A pipe spacing wedge system including a pipe spacing wedge assembly, with the pipe spacing wedge assembly including a wedge-body. The wedge-body may be defined by a front-side, a back-side, a right-edge, a left-edge, a top-edge, and a bottom-edge. The front-side of the wedge-body includes a plurality of stepped surfaces and the top-edge includes a sharp point. The pipe spacing wedge assembly is structured and arranged to assist a user in setting a variety of specific gap-distance between sections of pipe and pipe spacing wedge assembly is intended to be driven between the two sections of pipe by the user to set the gap-distance.

A device for measuring a gap between two objects located remotely from a user includes a base, a slider and a wedge. The slider is slidably received in the base and the wedge is attached to the slider and also slidably received in the base. A push-pull cable has a proximal end connected to the slider. The wedge is inclined at a predetermined angle and slides along an angled surface of the base such that a force applied to a distal end of the cable causes an upper surface of the wedge to move vertically forcing the wedge and the base into respective contact with the two objects forming the gap. By measuring the distance that the push-pull cable slides, the vertical distance traveled by the wedge and thus a measurement of the gap may be determined.

An alignment gauge includes a generally u-shaped main body and an alignment member extending therefrom. The alignment gauge is configured to be positioned on the frame of a cabinet during installation of one or more attached components, such as attachment of a pair of doors to a refrigerator cabinet. Specifically, the alignment gauge may be positioned so that the alignment member establishes a proper spacing for the attached components.

A feeler gauge includes multiple feeler blades and an optical sensor. Each of the multiple feeler blades rotates about an axis between a measuring position and a non-measuring position. Each of the multiple feeler blades includes a measurement portion configured to be inserted into a gap to be measured and a proximal end having an indication of thickness of the respective feeler blade thereon. The optical sensor optically determines one or more of the multiple feeler blades that are deployed in the measuring position from the respective indications of thickness of each of the one or more feeler blades.

The invention relates to a device for identifying glove-port positions intended for being mounted on a panel supported by a glovebox structure (11) which defines a closed chamber enabling an operator to perform handling operations while being isolated from said chamber. The device comprises a base (19), means for attaching this base (19) to the glovebox structure (11), at least one template (22, 23) which is supported by this base (19) while being movable with respect to this base, in order to be able to occupy different positions with respect to this base (19), each template comprising an opening which is capable of receiving a glove port, and means for locking each template (22, 23) in position with respect to the base (19).

The invention relates to a device for identifying glove-port positions intended for being mounted on a panel supported by a glovebox structure (11) which defines a closed chamber enabling an operator to perform handling operations while being isolated from said chamber. The device comprises a base (19), means for attaching this base (19) to the glovebox structure (11), at least one template (22, 23) which is supported by this base (19) while being movable with respect to this base, in order to be able to occupy different positions with respect to this base (19), each template comprising an opening which is capable of receiving a glove port, and means for locking each template (22, 23) in position with respect to the base (19).

A high spot material gauging device applies high spot detection material in multiple depths to provide a basis for correctly determining a depth of material to be removed to produce a planar surface. The device includes a block having a planar first face. Each of a plurality of channels extends into the first face of the block. Each channel has a planar bottom surface parallel to the face of the block. The bottom surface of each channel is a unique respective depth measured transversely from the face of the block such that each channel is configured for applying a unique thickness of high spot material onto a planar control surface.

A high spot material gauging device applies high spot detection material in multiple depths to provide a basis for correctly determining a depth of material to be removed to produce a planar surface. The device includes a block having a planar first face. Each of a plurality of channels extends into the first face of the block. Each channel has a planar bottom surface parallel to the face of the block. The bottom surface of each channel is a unique respective depth measured transversely from the face of the block such that each channel is configured for applying a unique thickness of high spot material onto a planar control surface.

A calibration gauge having plane symmetry is set in a position other than a rotation center of a rotary table. The calibration gauge is measured while the rotary table is driven to rotate. Offset of a measurement axis is determined based on a phase pattern of the rotary table when a stylus head detects the calibration gauge.

A calibration gauge having plane symmetry is set in a position other than a rotation center of a rotary table. The calibration gauge is measured while the rotary table is driven to rotate. Offset of a measurement axis is determined based on a phase pattern of the rotary table when a stylus head detects the calibration gauge.