A dispensing container with a cutter, in which a storage part can be used as a refill. A dispensing container 100 with a cutter 54 includes a storage part 1, a helical tube 2, a rotating lid 5, and a movable plate 3. The storage part 1 has a tubular shape with an opening at a top and is configured to contain a solid material. The helical tube 2 has a helical groove on an outer peripheral surface thereof, and is configured to be attached to a bottom surface of the storage part. The rotating lid 5 is disposed to be horizontally rotatable and includes a top plate 51 and a peripheral wall 52 that is a side surface. The top plate 51 is provided with the cutter 54 on an underside thereof and has an outlet 53. The cutter 54 is configured to cut the solid material into a thin piece, and the outlet 53 is configured to discharge the cut thin piece of the solid material. The movable plate 3 has a hole into which the helical tube is fitted, and is configured to be raised within the storage part in conjunction with rotation of the rotating lid. The top plate 51 of the rotating lid has a fitting projection 55 that extends downward to be inserted into an upper end of the helical tube 2 so as to cause the helical tube 2 to rotate together with the rotating lid.

The cutting system is configured to cut a continuous strip which extends lengthwise in a longitudinal direction and widthwise between a first edge and a second edge into strips. The cutting system includes a drive device which imparts to the continuous strip a feed speed, a first cutting roller and a contrarotating second cutting roller that cooperate to cut the continuous strip across its full width. The first cutting roller is provided with a first helical blade and is driven in rotation A variable synchronizer makes it possible to select and to modify the synchronization ratio between the rotational speed of the first cutting roller and the non-zero forward speed of the continuous strip in such a way as to be able to adjust the cutting angle according to which the cross-section of the continuous strip is oriented with respect to the longitudinal direction of the continuous strip.

Positioning of a shield electric wire is performed by an insertion jig in front of a peeling jig, and a portion at a distal end of the shield electric wire where a metal foil is exposed is inserted into an electric wire insertion hole of a peeling jig through the center hole of an insertion jig. Air is blown from an opening on an other-end-surface side of the peeling jig toward the distal end of the shielded electric wire, and the metal foil is expanded while being separated from a wire core. A cut is formed from a side of a metal foil expanded by blowing air in a predetermined gap between a one-end-surface of the peeling jig and an end surface of the insertion jig, and the metal foil is cut from the cut as a starting point.

Insulated, load bearing wall panels are machined from a raw foam slab of foam material. The raw foam slab is loaded into a Turcotte sculptor. The Turcotte sculptor is an elegant 36-axis machine that machines the raw foam slab into one or more insulated foam wall panels. The Turcotte sculptor, in particular, may accept very large 18x4x2 feet slabs of foam material. The Turcotte sculptor then individually commands and actuates any of 36 linear actuators to produce the one or more insulated foam wall panels. The Turcotte sculptor, within minutes, simultaneously machines the raw 18x4x2 foam slab into two (2) 9-feet tall wall panels for 9-feet ceilings. The Turcotte sculptor may easily machine other wall sizes. The Turcotte sculptor thus efficiently and quickly volume produces entire one-piece, single-height insulated wall panels at reduced cost and with outstanding energy performance.

An apparatus for machining a ski includes a support for the ski and a device for conveying the ski in the longitudinal direction of the ski, along the support. The support is assigned a device for machining the side walls of the ski using at least one cutting tool, which is arranged on a tool carrier, the latter being guided adjustably in a direction transverse to the conveying direction and parallel to the support, and which, with the aid of a resilient actuator for the tool carrier, can be positioned, with resilient prestressing, against that side wall of the ski being conveyed along the support which is to be machined.

An apparatus for machining a ski includes a support for the ski and a device for conveying the ski in the longitudinal direction of the ski, along the support. The support is assigned a device for machining the side walls of the ski using at least one cutting tool, which is arranged on a tool carrier, the latter being guided adjustably in a direction transverse to the conveying direction and parallel to the support, and which, with the aid of a resilient actuator for the tool carrier, can be positioned, with resilient prestressing, against that side wall of the ski being conveyed along the support which is to be machined.

A separating device (10) for separating a tubular flat material (1) having an actual tube width (1.1), comprising at least one longitudinal separating unit (20) for removing a first edge region (2) and a second edge region (3) of the flat material (1) is provided. In addition, a separating method (100) for separating a tubular flat material and to a system (70) having a separating device (10) is provided.

A processing apparatus 1 includes: a workpiece-set-position recognition unit 114 that moves an arm distal-end portion to a specified position measurement point to measure a shape of a workpiece in a workpiece set state in which the workpiece is positioned by a workpiece positioning unit, and thereby recognizes a set position of the workpiece; a processing-point-information generation unit 115 that, based on the set position of the workpiece and processing-target-portion information 124 indicating a position of a target portion of the workpiece for specified processing, generates processing-point information 125 indicating a processing point which is a movement point of the arm distal-end portion to perform the specified processing on the workpiece using a processing tool in the workpiece set state; and a workpiece-processing control unit 116 that moves the arm distal-end portion to the processing point based on the processing-point information 125 to perform the specified processing on the workpiece using the processing tool.

An objective of the apparatus is to enable users to cut, seal, and crimp a sandwich. The apparatus is a sandwich maker that can apply pressure from both sides of the sandwich while sealing and crimping the sandwich, so as to make a perfectly rounded and spill proof sandwich. Additionally, the apparatus includes alignment pointers that enable users to create a crimped sandwich with perfectly crimped edges. Further, the apparatus includes multiple pieces and shapes that serve specific purposes and gives users the option to use them mutually exclusively. Furthermore, each of the different pieces of the apparatus have aesthetically appealing shapes and air gaps in the center, which enables users to release the sandwich easily.

A cartilage cutting device for a bone-in meat according to an embodiment includes a cutting blade disposed on a conveying path for a bone-in meat and an elastic support portion for elastically supporting the cutting blade so that the cutting blade can recede by a reaction force applied to the cutting blade when cutting the bone-in meat. The elastic support portion is configured such that an elastic supporting force of the elastic support portion is switchable between a first elastic supporting force and a second elastic supporting force. The first elastic supporting force is capable of cutting a cartilage adhering to a bone part of the bone-in meat. The second elastic supporting force is smaller than the first elastic supporting force and is incapable of cutting the cartilage.