cable having a second end configured to be electrically connected to said high voltage source. the first conductive member electrically connecting the first electrode to the cable and the second conductive member electrically connecting the second electrode to the cable; A plasma reactor according to claim 8 . 10. The cable of claim 9 , wherein the cable has an impedance of 50 ohms, the first conductive member has an impedance of 100 ohms, and the second conductive member has an impedance of 100 ohms. plasma reactor. a first spacer disposed within the first reactor tube and coupled to the first conductive member and the first electrode;
a second spacer disposed within the second reactor tube and coupled to the second conductive member and the second electrode;
The first spacer is configured to maintain the position of the first electrode within the first reactor tube such that the first electrode is positioned against the inner surface of the first reactor tube. non-contacting, the second spacer is configured to maintain the position of the second electrode within the second reactor tube, whereby the second electrode is adapted to the kept out of contact with the inner surface of the second reactor tube,
A plasma reactor according to claim 7 . 12. The plasma reactor of claim 11 , wherein both said first spacers and said second spacers are formed from an insulating material. 2. The plasma reactor of claim 1 , wherein said first electrode or said second electrode is a 3-wire electrode, a 4-wire electrode, or an extruded electrode. 14. The plasma reactor of claim 13, wherein said extruded electrode includes a central portion and one or more arms extending from said central portion and has a cross-section of 1 inch to 5 inches . 14. The plasma reactor of claim 13, wherein said 3-wire electrode has a cross-section of 2 inches. Combined with an engine with an exhaust port,
The exhaust port of the engine is coupled to the inlet port, and the engine passes through the exhaust port such that exhaust gas can flow through the first reactor tube and the second reactor tube. NO molecule and NO _X configured to emit an exhaust gas containing molecules,
The high voltage source delivers electrical pulses to the first electrode and the second electrode, thereby forming a plasma from exhaust gases flowing through the first reactor tube and the second reactor tube. and from the exhaust gas, (i) at least a portion of NO molecules, (ii) NO _X at least a portion of the molecule, or (iii) at least a portion of the NO molecule and NO _X configured to remove at least a portion of the molecule;
A plasma reactor according to claim 1. 17. The plasma reactor of claim 16 , wherein said engine is a diesel engine. 18. The plasma reactor of claim 17 , wherein said diesel engine is from a merchant ship. A system for plasma-based purification, comprising:
one or more pairs of reactor tubes, each reactor tube of each pair of reactor tubes having an electrode disposed therein;
an inlet port fluidly coupled to one or more pairs of said reactor tubes, said inlet port fluidly coupling an engine exhaust port to said one or more pairs of reactor tubes; the inlet port configured to allow the exhaust gas to flow through one or more pairs of the reactor tubes;
one or more high voltage connectors, each high voltage connector being coupled to each of said one or more pairs of reactor tubes, each high voltage connector being connected to one or more of said reactor tube pairs; the one or more high voltage connectors electrically connected to the electrodes of the respective reactor tubes of the pair of
Each high voltage connector carries an electrical pulse from a high voltage source to the electrodes of each of the respective one or more pairs of reactor tubes, thereby configured to form a plasma from the exhaust gas flowing through the pair;
said system. A system for plasma-based purification, comprising:
a diesel engine including an exhaust port, said diesel engine emitting exhaust gas from said exhaust port, said exhaust gas comprising NO and _NOx molecules passing through said exhaust port;
A plasma reactor comprising a reactor tube and electrodes, wherein the reactor tube defines an interior chamber, the electrodes are disposed at least partially within the interior chamber of the reactor tube, the interior chamber comprising: , the plasma reactor fluidly coupled to the exhaust port of the diesel engine such that the exhaust gases flow from the exhaust port into the internal chamber of the plasma reactor;
a high voltage source electrically coupled to the electrodes of the plasma reactor comprising:
delivering an electrical pulse to the electrode, thereby forming a plasma from the exhaust gas, and from the exhaust gas : (i) at least a portion of the NO molecules; (ii) at least a portion of the NO _x molecules; or (iii) the high voltage source configured to remove at least a portion of the NO molecules and at least a portion of the _NOX molecules.