Abstract: A containment boom system for remediating an oil spill in a body of water includes a base support structure and a containment boom. An elongated rod has a proximal end and a spaced apart distal end. The proximal end is hingedly attached to the base support structure and extends laterally therefrom. A buoy is coupled to the distal end of the elongated rod. The buoy has sufficient buoyancy so as to remain floating on the liquid body while supporting the elongated rod. A reclamation loop is disposed in the water, a first portion of which is disposed in the oil spill and a second portion is disposed the water on the opposite side of the containment boom from the oil spill. The reclamation loop is continuously driven through a reclamation station, which removes oil therefrom.

Abstract: A containment boom system for remediating an oil spill in a body of water includes a base support structure and a containment boom. An elongated rod has a proximal end and a spaced apart distal end. The proximal end is hingedly attached to the base support structure and extends laterally therefrom. A buoy is coupled to the distal end of the elongated rod. The buoy has sufficient buoyancy so as to remain floating on the liquid body while supporting the elongated rod. A reclamation loop is disposed in the water, a first portion of which is disposed in the oil spill and a second portion is disposed the water on the opposite side of the containment boom from the oil spill. The reclamation loop is continuously driven through a reclamation station, which removes oil therefrom.

Abstract: A containment boom system for remediating an oil spill in a body of water includes a base support structure and two spaced apart containment booms defining a channel therebetween. An elongated rod has a proximal end and a spaced apart distal end. The proximal end is hingedly attached to the base support structure and extends laterally therefrom. A buoy is coupled to the distal end of the elongated rod. The buoy has sufficient buoyancy so as to remain floating on the liquid body while supporting the elongated rod. A reclamation loop is disposed in the water, a first portion of which is disposed in the oil spill and a second portion is disposed in the channel. The reclamation loop is continuously driven through a reclamation station, which removes oil therefrom.

Abstract: A containment boom system for remediating an oil spill in a body of water includes a base support structure and two spaced apart containment booms defining a channel therebetween. An elongated rod has a proximal end and a spaced apart distal end. The proximal end is hingedly attached to the base support structure and extends laterally therefrom. A buoy is coupled to the distal end of the elongated rod. The buoy has sufficient buoyancy so as to remain floating on the liquid body while supporting the elongated rod. A reclamation loop is disposed in the water, a first portion of which is disposed in the oil spill and a second portion is disposed in the channel. The reclamation loop is continuously driven through a reclamation station, which removes oil therefrom.

Abstract: A multiphase-liquid level sensing system for sensing a layer depth and thickness of a liquid of a first phase that floats on a liquid of a different second phase includes an elongated stem that defines an elongated cavity. A float, which exhibits a sensible property, is disposed coaxially around the elongated stem and has negative buoyancy relative to the liquid of the first phase and positive buoyancy relative to the liquid of the second phase. A level sensor senses the sensible property and indicates a second phase liquid distance from the float to the bottom of the stem. An overburden sensor extends downwardly from the stem senses total liquid thickness of the liquid above the overburden sensor. A computational circuit calculates a layer depth and thickness of the liquid of the first phase, based on input from the level sensor and the overburden sensor.

Abstract: A containment boom system for use in a liquid body includes a base support structure and a containment boom. An elongated rod has a proximal end and a spaced apart distal end. The proximal end is hingedly attached to the base support structure and extends laterally therefrom. A buoy is coupled to the containment boom and is coupled to the distal end of the elongated rod. The buoy has sufficient buoyancy so as to remain floating on the liquid body while supporting the elongated rod.

Abstract: A multiphase-liquid level sensing system for sensing a layer depth and thickness of a liquid of a first phase that floats on a liquid of a different second phase includes an elongated stem that defines an elongated cavity. A float, which exhibits a sensible property, is disposed coaxially around the elongated stem and has negative buoyancy relative to the liquid of the first phase and positive buoyancy relative to the liquid of the second phase. A level sensor senses the sensible property and indicates a second phase liquid distance from the float to the bottom of the stem. An overburden sensor extends downwardly from the stem senses total liquid thickness of the liquid above the overburden sensor. A computational circuit calculates a layer depth and thickness of the liquid of the first phase, based on input from the level sensor and the overburden sensor.

Abstract: A multiphase-liquid level sensing system for sensing a layer depth and thickness of a liquid of a first phase that floats on a liquid of a different second phase includes an elongated stem that defines an elongated cavity. A float, which exhibits a sensible property, is disposed coaxially around the elongated stem and has negative buoyancy relative to the liquid of the first phase and positive buoyancy relative to the liquid of the second phase. A level sensor senses the sensible property and indicates a second phase liquid distance from the float to the bottom of the stem. An overburden sensor extends downwardly from the stem senses total liquid thickness of the liquid above the overburden sensor. A computational circuit calculates a layer depth and thickness of the liquid of the first phase, based on input from the level sensor and the overburden sensor.

Abstract: A multiphase-liquid level sensing system for sensing a layer depth and thickness of a liquid of a first phase that floats on a liquid of a different second phase includes an elongated stem that defines an elongated cavity. A float, which exhibits a sensible property, is disposed coaxially around the elongated stem and has negative buoyancy relative to the liquid of the first phase and positive buoyancy relative to the liquid of the second phase. A level sensor senses the sensible property and indicates a second phase liquid distance from the float to the bottom of the stem. An overburden sensor extends downwardly from the stem senses total liquid thickness of the liquid above the overburden sensor. A computational circuit calculates a layer depth and thickness of the liquid of the first phase, based on input from the level sensor and the overburden sensor.