An inner static electricity eliminating control valve for organic solvent delivery pipelines is disclosed. The inner static electricity eliminating control valve is to be installed on and connected to an organic solvent delivery pipeline, to eliminate the inner static electricity generated by the organic solvent inside the organic solvent delivery pipeline. The inner static electricity eliminating control valve includes a valve casing, a main valve chamber, a pneumatic valve, a subsidiary valve chamber, a check valve, a static electricity export mechanism and a solvent export portion, wherein, the pneumatic valve can periodically apply pressure toward the organic solvent inside the main valve chamber, so that the organic solvent inside the main valve chamber can be delivered periodically through the check valve to the subsidiary valve chamber, and during this process, the static electricity export mechanism will export and eliminate the static electricity existing in the organic solvent.

A method of supporting an upright member from a support surface includes inserting an elongated carrier of an upright member support system into a hole in the support surface. A base of the support system is positioned at least partially around the carrier so the base contacts at least one upper surface of the support surface. A lock of the support system is releasably engaged with the carrier above the base and tightened down sufficient to maintain the base in contact with the support surface. The upright member is inserted into a bore of the carrier.

System for supporting an upright member from a support surface includes an elongated carrier releasably engageable with the support surface, a base adapted to extend around at least part of the lower end of the carrier and abut the support surface and at least one anchor associated with the carrier and configured to grip the upright member when the upright member is inserted into a bore of the carrier.

An ESD grounding apparatus for grounding mats or other equipment to provide a ground connection to mat as well as receptacles for operator wrist straps, and other equipment. The apparatus attaches to a mat by means of securing member such as a clamp or compressing screw rather than using destructive rivets or snaps that create holes in the mat. By using a securing member to secure the device to the mat, the device can be easily removed and reused in another location without damaging or weakening the mat, whereas the previous devices require installing an additional snap into the mat in each location that requires a ground.

An electrically groundable support surface includes a lower portion configured to be deployed on or near the surface of the earth. An electrically-conductive cover portion constructed at least partially of electrically-conductive material is configured to extend at least partially across the top surface of the lower portion and is electrically groundable to the earth. At least one electrically-conductive interface is configured to facilitate electrical connection of the support surface to another electrically-conductive component.

An insulated, electrically groundable, support surface includes at least one heat shield configured to be disposed between a ground cover and an electrically-conductive cover(s) of the support surface to insulate the ground cover from heat generated by electric current flowing through the electrically-conductive cover(s).

An electrically-conductive cover for electrically grounding a mat includes a frame constructed at least partially of electrically-conductive material and configured to sit at the perimeter of the top surface of the mat. An electrically-conductive inner panel fits within the frame. The inner panel is coupled to the frame so they can be attached to or removed from the mat as a single unit. At least one fastener releasably couples the frame and/or inner panel to the mat. At least one electrically-conductive interface is configured to facilitate electrical connection of the cover to another electrically-conductive component.

A layer of the mixture that contains polymer and conductive particles is applied over a first surface, when the mixture has a first viscosity that allows the conductive particles to rearrange within the layer. An electric field is applied over the layer, so that a number of the conductive particles are aligned with the field and thereafter the viscosity of the layer is changed to a second, higher viscosity, in order to mechanically stabilise the layer. This leads to a stable layer with enhanced and anisotropic conductivity.

An inner static electricity eliminating control valve for organic solvent delivery pipelines is disclosed. The inner static electricity eliminating control valve is to be installed on and connected to an organic solvent delivery pipeline, to eliminate the inner static electricity generated by the organic solvent inside the organic solvent delivery pipeline. The inner static electricity eliminating control valve includes a valve casing, a main valve chamber, a pneumatic valve, a subsidiary valve chamber, a check valve, a static electricity export mechanism and a solvent export portion, wherein, the pneumatic valve can periodically apply pressure toward the organic solvent inside the main valve chamber, so that the organic solvent inside the main valve chamber can be delivered periodically through the check valve to the subsidiary valve chamber, and during this process, the static electricity export mechanism will export and eliminate the static electricity existing in the organic solvent.

A magnetically adhered, static dissipative floor covering comprises a magnetically receptive floor surface, and a floor covering comprising a plurality of static dissipative, magnetic floor tiles. The magnetic floor tiles are held in place by magnetic interaction between the magnetic floor tiles and the magnetically receptive floor surface. Each of the magnetic floor tiles is a composite construction comprising a static dissipative vinyl wear layer, an integral, conductive ground plane, and an integral, planar magnetic layer. The conductive ground plane comprises a non-woven synthetic fabric with a nickel-copper coating and a conductive adhesive backing. The conductive ground plane is bonded to the static dissipative wearing layer by the conductive adhesive backing.