The clamping device according to the invention for clamping at least two processing devices for a sample preparation is made up essentially of at least three clamping blocks arranged in the axial direction, at least two of which are designed as movable clamping blocks, and a displacement mechanism for displacing the movable clamping blocks between an open position for inserting the processing devices, and a clamping position in which the at least two processing devices are clamped one on top of the other in the axial direction between two clamping blocks in each case. The displacement mechanism is designed for displacing the at least two movable clamping blocks in opposite directions.

A pipe clamp includes a length of tubing having a pair of polygonal clamps moveably secured about the tube through an aperture located at a proximal end of each clamp. At a distal end of the tubing projects a nut which is perpendicularly secured thereto. A rod is engaged within the nut and in mechanical communication with the distal exterior end of the closest clamp. A handle is secured to the distal end of the rod.

The present invention relates to a device for mounting wall objects. The device has a vertical member and a horizontal member attached to one another along a fold line. The vertical member has a wall-facing side that engages and is secured to a wall or surface by receiving connection members through one or more mounting holes. The horizontal member, in some arrangements, has a pair of flanges that form a gap along an outer end opposite the fold line. A pair of spaced-apart support braces that form a slot extend generally down the middle between the horizontal and vertical member. The slot allows for the reception of a brace or clamp that can be held in place by inserting a locking pin through aligned sets of locking holes and through either a brace hole in the brace or a fixing hole in a transverse hole of the clamp.

A clamping and spreading device for separating layers of a substrate includes a C-clamp that is configured to fixedly couple to a substrate. A second rod is coupled to and extends from the C-clamp. The second rod is selectively extensible from the C-clamp. A first wedge is coupled to and extends bidirectionally from the second rod distal from the C-clamp. A second wedge is coupled to and extends from the C-clamp. An actuator is coupled to the C-clamp and is operationally coupled to the second rod. The first wedge and the second wedge are configured to insert into a first gap defined by two layers of the substrate. The actuator is positioned to compel the second rod to extend from the C-clamp. The first wedge is compelled distally from the second wedge to separate the two layers of the substrate.

A machining assembly which allows for precise and repeatable machining operationsprimarily tube notchingto be carried out by an operator in various situations, and is specifically designed for hollow-form parting without use of a mandrel in prototyping and small-scale production. This system allows operators to cut copes in both typical and atypical materials, and offers the ability to produce double end-coped workpieces quickly. Additionally, the preferred embodiment can be equipped for use as a light-duty milling machine which incorporates portability with the benefits of traditional milling centers.

A solid surface clamp that has a top jaw and bottom jaw, along with alignment structures is disclosed. The clamp includes a top jaw, a bottom jaw, a bolt attached to the bottom jaw and slideably received through the top jaw, and a nut. The bolt has an alignment cutout, a threaded portion extending from the top jaw and defines a bolt longitudinal axis. The nut is threaded onto the threaded portion of the bolt and transitions the clamp from an open position to a clamping position. The top jaw further includes an alignment hole that contacts the alignment cutout and maintains the top jaw and bottom jaw substantially fixed relative to each other about the bolt longitudinal axis. The alignment cutout moves relative to the alignment shaft in the direction of the bolt longitudinal axis when the clamp transitions from an open position to a clamping position.

A clamp comprises first and second clamp halves, each comprising an elongate object receiving portion and a portion of a clamp retention mechanism. The first and second elongate object receiving portions are sized and shaped to cooperatively hold an elongate object at a desired position when the first and second clamp halves are fastened together. The first and second portions of the clamp retention mechanism are sized and shaped to (a) engage each other when the first and second clamp halves are moved towards each other in a first direction, (b) fasten the first and second clamp halves together without requiring use of a tool to engage the retention mechanism, and (c) disengage from each other when the first and second clamp halves are moved away from each other in a direction orthogonal to the first direction to unfasten the first and second clamp halves without use of a tool.

A remote jig control system may comprise a jig configured to place a car body to a particular position, a wireless magnetic sensor installed in the jig, a control panel wirelessly connected with the wireless magnetic sensor via first wireless communication to receive state information about the jig from the wireless magnetic sensor, a gateway connected with the control panel via the first wireless communication to receive the state information, a user terminal connected with the gateway via second wireless communication to receive the state information; and monitoring server configured to receive the state information from the gateway and store the state information, wherein the control panel is configured to be controlled through the user terminal to generate a jig control signal corresponding to the state information.

A precision positioning device extending along an axis to be maintained in a first opening of a mechanical part, includes an axial element provided with a passage, a nut, a support and a moveable element, the axial element being integral with the support, and including a first screw thread for mounting the nut on the axial element, the nut providing an axial stop blocking the axial movement of the axial element relative to the nut, the axial element having an end portion including a deformable cylindrical male profile, adapted to cooperate with the inner circumference of the first opening, the deformation or radial expansion of the end of the axial element being driven by the action of the insertion of the moveable element in movement in the passage of the axial element in the direction of the end of the axial element.

A solid surface clamp that has a top jaw and bottom jaw, along with alignment structures is disclosed. The clamp includes a top jaw, a bottom jaw, a bolt attached to the bottom jaw and slideably received through the top jaw, and a nut. The bolt has an alignment cutout, a threaded portion extending from the top jaw and defines a bolt longitudinal axis. The nut is threaded onto the threaded portion of the bolt and transitions the clamp from an open position to a clamping position. The top jaw further includes an alignment shaft that contacts the alignment cutout and maintains the top jaw and bottom jaw substantially fixed relative to each other about the bolt longitudinal axis. The alignment cutout moves relative to the alignment shaft in the direction of the bolt longitudinal axis when the clamp transitions from an open position to a clamping position.