Abstract: Provided is a method for making a composite structure with exposed conductive fibers. The exposed conductive fibers can be used for static dissipation. In the present method, a liquid, gum, gel, or impermeable film mask is applied to the conductive fiber material. The mask functions to prevent infiltration of curable liquid resin into the conductive fiber material. The masked conductive fiber material is incorporated into the composite structure, along with structural fiber material. The liquid resin is cured. The mask material and cured resin are removed from the masked areas, thereby exposing the conductive fiber material. The exposed conductive fiber material can collect and drain electrostatic charges. The present method can be used to make storage tanks and other objects that require electrostatic charge dissipation.

Abstract: Provided is a method for making a composite structure with exposed conductive fibers. The exposed conductive fibers can be used for static dissipation. In the present method, a liquid, gum, gel, or impermeable film mask is applied to the conductive fiber material. The mask functions to prevent infiltration of curable liquid resin into the conductive fiber material. The masked conductive fiber material is incorporated into the composite structure, along with structural fiber material. The liquid resin is cured. The mask material and cured resin are removed from the masked areas, thereby exposing the conductive fiber material. The exposed conductive fiber material can collect and drain electrostatic charges. The present method can be used to make storage tanks and other objects that require electrostatic charge dissipation.

Abstract: Provided is a method for making a composite structure with exposed conductive fibers. The exposed conductive fibers can be used for static dissipation. In the present method, a liquid, gum, gel, or impermeable film mask is applied to the conductive fiber material. The mask functions to prevent infiltration of curable liquid resin into the conductive fiber material. The masked conductive fiber material is incorporated into the composite structure, along with structural fiber material. The liquid resin is cured. The mask material and cured resin are removed from the masked areas, thereby exposing the conductive fiber material. The exposed conductive fiber material can collect and drain electrostatic charges. The present method can be used to make storage tanks and other objects that require electrostatic charge dissipation.

Abstract: Provided is a storage tank or structure with conductive fiber material (e.g. carbon fiber) for dissipating electrostatic charge. The tank comprises a tank wall made of composite material, such as polyester-fiberglass composite. On an inner tank surface, open areas are provided in which the conductive fiber is exposed. The conductive fiber material has broken fiber tips and stray fibers for collecting electrostatic charge. Outside the open areas, the conductive fiber material is covered with a layer of cured resin. The conductive fiber is exposed only in the open areas. An impermeable film may be present under the conductive fiber in the open areas. The present invention also includes a method for making the tank, in which a liquid, gel, or impermeable film mask is applied to the conductive fiber material. The mask functions to prevent infiltration of liquid resin into the conductive fiber material.

Abstract: Provided is an electrostatic charge dissipator for removing electrostatic charge inside a storage tank or other enclosed volume. The dissipator comprises yarns of electrically conductive polymeric fibers, such as carbon fiber. The yarns have broken fiber tips or stray fibers projecting away from the yarns, thereby functioning to concentrate electric fields and facilitate charge collection. The yarns are attached to a bracket for mechanical attachment to the tank, and are electrically connected to a feedthrough for providing an electrical path to ground potential. The present dissipator can also comprise a support, such as a rope, chain, or the like, and a weight for limiting the movement of the dissipator. The present dissipator is highly corrosion resistant and does not threaten pumps or valves with damaging metal debris.

Abstract: Provided is an electrostatic charge dissipator for removing electrostatic charge inside a storage tank or other enclosed volume. The dissipator comprises yarns of electrically conductive polymeric fibers, such as carbon fiber. The yarns have broken fiber tips or stray fibers projecting away from the yarns, thereby functioning to concentrate electric fields and facilitate charge collection. The yarns are attached to a bracket for mechanical attachment to the tank, and are electrically connected to a feedthrough for providing an electrical path to ground potential. The present dissipator can also comprise a support, such as a rope, chain, or the like, and a weight for limiting the movement of the dissipator. The present dissipator is highly corrosion resistant and does not threaten pumps or valves with damaging metal debris.

Abstract: Provided is a storage tank or structure with conductive fiber material (e.g. carbon fiber) for dissipating electrostatic charge. The tank comprises a tank wall made of composite material, such as polyester-fiberglass composite. On an inner tank surface, open areas are provided in which the conductive fiber is exposed. The conductive fiber material has broken fiber tips and stray fibers for collecting electrostatic charge. Outside the open areas, the conductive fiber material is covered with a layer of cured resin. The conductive fiber is exposed only in the open areas. An impermeable film may be present under the conductive fiber in the open areas. The present invention also includes a method for making the tank, in which a liquid, gel, or impermeable film mask is applied to the conductive fiber material. The mask functions to prevent infiltration of liquid resin into the conductive fiber material.

Abstract: Provided is an electrostatic charge dissipator for removing electrostatic charge inside a storage tank or other enclosed volume. The dissipator comprises yarns of electrically conductive polymeric fibers, such as carbon fiber. The yarns have broken fiber tips or stray fibers projecting away from the yarns, thereby functioning to concentrate electric fields and facilitate charge collection. The yarns are attached to a bracket for mechanical attachment to the tank, and are electrically connected to a feedthrough for providing an electrical path to ground potential. The present dissipator can also comprise a support, such as a rope, chain, or the like, and a weight for limiting the movement of the dissipator. The present dissipator is highly corrosion resistant and does not threaten pumps or valves with damaging metal debris.

Abstract: Provided is a storage tank or structure with conductive fiber material (e.g. carbon fiber) for dissipating electrostatic charge. The tank comprises a tank wall made of composite material, such as polyester-fiberglass composite. On an inner tank surface, open areas are provided in which the conductive fiber is exposed. The conductive fiber material has broken fiber tips and stray fibers for collecting electrostatic charge. Outside the open areas, the conductive fiber material is covered with a layer of cured resin. The conductive fiber is exposed only in the open areas. An impermeable film may be present under the conductive fiber in the open areas. The present invention also includes a method for making the tank, in which a liquid, gel, or impermeable film mask is applied to the conductive fiber material. The mask functions to prevent infiltration of liquid resin into the conductive fiber material.