A conduit cutting assembly is comprised of a conduit cutting surface, a drive shaft, a top shield and a bottom guide. The conduit cutting assembly is inserted into a rotary device which provides a torque to rotate the conduit cutting assembly. The shield glides along the top surface of the conduit preventing deeper penetration of the cutting surface and deflecting dust as conduit is cut. The guide is positioned on the internal side of the conduit and prevents the cutting surface from contacting encased wiring. The distance between the bottom surface of the shield and the top surface of the guide is closely aligned to the conduit wall thickness. Conduit cutting assemblies can be customized for conduit material and conduit wall thickness. The conduit cutting assembly safely cuts through conduit without damaging encased wiring, limits incidental contact with the cutting surface, and limits contact with dust generated through the cutting procedure.

A power tool includes a spindle, a motor, an inner housing and an outer housing elastically connected to the inner housing. The inner housing is formed by a first inner housing portion formed of metal connected to a second inner housing portion formed of synthetic polymer. The first inner housing portion includes a housing part disposed in a front part of the outer housing, and a first extending part extending rearward from the housing part and disposed in a grip part of the outer housing. The second inner housing portion includes a second extending part that has a tubular shape and at least partially surrounds the first extending part, and a rear end part connected to the second extending part and disposed in a rear part of the outer housing. The first extending part extends rearward of a center of the second extending part in the front-rear direction.

A food cutting device includes a housing and a cutting mechanism, wherein a feeding port is arranged at one side of the housing, and a discharging port is arranged at the other side of the housing; the cutting mechanism includes a cutting portion and a push-pull portion for controlling reciprocating movement of the cutting portion; the cutting portion includes a sliding component, a first cutter and a plurality of second cutters; the sliding component is slidably connected with the housing; both the first cutter and the second cutters are located on the side of the sliding component close to the feeding port, and are detachably connected with the sliding component; and the first cutter is parallel to a sliding direction of the sliding component, and is not parallel to the second cutters. The food cutting device can meet various cutting requirements of people and is efficient.

A food slicer assembly includes a housing defining a first opening and a second opening perpendicularly arranged. A slicing blade received at the second opening enters the first opening of the housing. A coupling releasably couples a food product or a food product packaging to the housing. The first opening receives a food product therethrough, the second opening receives the slicing blade therethrough, and the slicing blade slices the food product arranged in the first opening such that the food product is divided into multiple portions using the food slicer assembly. The slicing blade may pass into the first opening from a first end, and upon reaching the second end, the slicing blade seals the food slicer assembly at the first opening. The assembly may be a cheese slicer assembly for slicing a block of cheese so that a slice of cheese can be removed from the first opening.

A deflectable lifting device can be mounted to a frame, work surface, or other member of a material conveying system. The deflectable lifting device can have a base that mounts into a mounting slot of a frame, and a bendable arm arranged in the pathway of a material conveying system, such as a paper stripping or paper blanking work station. When a sheet of material travels over the deflectable lifting device, the bendable arm can bend and deflect downwardly, but still contacts the sheet of material to provide a small margin of elevation or lift to the sheet of material. The sheet of material can therefore be elevated above edges, holes, or other obstructions in the pathway, which could otherwise jam or snag the delivery of the sheet of material.

A deflectable lifting device can be mounted to a frame, work surface, or other member of a material conveying system. The deflectable lifting device can have a base that mounts into a mounting slot of a frame, and a bendable arm arranged in the pathway of a material conveying system, such as a paper stripping or paper blanking work station. When a sheet of material travels over the deflectable lifting device, the bendable arm can bend and deflect downwardly, but still contacts the sheet of material to provide a small margin of elevation or lift to the sheet of material. The sheet of material can therefore be elevated above edges, holes, or other obstructions in the pathway, which could otherwise jam or snag the delivery of the sheet of material.

The present disclosure provides a display panel motherboard, including a first substrate and a second substrate arranged opposite to each other to form a cell. A display region and a non-display region surrounding the display region are provided at the first substrate and the second substrate. At the non-display region of the first substrate, a first spacer and a second spacer are arranged sequentially in a direction away from the display region of the first substrate. A vertical distance d1 between an end surface of the first spacer adjacent to the second substrate and a surface of the second substrate adjacent to the first substrate is equal to a vertical distance d2 between an end surface of the second spacer adjacent to the second substrate and the surface of the second substrate adjacent to the first substrate.

A cutting mechanism for a composite material lay-up head comprises a plurality of blades, each blade having a variable width, and a drive mechanism to drive the blades along an axial direction to cut a respective tow of composite material. The blades are rotatable about the axial direction between a first angular position, wherein the blades sever the respective tow along a first cutting direction transversal to a longitudinal direction of the respective tow, and a second angular position, wherein the blades sever the respective tow along a second cutting direction rotated by a rotation angle to the first cutting direction.

An electronic cutting machine includes at least one housing to which a drive roller is coupled for moving a sheet to be cut in a first direction and a cutter assembly coupled to the housing and moveable in a second direction that is perpendicular to the first direction.

A multi-axis machining tool is mounted on an asymmetric movable member driven by a motor housed in a sealed, stationary base. The asymmetric movable member is horizontally fixed and rotates about a central vertical axis in synchrony with the machining tool in order to increase the work envelope of the machining tool. Further, the machining tool has a first tool mounted on a tool head as well as second tool mount that may receive a second tool on the tool head without necessitating the removal of the first tool. The second tool is operable while the first tool is still mounted on the tool head. The machining tool may receive instruction from an operator or through pre-programmed code to couple or decouple the second tool without physical decoupling or coupling by the operator.