A machining data generation apparatus 4 is used in a sheet process system, which executes a plurality of times of processes by using one or more sheet process apparatuses processing a sheet by performing one or more times of machining and obtains a product in a desired form from the sheet, and generates machining data for operating the sheet process apparatus, and the machining data generation apparatus 4 includes a machining condition input unit 51 that inputs a machining condition for obtaining the product in a desired form from the sheet; a data generation unit 8 that generates the machining data including each machining data piece for operating the sheet process apparatus in order to execute each process in the plurality of times of processes, on the basis of the input machining condition; and a data output unit 71 that outputs the generated machining data to the sheet process apparatus that executes each process.

A die output lane assembly for receiving a blank through an opening of a die-cutter machine includes a frame, a support structure, and a memory device. The support structure is attached to the frame to form a lane and is configured to receive the blank from the opening of the die-cutter machine and temporarily store the blank in the lane. The memory device is configured to store data associated with the die output lane assembly thereon. The data includes at least one of a dimension of the die output lane assembly, a dimension of a cutting die of the die-cutter machine, a dimension of the blank, a pick position for removing the blank, a retraction path for removing the blank, a speed of part handling, or placement position data for storing the blank.

Systems and methods of the present disclosure relate generally to facilitate performing a task on a surface such as woodworking or printing. More specifically, in some embodiments, the present disclosure relates to mapping the surface of the material and determining the precise location of a tool in reference to the surface of a material. Some embodiments relate to obtaining and relating a design with the map of the material or displaying the current position of the tool on a display device. In some embodiments, the present disclosure facilitates adjusting, moving or auto-correcting the tool along a predetermined path such as, e.g., a cutting or drawing path. In some embodiments, the reference location may correspond to a design or plan obtained from obtained via an online design store.

In a method for guiding a cutting head in relation to a material, a position and a speed of the cutting head are set by means of a drive unit depending on a desired position value and a desired speed value established by an interpolator unit, a control signal for the drive unit is determined, a distance between the cutting head and the material is determined with a distance sensor, and a corresponding distance signal is provided. The distance signal is compared with a predetermined comparison distance to yield a distance-control signal, and the control signal for the drive unit is additionally determined dependent upon a distance-control signal. The comparison distance is subtracted from the distance signal and the difference is superimposed on the actual position signal, which is delayed by a first time period, wherefrom the distance-control signal is determined.

An ultra-high pressure pump (10) adapted to supply a constant flow of very high-pressure water for the cutting apparatuses of a water-jet and abrasive processing machine, comprising a control unit (15) consisting of a hydraulic pump (15′) connected to a servomotor (15″), a hydraulic switching and compensation unit (16) comprising at least one progressive opening cartridge (16′) and at least one high-speed solenoid valve (16″), a hydraulic accumulator (16′″), a pressure control device (17) and an attenuator unit (18) cooperating with a pressure intensifier unit (14) supplied by means of a low-pressure water circuit (23).

Disclosed embodiments include the production of construction plans upon planar surfaces such as studless walls near studless walls or traditional framing. Disclosed embodiments include specialized databases, cutting systems and printing systems useful for implementation of various plans upon planar surfaces sometimes used with hollow wall systems, sometimes constructed with bamboo or other fast growing sources of structural fiber, with the types of subject printing and cutting sometimes including architectural plans, structural plans, electrical plans, plumbing plans, mechanical plans, insulation plans, media plans, security plans and construction plans and details including those derived directly from various plans

Embodiments of the present disclosure are drawn to additive manufacturing apparatus and methods. An exemplary additive manufacturing method may include forming a part using additive manufacturing. The method may also include bringing the part to a first temperature, measuring the part along at least three axes at the first temperature, bringing the part to a second temperature, different than the first temperature, and measuring the part along the at least three axes at the second temperature. The method may further include comparing the size of the part at the first and second temperatures to calculate a coefficient of thermal expansion, generating a tool path that compensates for the coefficient of thermal expansion, bringing the part to the first temperature, and trimming the part while the part is at the first temperature using the tool path.

The present invention provides a panel cutting device and a panel cutting method. By using a sensing member to sense a mass change of residual material and prompt according to the mass change of the residual, it can be determined according to a prompt whether to stop the panel cutting device from operating, so the residual material is prevented from entering downstream equipment and damaging display panels. This solves an existing problem in a conventional panel cutting device, which residual material enters downstream equipment and damages display panels.

In a method for guiding a cutting head in relation to a material, a position and a speed of the cutting head are set by means of a drive unit depending on a desired position value and a desired speed value established by an interpolator unit, a control signal for the drive unit is determined, a distance between the cutting head and the material is determined with a distance sensor, and a corresponding distance signal is provided. The distance signal is compared with a predetermined comparison distance to yield a distance-control signal, and the control signal for the drive unit is additionally determined dependent upon a distance-control signal. The comparison distance is subtracted from the distance signal and the difference is superimposed on the actual position signal, which is delayed by a first time period, wherefrom the distance-control signal is determined.

A precut module with one or more profiling heads and/or circular saws may be provided upstream of a saw module. The precut module may be used to implement a portion of a cut that would otherwise be made by the saw module, thereby reducing the depth of cut required at the saw module. In some embodiments, profiling heads may be used to profile a block that is wider than a desired side board. The block may be cut from the workpiece and sent to the edger. This may provide the same or better wood volume recovery and/or throughput speed than profiling the side board or cutting the side board from a flitch. In some embodiments, cut patterns for the precut module and other machine centers may be calculated and/or selected based on a desired depth of cut at the saw module, desired throughput speed, wood volume recovery, and/or other parameters.