A burner for venting gas of a gas or oil well, the same comprises a venting gas tubing laid from the well up to a burning pit; a tubing for the supply of pilot gas laid parallel to the tubing of venting gas; a tubing of power lines from a control panel up to at least one electrode; a nozzle constituted by a tube that comprises a plurality of perforations that go through the wall of said tube, a plurality of air inlet tubes affixed to the wall of said tube; and a plurality of support spoilers affixed to the wall of said tube; where, the distal ends of the venting gas tubing, the tubing of supply of pilot gas and at the least one electrode, are located inside the nozzle; and where, the nozzle is installed inside the burning pit.

A burner for venting gas of a gas or oil well, the same comprises a venting gas tubing laid from the well up to a burning pit; a tubing for the supply of pilot gas laid parallel to the tubing of venting gas; a tubing of power lines from a control panel up to at least one electrode; a nozzle constituted by a tube that comprises a plurality of perforations that go through the wall of said tube, a plurality of air inlet tubes affixed to the wall of said tube; and a plurality of support spoilers affixed to the wall of said tube; where, the distal ends of the venting gas tubing, the tubing of supply of pilot gas and at the least one electrode, are located inside the nozzle; and where, the nozzle is installed inside the burning pit.

Disclosed are methods and systems for producing a gas from a combustible material. In particular, disclosed are methods and systems for batch-type production of a gas from a combustible material. The methods and systems include igniting at least a portion of the combustible material loaded in the sealed containment structure to form a thermally affected layer, wherein the step of feeding the oxidant into the sealed containment structure is carried out so that conversion of the combustible material to a gas at one point in the sequence is initiated prior to complete conversion of the combustible material at a previous point in the sequence.

Disclosed are methods and systems for producing a gas from a combustible material. In particular, disclosed are methods and systems for batch-type production of a gas from a combustible material. The methods and systems include igniting at least a portion of the combustible material loaded in the sealed containment structure to form a thermally affected layer, wherein the step of feeding the oxidant into the sealed containment structure is carried out so that conversion of the combustible material to a gas at one point in the sequence is initiated prior to complete conversion of the combustible material at a previous point in the sequence.

Embodiments are directed toward a burn bucket. The burn bucket preferably includes a body, a door moveably coupled to the body, and a lifting machine interface coupled to the body. The body preferably defines an inner burn space. The lifting machine interface is preferably configured to receive a portion of a machine that tilts the burn bucket to transition the burn bucket between a closed configuration in which the door is closed and a dumping configuration in which the door is open to facilitate dumping burnt material out of the inner burn space.

Embodiments are directed toward a burn bucket. The burn bucket preferably includes a body, a door moveably coupled to the body, and a lifting machine interface coupled to the body. The body preferably defines an inner burn space. The lifting machine interface is preferably configured to receive a portion of a machine that tilts the burn bucket to transition the burn bucket between a closed configuration in which the door is closed and a dumping configuration in which the door is open to facilitate dumping burnt material out of the inner burn space.

Methods are provided for the removal of sulfur and other ARD/AMD-generating materials through the smoldering combustion of an organic material. The methods comprise admixing an ARD/AMD-generating porous matrix material with an organic material to produce a mixture, exposing the mixture to an oxidant, and initiating a self-sustaining smoldering combustion of the mixture. Additional embodiments aggregate the organic material or ARD/AMD-generating porous matrix material or mixture thereof in an impoundment such as a reaction vessel, depression or matrix pile. Further embodiments utilize at least one heater to initiate combustion and at least one air supply port to supply oxidant to initiate and maintain combustion.

Methods are provided for the removal of sulfur and other ARD/AMD-generating materials through the smoldering combustion of an organic material. The methods comprise admixing an ARD/AMD-generating porous matrix material with an organic material to produce a mixture, exposing the mixture to an oxidant, and initiating a self-sustaining smoldering combustion of the mixture. Additional embodiments aggregate the organic material or ARD/AMD-generating porous matrix material or mixture thereof in an impoundment such as a reaction vessel, depression or matrix pile. Further embodiments utilize at least one heater to initiate combustion and at least one air supply port to supply oxidant to initiate and maintain combustion.

Embodiments are directed toward a burn bucket. The burn bucket preferably includes a body, a door moveably coupled to the body, and a lifting machine interface coupled to the body. The body preferably defines an inner burn space. The lifting machine interface is preferably configured to receive a portion of a machine that tilts the burn bucket to transition the burn bucket between a closed configuration in which the door is closed and a dumping configuration in which the door is open to facilitate dumping burnt material out of the inner burn space.

Embodiments are directed toward a burn bucket. The burn bucket preferably includes a body, a door moveably coupled to the body, and a lifting machine interface coupled to the body. The body preferably defines an inner burn space. The lifting machine interface is preferably configured to receive a portion of a machine that tilts the burn bucket to transition the burn bucket between a closed configuration in which the door is closed and a dumping configuration in which the door is open to facilitate dumping burnt material out of the inner burn space.