US2016169509A1PendingUtilityA1

Pyrolytic gas processor and tire conversion system therefrom

Assignee: INFINITUS RENEWABLE ENERGY LLCPriority: Dec 12, 2014Filed: Jun 9, 2015Published: Jun 16, 2016
Est. expiryDec 12, 2034(~8.4 yrs left)· nominal 20-yr term from priority
Inventors:David Fowler
Y02P20/143F23N 3/042F23G 7/003C10B 47/44F23N 2235/28F23G 5/50F23G 5/444F23G 2900/50205F23G 7/12F23G 2201/80F23G 2209/281C10B 53/07F23G 5/12C10G 1/10F23G 5/027F23G 5/0276F23N 2035/28
51
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Claims

Abstract

A gas processor includes a burner chamber including a first end and a second end, a gas/fuel burner having an inlet receiving air and an inlet for receiving a first combustible gas including a nozzle providing a flame extending out from the nozzle. A syn-gas chamber including injection holes and a syn-gas feed line and a syn-gas nozzle plate is coupled between the second end of the burner chamber and the gas/fuel burner including over the nozzle, wherein syn-gas is directed by the injection holes into a path of the flame for combustion of the syn-gas. An air pipe having a plurality of air discharge ports extending from the first end to within the burner chamber having an air blower coupled thereto is configured to pump air into the burner chamber.

Claims

exact text as granted — not AI-modified
1 . A gas processor, comprising:
 a burner chamber including a first end and a second end;   a gas/fuel burner having an inlet receiving air and an inlet for receiving a first combustible gas including a nozzle providing a flame extending out from said nozzle;   a syn-gas chamber having injection holes including a syn-gas feed line and a syn-gas nozzle plate coupled between said second end of said burner chamber and said gas/fuel burner including over said nozzle, wherein syn-gas is directed by said injection holes into a path of said flame for combustion of said syn-gas, and   an air pipe having a plurality of air pipe discharge ports extending from said first end to within said burner chamber having an air blower coupled thereto configured to pump air into said burner chamber.   
     
     
         2 . The gas processor of  claim 1 , wherein said air pipe comprises a plurality of protruding heat fins. 
     
     
         3 . The gas processor of  claim 1 , comprising a first temperature sensor for sensing a temperature over a reactor chamber being heated by radiant heat from said gas processor and a fan controller which receives said temperature from said first temperature sensor configured to regulate a flow of air provided by said air blower. 
     
     
         4 . The gas processor of  claim 1 , wherein said burner chamber includes a second temperature sensor therein, and wherein said gas/fuel burner comprises a modulation damper operable to change a flow of air through said inlet receiving air based on a temperature reading from said second temperature sensor. 
     
     
         5 . The gas processor of  claim 1 , further comprising an air blast plate having baffles positioned under said plurality of air pipe discharge ports. 
     
     
         6 . The gas processor of  claim 1 , further comprising a system for pyrolizing tires, said system comprising:
 a reactor including a pyrolysis (reactor) chamber including at least one heater having a pyrolysis zone, an inlet and outlets on respective sides of said pyrolysis zone, said outlets including a flue pipe and a second outlet;   a feed system for transferring feedstock comprising tire pieces received from a feed source into said inlet;   a conveyer for moving material associated with said tire pieces through said reactor chamber;   wherein pyrolysis performed in said reactor chamber pyrolizes said feedstock to generate solid material and hydrocarbon gases including ash particles,   a condenser coupled to said flue pipe for liquefying said hydrocarbon gases before collection in a collection tank, and   an outlet conveyor for transferring said solid material from said second outlet to a recovery hopper,   wherein said burner chamber of said gas processor is positioned proximate to said reactor chamber to provide radiant heat for heating said reactor chamber.   
     
     
         7 . The gas processor of  claim 6 , further comprising a heat box surrounding both said reactor chamber and said burner chamber, and an air blast plate under said burner chamber, wherein air interning into said heat box through said air pipe discharged by said air pipe discharge ports is distributed essentially evenly under said burner chamber by said air blast plate. 
     
     
         8 . The gas processor of  claim 1 , wherein said syn-gas chamber is a coaxial syn-gas chamber including inner and outer metals cylinders wherein said syn-gas received from said syn-gas feed line travels laterally in a gap between said metals cylinders before being injected through said injection holes. 
     
     
         9 . The gas processor of  claim 1 , wherein said gas processor is a modular design including a plurality of gas processor modules (gas modules) coupled end-to-end to one another by coupling structures configured to allow movement of said plurality of gas modules. 
     
     
         10 . A method of gas processing, comprising:
 receiving air and a first combustible gas at a first end of a gas/fuel burner including a nozzle providing a flame extending out from said nozzle;   using a syn-gas chamber having injection holes including a syn-gas feed line and a syn-gas nozzle plate coupled between a second end of a burner chamber and said gas/fuel burner including over said nozzle, directing syn-gas received from said syn-gas feed line through said injection holes into a path of said flame for combusting said syn-gas, and   while combusting said syn-gas, pumping air into said burner chamber to cool said burner chamber.   
     
     
         11 . The method of  claim 10 , wherein said pumping said air into said burner chamber comprises using an air pipe having a plurality of air pipe discharge ports extending from said first end to within said burner chamber having an air blower coupled thereto configured to pump said air into said burner chamber. 
     
     
         12 . The method of  claim 11 , wherein said air pipe comprises a plurality of protruding heat fins. 
     
     
         13 . The method of  claim 11 , further comprising sensing a temperature over a reactor chamber being heated by radiant heat from said combustion of said syn-gas and a fan controller which receives said temperature from a first temperature sensor regulating a flow of said air provided by said air blower. 
     
     
         14 . The method of  claim 10 , wherein said burner chamber includes a second temperature sensor therein, and wherein said gas/fuel burner comprises a modulation damper, changing a flow of said air received by said gas/fuel burner based on a temperature reading from said second temperature sensor. 
     
     
         15 . The method of  claim 10 , wherein said burner chamber is positioned proximate to a reactor chamber of a system for pyrolizing tires to provide radiant heat for heating said reactor chamber. 
     
     
         16 . The method of  claim 11 , wherein said burner chamber is positioned proximate to a reactor chamber of a system for pyrolizing tires to provide radiant heat for heating said reactor chamber, further comprising a heat box surrounding both said reactor chamber and said burner chamber, and an air blast plate under said burner chamber, wherein air interning into said heat box through said air pipe discharged by said air pipe discharge ports is distributed essentially evenly under the burner chamber by said air blast plate.

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