The present invention relates to a reciprocating wire saw device. The device is primarily comprised of a body with at least one handle, at least one trigger, at least one battery, and a second end with at least one blade and at least one plunger. The device preferably has two oscillating arms that oscillate independently via the motor. Therefore, each end of a wire blade can be attached to each arm such that oscillation of the arms allow the blade to cut a pipe or other similar object.

Some embodiments include an apparatus for cutting a pile. In some embodiments, the apparatus includes a shaft module including a cylindrical shaft including a first cavity configured to receive the pile. In some embodiments, the apparatus also includes a cutting module coupled to the shaft module, the cutting module including a second cavity configured to receive the pile, clamps configured to clamp onto the pile, and a saw configured to cut the pile. In some embodiments, the apparatus also includes a drilling module coupled to the cutting module, the drilling module including blades to burrow into an earth surface.

An electric power saw/cutter includes a rotatable saw structure, a rear handle with a switch/speed control, a front handle, and a drive unit for rotating the saw structure. The drive unit includes a saw structure drive arrangement to which the saw structure is attachable, a transmission for driving the saw drive arrangement, an electric motor for driving an input shaft of the transmission, and a support structure for holding/carrying the saw structure drive arrangement. The transmission and the electric motor may be characterized in that the front handle and the rear handle are directly connected to each other to form a handle unit, which unit is resiliently connected to the drive unit, so that vibrations from the saw blade and drive unit will be reduced in the handle unit.

A method is provided for removing an abandoned marine platform from a seabed. The platform extends below the seabed mud line. In order to remove the platform, a frame is provided having a perimeter that surrounds an open center. The frame is lowered over the platform wherein the platform occupies the open center portion. A movable cutter cable is fitted to the frame. At least a part of the cutter cable is positioned below the mud line. The cutter is moved relative to the frame to cut the platform below the mud line. Such movement can be a back and forth movement wherein the cutter cable moves in a first direction, stops and then moves in a second direction that is generally opposite the first direction. A lifting device can employ two vessels and two frames, each frame bridging from one vessel to the other. Winches on the vessel can be used to provide movement to the cutter cable. These same winches can take up cable slack as cutting moves from one platform member (e.g. leg, jacket leg, piling, etc) to another.

Various aspects to facilitate mobilizing bulk equipment are disclosed. In a first aspect, a saw apparatus includes a vacuum source, a worktable, and a portability mechanism integrated within the saw apparatus in which dimensions associated with the portability mechanism depend on a location of a center of mass of the saw apparatus. The worktable includes a center slot axially aligned to a circular saw blade, and the vacuum source is configured to provide a negative pressure beneath the worktable at the center slot. In a second aspect, a center of mass inquiry is received, which includes data associated with equipment having a non-uniform distribution of mass. The center of mass inquiry is then processed, and a portability mechanism adjustment is sent in response to a processing of the center of mass inquiry.

A method for slicing a workpiece with a wire saw which includes a wire row formed by winding a fixed abrasive grain wire having abrasive grains secured to a surface thereof around multiple grooved rollers, the method including feeding a workpiece to the wire row for slicing while allowing the fixed abrasive grain wire to reciprocatively travel in an axial direction thereof, thereby slicing the workpiece at multiple positions aligned in an axial direction of the workpiece simultaneously. The method includes: supplying a coolant for workpiece slicing onto the wire row when the workpiece is sliced with the fixed abrasive grain wire; and supplying a coolant for workpiece drawing, which differs from and has a higher viscosity than the coolant for workpiece slicing, onto the wire row when the workpiece is drawn out from the wire row after the slicing of the workpiece.

A cable saw for cutting a workpiece includes a circulating saw cable, a guide device, and a cable storage device and cable tensioning device. The saw cable is driven by a drive and includes a sawing section. The guide device is arranged to move the sawing section along a cutting direction for cutting engagement with the workpiece. The guide device is arranged to allow several movement directions including the cutting direction and at least one lengthening or shortening of the sawing section. The cable storage device and cable tensioning device is arranged for storing, releasing and/or tensioning the saw cable when changing a position and/or length of the sawing section. The guide device includes a lever gear with a pivot lever rotatably hinged to a base holder. The lever gear is arranged to convert a rotational movement of the pivot lever into a movement of deflection rollerswhich form the sawing section therebetweento lengthen and/or shorten the sawing section.

A cutting apparatus and the method of operating same is provided. The apparatus includes a feed tower assembly configured to be attached to an object and a frame assembly movably attached thereto. The frame assembly has arm assemblies thereon which accept a cutting member. At least one arm assembly can be pivoted relative to the other arm assembly and relative to the feed tower assembly. One arm assembly can further be moved relative to the other arm assembly and relative to the feed tower assembly in a vertical direction.

Provided are an apparatus and a method for machining cylindrical grooves by multi-wire cutting of profiles, the apparatus includes a driving guide roller and a driven guide roller in a guide roller assembly with axes thereof disposed parallelly and symmetrically, a tension wheel further disposed between the driving guide roller and the driven guide roller, a cutting wire clamped in grooves of the driving guide roller and the driven guide roller and perpendicular to a central axis of a workpiece, and a plurality of segments of the cutting wire forming a cutting wire group mesh surface; and a plurality of grooves are machined simultaneously on the cylindrical surface of the workpiece by the wire group mesh surface, and the cutting wire forms a machining pressure under an action of tension wheel, which can feed smoothly and ensure the accuracy and machining efficiency of the grooves.

A cutting apparatus (1) configured for The cutting apparatus (1) has a cutting means drive arrangement (100) having at least one cutting means (12) and at least one motive means (43) for providing power to the cutting means (12). The cutting apparatus (1) is configured such that all, some or a part of the cutting means drive arrangement (100) is interchangeable, on site. This enables use of a single cutting apparatus to perform a variety of different cuts and/or to cut a variety of different objects.