China YUSH Electronic Technology Co.,Ltd Company News

Machine Application   1. In-line automatic PCB separator can load,cut ,and un-load PCBs automatically to meet the needs of auotmatic factory. 2. Suitable for cutting small-sized PCBA panel used in cell phone,digital camera ,and GPS device. 3. Larger cutting size is suitable for cutting big sized PCBA panel used in TV,PC host,work station,sever etc. 4. Different options of unloading PCBs solutions,Achieve full automation and save labor cost.

The core precautions for operating a PCB Router Depaneling Machine are to ensure personal safety, avoid equipment damage, and ensure accurate and high-quality depaneling. Preparation Compare the PCB design files (Gerber files) with the machining program (G-code) to confirm that the cutting path, reference points, and tool parameters are correct. Check the machine's status, including spindle speed, vacuum suction pressure, fixture security, and whether safety devices such as the emergency stop button and safety door are functioning properly. Select a router blade (such as a carbide blade or a diamond-coated blade) that matches the PCB material (e.g., FR-4, flexible), thickness, and edge requirements. Ensure the blade is free of wear, breakage, or deformation. Operators must wear protective equipment, including a dust mask, safety glasses, and cut-resistant gloves, to avoid injury from debris and contact with the tool. Loading and Positioning Clean the PCB surface and the machine workbench to remove any oil, dust, or residual solder that may affect the suction effect. When using vacuum suction or clamping, ensure the PCB is flat against the tabletop, free of warping or offset, to prevent loosening during processing that could cause cutting errors. Use the machine's probe to calibrate the reference points and confirm positioning accuracy within ±0.02mm. Readjust positioning parameters if necessary. Process Control Before starting the machine, perform a dry run to verify that the tool motion path is consistent with the programmed path. Only begin formal processing if there is no risk of collision. Control the spindle speed and feed rate, adjusting them according to tool specifications and PCB thickness (typically 8,000-30,000 rpm and 50-300 mm/min). Avoid excessive speeds that may cause tool overheating, or excessive feed rates that may cause edge burrs or PCB tearing. Use a layered milling method, with each cut depth not exceeding 1/3 of the tool diameter. Complex contours require increased milling passes to reduce machining stress. Observe the machine's operating status during processing, paying attention to any unusual tool noises and smooth chip removal. Immediately press the emergency stop button if any abnormalities are detected. Safety Operating Procedures Do not open the safety door while the machine is operating. Do not touch the rotating cutter, PCB board, or worktable with your hands to avoid entanglement or scratches. Do not change cutters, adjust fixtures, or modify processing parameters while the machine is running. Always shut down the machine and disconnect the power cord before operating. When handling PCB debris, use an air gun or vacuum cleaner. Do not blow or remove with your mouth to prevent debris from entering the respiratory tract or scratching the skin. Post-Processing After shutting down the machine, wait until the cutter is completely still before removing the separated PCB unit to avoid damage from tool inertia. Clean the machine worktable, cutter, and suction device to remove any remaining debris to prevent it from affecting the accuracy of the next machining operation. Inspect the cut edges (for burrs and tears), dimensional accuracy, and circuit integrity of the PCB unit. If any quality issues are found, promptly investigate the process or cutter for potential causes. Equipment Maintenance and Care Regularly check cutter wear and replace any severely worn cutters to avoid compromising cutting quality or causing cutter breakage. Regularly clean the equipment's guide rails, lead screws, and spindles, and add lubricant to ensure smooth operation of moving parts. Regularly calibrate the equipment's positioning accuracy and vacuum pressure, record equipment operating parameters and maintenance status, and maintain a maintenance log.

As the demand for intelligent and flexible manufacturing continues to grow, electronic manufacturers are seeking more balanced solutions that combine efficiency, quality, and cost-effectiveness. In response, Dongguan Yushunli Automation Equipment Co., Ltd. has launched its latest Semi-Automatic SMT Line Solution, designed to help factories transition smoothly from manual operations to intelligent production. Modular Design for Multi-Size Compatibility The semi-automatic SMT line features a modular structure that allows flexible configuration of loaders, printers, placement machines, reflow ovens, inspection stations, and unloaders. It supports a wide range of PCB sizes, enabling one production line to handle multiple products efficiently and improving both equipment utilization and production flexibility. Reduced Labor Costs and Simplified Operations Striking the perfect balance between automation and human control, the system integrates smart alignment, automatic conveyance, and precise inspection modules. Operators can easily perform loading, inspection, and unloading tasks, reducing labor intensity and minimizing training requirements while improving consistency and throughput. Efficient Coordination and Scalable Integration The semi-automatic line enables seamless communication between each process through data interfaces, ensuring synchronized operations and process traceability. It can also be connected to MES systems for production data management and visualization, paving the way for gradual upgrades to fully automated production. Empowering Smart Manufacturing Transformation More than an entry-level automation solution, the semi-automatic SMT line serves as a strategic foundation for digital transformation. Combining high adaptability with cost efficiency, it empowers manufacturers to enhance productivity and quality without excessive investment. Dongguan Yushunli Automation Equipment Co., Ltd. remains committed to innovation, offering comprehensive automation solutions—from single machines to full production lines—to help customers build efficient, reliable, and intelligent manufacturing systems.

