A perforating apparatus may have a first roll comprising a first design and a second roll comprising a second design, each roll being in close proximity with a support member and each roll comprising a blade or an anvil. A web material may travel a first path between the first roll and the support member or, alternatively, may travel a second path between the second roll and the support member.

A perforating apparatus may have a first roll comprising a first design and a second roll comprising a second design, each roll being in close proximity with a support member and each roll comprising a blade or an anvil. A web material may travel a first path between the first roll and the support member or, alternatively, may travel a second path between the second roll and the support member.

A box unpacking device includes a robot, and a cutting device. A robot hand is attached to a wrist of the robot. The robot hand has a holding device configured to hold a packed box. The cutting device has a cutting blade of which the point is oriented downward or obliquely downward. The robot can move the box held by the holding device in a vertical plane, and change an angle of the box in the vertical plane.

Embodiments are directed to an automated cutting tool that is configured to cut open nonuniform enclosures, such as cases containing electronic components. An example system comprises a multi-speed motor that is coupled to a cradle. The multi-speed motor rotates the cradle at a selected speed, and the cradle adapted to hold a case. A cutting head is positioned adjacent to the cradle and is configured to maintain contact with the case during rotation of the multi-speed motor. The multi-speed motor is configured to operate at a first speed when first segments of the case are in contact with the cutting head and to operate at a second speed when second segments of the case are in contact with the cutting head.

Embodiments are directed to an automated cutting tool that is configured to cut open nonuniform enclosures, such as cases containing electronic components. An example system comprises a multi-speed motor that is coupled to a cradle. The multi-speed motor rotates the cradle at a selected speed, and the cradle adapted to hold a case. A cutting head is positioned adjacent to the cradle and is configured to maintain contact with the case during rotation of the multi-speed motor. The multi-speed motor is configured to operate at a first speed when first segments of the case are in contact with the cutting head and to operate at a second speed when second segments of the case are in contact with the cutting head.

A line-type auto glass cutout tool for use with a vacuum cup device having a vacuum cup and a base connected to the vacuum cup. The tool includes a tool body with a first winding spool mounted on the tool body for rotation about a first spool axis relative to the tool body. A first drive element is coupled to the first winding spool to rotate with the first winding spool about the first spool axis. The auto glass cutout tool also includes an attachment arrangement for releasably securing the tool body to the vacuum cup device in a tool operating position.

A line-type auto glass cutout tool for use with a vacuum cup device having a vacuum cup and a base connected to the vacuum cup. The tool includes a tool body with a first winding spool mounted on the tool body for rotation about a first spool axis relative to the tool body. A first drive element is coupled to the first winding spool to rotate with the first winding spool about the first spool axis. The auto glass cutout tool also includes an attachment arrangement for releasably securing the tool body to the vacuum cup device in a tool operating position.

A food processing attachment for a food processing device includes a rotational adapter configured to be selectively coupled with a drive system of the food processing device. A food holder is coupled to the rotational adapter and having a base, wherein the food holder is selectively rotated by the rotational adapter. A central spear extends perpendicularly from a center of the base. A plurality of radial flanges extend perpendicularly from the base, wherein each radial flange of the plurality of flanges is discontinuous with the other radial flanges, wherein the central spear and the plurality of radial flanges are adapted to secure a food item in a processing space and in communication with the rotational adapter. A blade is coupled to an operable carriage and is adapted to selectively engage the food item within the processing space to remove at least a portion of the food item.

A food processing attachment for a food processing device includes a rotational adapter configured to be selectively coupled with a drive system of the food processing device. A food holder is coupled to the rotational adapter and having a base, wherein the food holder is selectively rotated by the rotational adapter. A central spear extends perpendicularly from a center of the base. A plurality of radial flanges extend perpendicularly from the base, wherein each radial flange of the plurality of flanges is discontinuous with the other radial flanges, wherein the central spear and the plurality of radial flanges are adapted to secure a food item in a processing space and in communication with the rotational adapter. A blade is coupled to an operable carriage and is adapted to selectively engage the food item within the processing space to remove at least a portion of the food item.

A borehole is bored to a borehole target depth in a site and a geothermal heat exchanger is inserted into and then secured in the borehole at the desired depth. Once the heat exchanger has been secured in the borehole, the heat exchanger has a closed distal end and an open proximal end and has at least one fluid path between the closed distal end and the open proximal end, with installation fluid disposed in the fluid path(s). After securing the heat exchanger in the borehole and before excavation of a portion of the site immediately surrounding the borehole, the heat exchanger is temporarily sealed by installing, through the open proximal end, at least one respective internal seal in each fluid path. For each fluid path, the internal seal(s) will be disposed below a respective notional subgrade depth and excavation of the site immediately surrounding the borehole can proceed.