Prolean MFG

Basic Cutting Principle of Milling Milling removes material via rotating multi-tooth cutters that feed against stationary workpieces. On the shop floor, cutters perform intermittent cutting to shape flat surfaces, grooves and complex contours. We regulate spindle speed and feed rate based on workpiece material. Stable parameter settings reduce tool vibration and keep surface texture and dimensional tolerance within required ranges. #Milling #CNCMachining #MaterialRemoval

Process & Parameter Control for Waterjet Cutting A stable water pressure level and uniform abrasive supply are core to consistent cutting results. Operators adjust pressure, jet speed and abrasive dosage according to material thickness and hardness. The process delivers narrow kerf and smooth cutting edges without secondary finishing. It adapts to both thin sheets and thick solid blanks across different industrial materials. #WaterjetCutting #PrecisionCutting #FabricationTechnology

Cold Cutting Mechanism of Waterjet Cutting Waterjet cutting leverages high-pressure water combined with abrasive particles to erode materials. This cold processing approach produces no heat-affected zones during operation. On the shop floor, the focused jet travels along programmed trajectories to cut through workpieces. It avoids thermal deformation, which helps retain the original physical properties of various metals and composite materials. #WaterjetCutting #ColdMachining #MaterialProcessing

Die & Tooling Application in Stamping Dies act as the core component throughout metal stamping operations. Different die sets correspond to distinct structural features of parts. Workpieces are positioned before the press moves to complete one-shot forming. Reasonable die maintenance and gap inspection help maintain stable dimensional consistency for batches of stamped components. #MetalStamping #StampingProcess #ToolingTechnology

Fundamental Forming Logic of Metal Stamping Metal stamping applies continuous mechanical pressure to create plastic deformation on metal sheets. On the production floor, matched upper and lower dies define the final shape of workpieces. The process includes blanking, punching and forming steps. We keep pressure and die clearance within standard ranges to prevent burrs, material tearing or uneven surface on finished parts. #MetalStamping #SheetMetalForming #MetalFabrication

Dimensional & Edge Control In sheet metal processing, laser cutting delivers precise contour cutting for flat blanks. The non-contact processing mode avoids mechanical extrusion and workpiece deformation. Operators set parameters to control kerf width and edge smoothness. This process suits intricate patterns and small cutouts that traditional shearing tools cannot complete accurately. #LaserCutting #SheetMetalProcessing #CuttingTechnology

Working Principle of Laser Cutting Laser cutting uses focused high-energy laser beams to melt or vaporize metal materials. From our shop floor, the beam follows programmed paths to separate workpieces from raw sheets. Auxiliary gas blows away molten residue during cutting, which keeps cut edges neat. We adjust laser power and moving speed based on material thickness to maintain stable cutting performance. #LaserCutting #MetalFabrication #ThermalMachining

Tool & Positioning Standards for Bending In shop production, sheet metal bending uses dedicated upper and lower dies to shape flat blanks into three-dimensional parts. Precise backgauge positioning ensures uniform dimensions for each bend. We follow a reasonable bending sequence to avoid workpiece interference with equipment. This workflow maintains structural integrity for assembled sheet metal components. #MetalFabrication #BendingProcess #IndustrialParts

Deformation Logic in Sheet Metal Bending Sheet metal bending relies on mechanical force to create plastic deformation on metal panels. During operation, we control bending angle and radius according to material thickness and ductility. Inner material compresses while outer material stretches, and improper parameters will lead to cracks or uneven shapes. Operators select matching dies to keep consistent forming results across batches. #SheetMetal #MetalForming #FabricationProcess

Practical Application of 5-Axis Machining 5-axis CNC technology handles irregular profiles, deep cavities and curved surfaces in actual production. Operators compile adaptive tool paths matching part geometric shapes. Cutting tools keep optimal contact angles with work surfaces throughout processing. Such working features cater to the manufacturing demands of high-complexity customized mechanical components. #MachiningTech #SubtractiveManufacturing #EngineeringProduction