The operating principle of a PCB depaneling machine varies slightly depending on its type, but all share the core goal of separating individual PCBs from a panel with precision and minimal damage. Below is a detailed breakdown of the working principles for the most common types:   1. V-Cut Depaneling Machines   Principle: Utilizes mechanical force to separate PCBs along pre-scored V-shaped grooves (V-cuts) on the panel.   Process:   Preparation: The PCB panel is pre-machined with V-shaped grooves (typically 30°–60° angles) along the separation lines, leaving a thin remaining layer (0.1–0.3mm) to keep the panel intact during earlier manufacturing steps. Clamping: The panel is securely held in place by adjustable fixtures to prevent movement. Separation: A pneumatic or electric-driven blade/press applies controlled downward force along the V-cut lines. This force causes the remaining thin layer to bend and fracture cleanly, splitting the panel into individual PCBs. Key Feature: Uses minimal force to avoid stress on components, making it ideal for PCBs with components near the edges.   2. Router Depaneling Machines   Principle: Employs high-speed rotating cutters (milling tools) to mechanically cut through the panel along predefined paths.   Process:   Programming: The machine is loaded with the PCB panel’s CAD design, which specifies the cutting paths (usually along "breakaway tabs"—small connecting bridges between PCBs in the panel). Clamping: The panel is firmly secured on a vacuum table or mechanical 夹具 to prevent vibration during cutting. Cutting: A spindle (rotating at 30,000–60,000 RPM) with a specialized cutter (e.g., carbide or diamond-tipped) moves along the programmed path, removing material to separate the PCBs. Debris Removal: An integrated vacuum system extracts dust and copper shavings to avoid contamination and protect the cutter. Key Feature: Offers high flexibility for complex shapes and thick PCBs but requires careful programming to avoid mechanical stress.   3. Laser Depaneling Machines   Principle: Uses focused laser energy to vaporize or ablate material along the cutting line, achieving non-contact separation.   Process:   Laser Selection: CO₂ lasers (for organic materials like FR4) or UV lasers (for precision cutting of delicate materials like FPCs or ceramics) are used based on the PCB substrate. Alignment: Vision systems (cameras) locate the panel’s reference marks to ensure the laser aligns with the cutting path. Cutting: The laser beam (focused to a diameter of 10–50μm) scans along the separation line, heating and vaporizing the material. Multiple passes may be needed for thick panels to achieve a clean cut. Cooling: Air or water cooling systems prevent heat damage to nearby components. Key Feature: No mechanical force or contact, eliminating stress, burrs, or debris—ideal for high-precision, fragile PCBs (e.g., wearables, medical devices).   4. Punch Depaneling Machines   Principle: Uses a die (customized to the PCB shape) to stamp and separate PCBs from the panel with a single mechanical press.   Process:   Die Setup: A metal die matching the PCB panel’s layout is mounted, with sharp edges corresponding to the separation lines. Positioning: The panel is aligned under the die using guides or vision systems. Stamping: A hydraulic or mechanical press drives the die downward, shearing the panel along the edges defined by the die. Key Feature: Extremely fast (milliseconds per panel) but limited to simple, uniform PCB shapes and low-mix production.   Core Common Principles Across All Types   Precision Alignment: All machines use fixtures, vision systems, or reference marks to ensure cuts align with the designed separation lines. Minimizing Damage: Whether through controlled force (V-cut), high-speed cutting (router), non-contact energy (laser), or stamping (punch), the goal is to avoid damaging components, traces, or substrate integrity. Automation Integration: Most modern machines integrate with CAD software and production lines for seamless, repeatable operation.   The choice of machine depends on PCB material, size, component sensitivity, and production volume, but each type adheres to these fundamental operating principles to achieve efficient, accurate depaneling.

