A cutting machine includes a cutting machine main body configured to cut a material transported along a longitudinal direction of a material into a plurality of cut materials, a material supply device and a product carrying-out device configured to carry the material into the cutting machine main body and to sort and carry out each of the plurality of cut materials into a product yard for accommodating a product or a residual material yard for accommodating a residual material of the material, respectively, and an NC device configured to control the cutting machine main body, the material supply device, and the product carrying-out device. The NC device is provided with a first operation mode for causing all of the plurality of cut materials to be carried out to the product yard 45.

Systems and methods for downsizing tires are disclosed. An automated downsizing apparatus comprises a cradle, mandrel table, cutting apparatus, and a control unit. A tire mounted on the cradle may be received by the movable and rotatable mandrel table, and positioned for engagement with the cutting apparatus. A user may customize a cutting configuration to be executed by the control unit. The control unit positions the mandrel table and cutting apparatus to remove portions from the tire, according to the cutting configuration. During operation, one or more system parameters may be monitored to determine compliance with the selected configuration, and the automated execution may be manually overridden.

Automated systems and processes for manufacturing post-tension tendons are provided. In one embodiment the system may comprise a conveyor configured to introduce a pre-determined length of a tendon into a tub; a cutter configured to cut the tendon when it meets the pre-determined length; and (c) a control unit configured for a user to input the pre-determined length and a pre-determined bundle diameter. The control until is typically operably connected to the cutter and to the tub. Advantageously, the tub is configured to coil the tendon to form a tendon bundle and tie the tendon bundle in the predefined bundle diameter. A movable seater station may be employed to fasten an anchor to one end of the strand and said seater station may be configured to move among two or more tubs. A manipulator may be employed to move and hang coiled tendons.

Systems and methods for downsizing tires are disclosed. An automated downsizing apparatus comprises a cradle, mandrel table, cutting apparatus, and a control unit. A tire mounted on the cradle may be received by the movable and rotatable mandrel table, and positioned for engagement with the cutting apparatus. A user may customize a cutting configuration to be executed by the control unit. The control unit positions the mandrel table and cutting apparatus to remove portions from the tire, according to the cutting configuration. During operation, one or more system parameters may be monitored to determine compliance with the selected configuration, and the automated execution may be manually overridden.

Systems and methods for downsizing tires, and an automated downsizing apparatus utilize a cradle, mandrel table, cutting apparatus, and a control unit. In various embodiments, a tire mounted on the cradle may be received by the movable and rotatable mandrel table, and positioned for engagement with the cutting apparatus. Users may customize one or more cutting configurations to be executed by the control unit. The control unit positions the mandrel table and cutting apparatus to remove portions from the tire, according to the cutting configurations. During tire downsizing operations, one or more system parameters may be monitored to determine compliance with the selected configuration, and the automated execution may be manually overridden.

A cutdown machine for a roller blind comprising: a cutting station between a feed station and an output station, wherein the cutting station comprises stationary clamps adjacently upstream and downstream of a cutter to hold and support the roller blind during and after cutting; a feed vacuum chuck and an output vacuum chuck to vacuum swarf during cutting of the roller blind, wherein the feed vacuum chuck is arranged upstream of the cutting station at the feed station, and the output vacuum chuck is arranged downstream of the cutting station at the output station; a heat blade adjacently downstream of the cutter to heat seal cut kerf edges of the roller blind after cutting; and wherein at least the cutter, stationary clamps, and feed vacuum chuck are servo actuated and controlled to automatically sequentially cut the roller blind into a plurality of roller blinds having custom widths.

A cutting machine includes a cutting machine main body configured to cut a material transported along a longitudinal direction of a material into a plurality of cut materials, a material supply device and a product carrying-out device configured to carry the material into the cutting machine main body and to sort and carry out each of the plurality of cut materials into a product yard for accommodating a product or a residual material yard for accommodating a residual material of the material, respectively, and an NC device configured to control the cutting machine main body, the material supply device, and the product carrying-out device. The NC device is provided with a first operation mode for causing all of the plurality of cut materials to be carried out to the product yard 45.

Systems and methods for downsizing tires are disclosed. An automated downsizing apparatus comprises a cradle, mandrel table, cutting apparatus, and a control unit. A tire mounted on the cradle may be received by the movable and rotatable mandrel table, and positioned for engagement with the cutting apparatus. A user may customize a cutting configuration to be executed by the control unit. The control unit positions the mandrel table and cutting apparatus to remove portions from the tire, according to the cutting configuration. During operation, one or more system parameters may be monitored to determine compliance with the selected configuration, and the automated execution may be manually overridden.

In a system for automatically manufacturing a pipe spool, when information on a pipe spool is input to a control unit, manufacturing of a spool pipe by cutting an original pipe, processing of a spool pipe, processing of a connection member, manufacturing of a straight pipe spool by welding a spool pipe to a connection member, and manufacturing a three-dimensional spool by welding a straight pipe spool to the other straight pipe spool or a connection member may be automatically performed by a sensor, an automatic device or a robot included in each process and the control unit connected to each of the devices.

A shearing machine includes a support frame, a magazine including a platform having a top surface extending between a processing end and a loading end, the magazine configured to support a plurality of struts on the top surface, a separator assembly configured to separate a separated strut from the plurality of struts, the separated strut defining a strut width, a feed assembly configured to move the separated strut relative to the support frame along a feed axis defining a feed direction, a shearing assembly disposed at the processing end, the shearing assembly including a die assembly operable to shear a strut segment from the separated strut, and a controller configured to control the separator assembly, the feed assembly, and the shearing assembly to automatically separate the separated strut, move the separated strut, and shear the strut segment from the separated strut to a predetermined length.