A fluid-driven ring saw includes a ring saw blade that is supported and driven by a fluid. The fluid-driven ring saw can include one or more pairs of fluid nozzles. Each pair of fluid nozzles can include a first fluid nozzle separated from a second fluid nozzle by a gap. The ring blade can be positioned within the gap. The ring blade can include a plurality of holes. The one or more pairs of fluid nozzles can deliver fluid jets that impinge upon the plurality of holes of the ring blade to drive rotation of the ring blade. The ring blade can be driven without direct contact of a mechanical linkage, such as a belt or chain. The ring blade can be relatively thinner than ring blades driven by mechanical linkages.

A fluid-driven ring saw includes a ring saw blade that is supported and driven by a fluid. The fluid-driven ring saw can include one or more pairs of fluid nozzles. Each pair of fluid nozzles can include a first fluid nozzle separated from a second fluid nozzle by a gap. The ring blade can be positioned within the gap. The ring blade can include a plurality of holes. The one or more pairs of fluid nozzles can deliver fluid jets that impinge upon the plurality of holes of the ring blade to drive rotation of the ring blade. The ring blade can be driven without direct contact of a mechanical linkage, such as a belt or chain. The ring blade can be relatively thinner than ring blades driven by mechanical linkages.

A fluid-driven ring saw includes a ring saw blade that is supported and driven by a fluid. The fluid-driven ring saw can include one or more pairs of fluid nozzles. Each pair of fluid nozzles can include a first fluid nozzle separated from a second fluid nozzle by a gap. The ring blade can be positioned within the gap. The ring blade can include a plurality of holes. The one or more pairs of fluid nozzles can deliver fluid jets that impinge upon the plurality of holes of the ring blade to drive rotation of the ring blade. The ring blade can be driven without direct contact of a mechanical linkage, such as a belt or chain. The ring blade can be relatively thinner than ring blades driven by mechanical linkages.

A segmenting mechanism includes outer and inner frame members that define a sliding space and an aperture extending therethrough. A first set of sliding blades operates linearly and proximate the aperture. A second set of sliding blades is positioned in an alternating configuration with the first set of sliding blades and also operates linearly within the sliding space proximate the aperture. Each sliding blade of the first and second sets of sliding blades operates cooperatively and simultaneously along each dedicated linear path from a start position, through a medial position to an end position. The start and end positions are each defined by the sliding blades being outside of the aperture to define respective first and second open states of the aperture. The medial position is defined by the sliding blades being at least partially within the aperture to define a closed state of the aperture.

The disclosure discloses a long-life annular wall cutting machine, relating to the technical field of wall cutting machines. The technical solution is as follows: The long-life annular wall cutting machine includes an annular saw blade fixing and protecting cover assembly. A power wheel is arranged in the annular saw blade fixing and protecting cover assembly, an annular saw blade is arranged in a middle of the power wheel, and the power wheel and the annular saw blade abut against each other. In the disclosure, by rotating a tensioning handwheel, a contact strength between the annular saw blade and the power wheel can be adjusted, thereby realizing optimized adjustment of the power wheel.

The disclosure discloses a long-life annular wall cutting machine, relating to the technical field of wall cutting machines. The technical solution is as follows: The long-life annular wall cutting machine includes an annular saw blade fixing and protecting cover assembly. A power wheel is arranged in the annular saw blade fixing and protecting cover assembly, an annular saw blade is arranged in a middle of the power wheel, and the power wheel and the annular saw blade abut against each other. In the disclosure, by rotating a tensioning handwheel, a contact strength between the annular saw blade and the power wheel can be adjusted, thereby realizing optimized adjustment of the power wheel.

An arc-shaped oscillating saw blade with sparse and dense teeth and an oscillating saw are provided. The arc-shaped oscillating saw blade with sparse and dense teeth includes a cutting end composed of a plurality of sawteeth distributed in an arc shape, and a tooth spacing between adjacent sawteeth gradually increases from a middle position to positions at two sides of the cutting end, thus forming a sawtooth arrangement structure with dense sawteeth at a middle and sparse sawteeth at two sides. With a tooth structure with arrangement of proper tooth density gradient, a contact area between the saw blade and a material in the cutting process can be reduced, so that cutting resistance can be reduced. Arc-shaped tooth distribution facilitates improving of the cutting accuracy and surface smoothness, reduces cutting errors and surface defects, reduces impact and vibration in the cutting process, and further improves the cutting accuracy.

An arc-shaped oscillating saw blade with sparse and dense teeth and an oscillating saw are provided. The arc-shaped oscillating saw blade with sparse and dense teeth includes a cutting end composed of a plurality of sawteeth distributed in an arc shape, and a tooth spacing between adjacent sawteeth gradually increases from a middle position to positions at two sides of the cutting end, thus forming a sawtooth arrangement structure with dense sawteeth at a middle and sparse sawteeth at two sides. With a tooth structure with arrangement of proper tooth density gradient, a contact area between the saw blade and a material in the cutting process can be reduced, so that cutting resistance can be reduced. Arc-shaped tooth distribution facilitates improving of the cutting accuracy and surface smoothness, reduces cutting errors and surface defects, reduces impact and vibration in the cutting process, and further improves the cutting accuracy.