PCB depaneling machines are engineered with specialized features to address the precision, efficiency, and safety requirements of separating PCBs from panels. These features vary slightly by machine type (laser, router, V-cut, etc.) but share core functionalities tailored to electronics manufacturing. Here are their key characteristics:   1. High-Precision Cutting Capabilities   Microscopic Accuracy: Advanced models achieve positioning precision of ±10–20 µm, critical for cutting small or densely packed PCBs (e.g., smartphone camera modules or medical sensors). This ensures cuts align exactly with pre-designated lines, avoiding damage to nearby components. Consistent Cutting Tolerances: Maintain uniform edge quality across batches, with minimal burrs or debris. For example, laser machines produce burr-free edges, while router machines use precision spindles (up to 60,000 RPM) to ensure clean cuts even on thick, multi-layer PCBs.   2. Stress-Reduction Technology   Low-Mechanical-Stress Design: Minimizes physical force on PCBs during separation, preventing warping, delamination (layer separation), or component displacement. This is vital for fragile PCBs with surface-mount devices (SMDs) or flexible substrates (FPCBs). Laser machines use non-contact cutting, eliminating mechanical stress entirely. Router machines employ adaptive clamping systems that secure panels without over-tightening. V-cut machines use controlled bending (rather than cutting) along pre-scored lines, reducing stress on edge-mounted components.   3. Versatility Across PCB Types   Material Compatibility: Handles diverse substrates, including rigid PCBs (FR4, aluminum-backed), flexible PCBs (FPC), rigid-flex PCBs (RFPC), ceramics, and high-temperature materials (polyimide). Laser machines, for instance, adapt to thin films and exotic materials, while routers excel with thick, multi-layer boards. Size Flexibility: Accommodates panels of varying dimensions (from small 100×100 mm panels for wearables to large 600×500 mm industrial PCBs) and supports custom cutting paths via programmable software.   4. Automation & Integration   Smart Programming: Equipped with CAD/CAM software integration, allowing operators to import PCB panel designs (Gerber files) and auto-generate cutting paths. This reduces setup time and human error. Automated Loading/Unloading: In-line models feature conveyor systems, robotic arms, or vacuum pickers for continuous processing, ideal for mass production lines (e.g., automotive or consumer electronics factories). Sensor-Based Safety: Vision systems (cameras) detect panel alignment in real time, adjusting cutting paths if the panel shifts—critical for maintaining precision in high-speed operations.   5. Efficiency & Speed   High Throughput: V-cut machines can separate up to 200 panels per hour, while laser and router machines handle 50–100 panels/hour (depending on complexity). This scalability suits both small-batch prototyping and large-scale manufacturing. Multi-Tool Compatibility: Router machines often support multiple spindles or tool changers, enabling sequential cuts with different cutter types (e.g., roughing and finishing tools) in a single cycle.   6. Debris & Dust Management   Integrated Extraction Systems: Router and laser machines include vacuum or air-blown systems to remove dust, copper shavings, or resin debris. This prevents contamination of PCBs (critical for medical or aerospace applications) and maintains cutter longevity.   7. User-Friendly Operation   Intuitive Interfaces: Touchscreen controls with preset cutting profiles for common PCB types (e.g., "smartphone PCB" or "automotive BMS") simplify setup for operators with minimal training. Diagnostic Tools: Real-time monitoring of cutting parameters (speed, pressure, laser power) with alerts for anomalies (e.g., dull cutters or misalignment), reducing downtime.   8. Safety Features   Enclosed Workspaces: Laser and router machines use protective enclosures to shield operators from laser radiation, flying debris, or loud noise (router spindles can exceed 85 dB). Emergency Stop Mechanisms: Instant shutdown triggers if sensors detect misalignment, component interference, or operator proximity, preventing accidents.   These features collectively ensure that PCB depaneling machines deliver precise, reliable, and efficient separation—critical for maintaining PCB integrity and meeting the quality standards of industries like automotive, medical, and aerospace.

