This wire saw machine having a dust collecting apparatus comprises a main roller for moving a wire by rotation; a first pulley system including a first upper dust collecting roller, a first lower dust collecting roller, and a first support roller; a second pulley system including a second upper dust collecting roller, a second lower dust collecting roller, and a second support roller; and a dust collecting unit which is provided under the first pulley system and the second pulley system to collect foreign substances that escape from the first pulley system and the second pulley system.

This wire saw machine having a dust collecting apparatus comprises a main roller for moving a wire by rotation; a first pulley system including a first upper dust collecting roller, a first lower dust collecting roller, and a first support roller; a second pulley system including a second upper dust collecting roller, a second lower dust collecting roller, and a second support roller; and a dust collecting unit which is provided under the first pulley system and the second pulley system to collect foreign substances that escape from the first pulley system and the second pulley system.

A power tool includes a housing, a motor located within the housing, a drive assembly located within the housing and connected to an output of the motor, at least one cutting wheel coupled to the drive assembly, and at least one switch configured to control activation of the motor for directional rotation of the drive assembly in either a forward rotational direction or a reverse rotational direction. The drive assembly is configured to operate in the reverse rotational direction during dry cutting. The drive assembly is configured to operate in the forward rotational direction during wet cutting.

A combination cart providing independent electrical power generation and dust extraction capabilities finds utility in concrete processing and other operations that create unwanted dust using hand tools for cutting, grinding, polishing, coring, drilling, sanding, and the like. A propane tank powers a propane engine, and the propane engine drives an electrical generator providing power to an electrical outlet panel mounted on the frame. The cart further includes a dust extraction and filtration system driven by an electric motor, also mounted on the frame. The inventive cart facilitates multiple modes of operation, including: (a) dust extraction and filtration only, with the dust extraction system being powered by an available external source of electrical power; (b) electrical power generation only, with the dust extraction and filtration system being turned off; and (c) simultaneous dust extraction/filtration and electrical power generation, with the dust extraction and filtration system being powered by the electrical generator.

A combination cart providing independent electrical power generation and dust extraction capabilities finds utility in concrete processing and other operations that create unwanted dust using hand tools for cutting, grinding, polishing, coring, drilling, sanding, and the like. A propane tank powers a propane engine, and the propane engine drives an electrical generator providing power to an electrical outlet panel mounted on the frame. The cart further includes a dust extraction and filtration system driven by an electric motor, also mounted on the frame. The inventive cart facilitates multiple modes of operation, including: (a) dust extraction and filtration only, with the dust extraction system being powered by an available external source of electrical power; (b) electrical power generation only, with the dust extraction and filtration system being turned off; and (c) simultaneous dust extraction/filtration and electrical power generation, with the dust extraction and filtration system being powered by the electrical generator.

Methods and apparatus for forming an aperture in a composite component are provided. For example, a method for forming an aperture in a ceramic matrix composite (CMC) component comprises, based on a final dimension of the aperture, selecting a tool having a tool size and a cutting surface; selecting an angle at which to cut the component with the tool; cutting a back surface of the component with the tool, the cutting surface positioned at the angle; repositioning the tool relative to the component; and cutting the aperture through to its final dimension. The tool may be a core drill with a diameter within a range of 60% to 90% of the aperture final dimension. The angle may be within a range of 10° to 60° with respect to the back surface. The aperture may be cut through to its final dimension from a front surface of the component.

A device for covering a cut gap which can be produced by a machine tool. The device can be connected to a dust suctioning device so that the dust produced while working with the machine tool can be removed from the working area of the machine tool using the dust suctioning tool. A second aspect of the invention relates to a system consisting of at least two proposed devices. Another aspect of the invention relates to a method for suctioning dust from a working region of a machine tool. The device includes sealing caps which can be connected to a dust suctioning device via suction connecting pieces. Furthermore, the sealing caps are used to seal the working area in which the working process of the machine tool is carried out.

A novel cutting method and apparatus includes a cutting blade adapted to consistently and easily form a desirable kerf in a concrete substrate while capturing substantially all resulting concrete dust.

A novel cutting method and apparatus includes a cutting blade adapted to consistently and easily form a desirable kerf in a concrete substrate while capturing substantially all resulting concrete dust.

A power saw machine for cutting a work piece includes a supporting frame, a cutting blade, and an environment control arrangement which includes a cutting table base, a sliding vacuum hood, and an outlet. The cutting table base is slidably supported by the supporting frame for supporting the work piece. The sliding vacuum hood has a narrow collecting chamber with a continuous inlet for directly contacting with the work piece to omit a spatial gap between the narrow collecting chamber and the work piece, wherein during the cutting process, a cutting portion of the cutting blade is entered into the narrow collecting chamber through the continuous inlet for cutting the work piece. The outlet is provided at the sliding vacuum hood for sucking residual debris of the work piece within the narrow collecting chamber during the cutting process.