PCB depaneling machines are core equipment in the electronics manufacturing value chain, playing a critical role in the transition from "PCB panels" (large boards with multiple PCBs) to "individual PCBs" (ready for component assembly or end-use). Their applications span all industries that rely on printed circuit boards (PCBs), with specific use cases tailored to the industry’s unique requirements for PCB size, precision, and component sensitivity. Below is a detailed breakdown of their key application fields:   1. Consumer Electronics Industry (Largest Application Sector)   Consumer electronics are the biggest driver of PCB demand, and depaneling machines here focus on high precision, low stress, and mass production efficiency—since PCBs in these products are often small, densely populated with components, and require consistent quality.   Key application scenarios:   Smartphones & Tablets: PCBs for mainboards, camera modules, fingerprint sensors, and charging ports are typically panelized (e.g., 10–20 small PCBs per panel) to speed up SMT (Surface Mount Technology) assembly. Depaneling machines (often laser or router types) separate these tiny PCBs without damaging fragile components (like microchips or connectors) or causing warpage. Wearables (Smartwatches, Earbuds): These devices use ultra-small, thin PCBs (even flexible PCBs/FPCBs). Laser depaneling machines are preferred here because they offer stress-free, dust-free cutting—critical for avoiding damage to delicate sensors (e.g., heart rate monitors) or flexible substrates. Home Appliances: TVs, refrigerators, washing machines, and smart speakers use mid-sized PCBs (e.g., control boards, power boards). V-cut depaneling machines (for PCBs with pre-scored V-grooves) or router machines are commonly used here, balancing efficiency and cost for bulk production.   2. Automotive Electronics Industry (Fast-Growing Sector)   The rise of electric vehicles (EVs) and intelligent driving has surged demand for automotive PCBs, which require extreme reliability, high temperature resistance, and zero defects (since failures can affect vehicle safety). Depaneling machines here prioritize low mechanical stress and high cutting consistency.   Key application scenarios:   EV Components: PCBs for battery management systems (BMS), motor controllers, and on-board chargers (OBC) are often large and thick (to handle high currents). Router depaneling machines with robust clamping systems are used to cut these rigid PCBs, ensuring no delamination (layer separation) or component displacement. Intelligent Driving Systems: PCBs for ADAS (Advanced Driver Assistance Systems, e.g., radar, LiDAR, cameras) are densely packed with high-precision chips (e.g., SoCs). Laser depaneling machines are ideal here because they avoid mechanical force (which could disrupt sensor calibration) and create clean, burr-free edges. In-Vehicle Electronics: Infotainment systems, instrument clusters, and climate control PCBs use a mix of rigid and flexible-rigid PCBs (RFPCBs). Depaneling machines with adjustable cutting modes (e.g., combining laser for flexible parts and router for rigid parts) ensure compatibility with hybrid substrates.   3. Medical Electronics Industry (High-Precision, Regulatory-Driven Sector)   Medical devices demand sterilizability, biocompatibility, and absolute precision—PCBs here are often used in life-critical equipment (e.g., pacemakers) or diagnostic tools (e.g., ultrasound machines), so depaneling must avoid contamination, component damage, or material degradation.   Key application scenarios:   Implantable Devices (Pacemakers, Insulin Pumps): These use micro-sized, hermetically sealed PCBs. Laser depaneling (with ultra-fine laser beams, e.g., UV lasers) is the only option here—it cuts without physical contact, eliminates dust (critical for sterility), and avoids stress that could compromise the PCB’s hermetic seal. Diagnostic Equipment (Blood Analyzers, PCR Machines): PCBs in these devices have precise electrical pathways for signal transmission. Router depaneling machines with high-precision linear guides (positioning accuracy ±10 µm) ensure cuts stay within strict tolerances, preventing signal interference. Portable Medical Devices (Fetal Monitors, Handheld Ultrasounds): Lightweight, flexible PCBs (FPCBs) are common here. Laser depaneling for FPCBs avoids bending or tearing the flexible substrate, ensuring the device’s durability.   4. Aerospace & Defense Industry (High-Reliability, Harsh-Environment Sector)   Aerospace and defense PCBs must withstand extreme conditions (high temperature, vibration, radiation) and meet strict military/aviation standards (e.g., IPC-A-610, MIL-STD-202). Depaneling machines here focus on damage-free cutting and traceability.   Key application scenarios:   Aerospace Components: PCBs for aircraft avionics (flight control systems, communication modules) or satellite electronics are made of high-performance materials (e.g., ceramic substrates, polyimide). Laser depaneling machines compatible with these exotic materials cut without generating heat (to avoid material warping) and leave no residue. Defense Equipment (Radar Systems, Missile Guidance): These use thick, multi-layer PCBs (up to 20 layers) with heavy components (e.g., power transistors). Router depaneling machines with high-torque spindles and specialized cutters (e.g., diamond-tipped) handle thick substrates, ensuring clean cuts without layer separation.   5. Industrial Electronics Industry (Bulk-Production, Durability-Focused Sector)   Industrial equipment (e.g., factory automation, power tools) uses PCBs that prioritize durability and cost-effectiveness—they are often larger, less densely populated than consumer electronics PCBs, and produced in high volumes.   Key application scenarios:   Factory Automation (PLCs, Sensors): PCBs for programmable logic controllers (PLCs) or industrial sensors are panelized in large quantities (e.g., 50+ PCBs per panel). V-cut depaneling machines are widely used here—they are fast (separating 100+ panels per hour) and low-cost, ideal for bulk production. Power Electronics (Inverters, Transformers): Thick, high-voltage PCBs (with copper layers up to 3 oz) require robust cutting. Router depaneling machines with heavy-duty cutters handle these thick substrates, while built-in dust extraction systems prevent copper debris from short-circuiting components. Industrial IoT (IIoT) Devices: Smart sensors or connected industrial machines use compact PCBs. A mix of router and laser depaneling machines balances precision (for IoT chips) and efficiency (for bulk production).  

A PCB depaneling machine is a specialized equipment in the electronics manufacturing industry, mainly used to separate individual printed circuit boards (PCBs) from a panelized board. Here is a detailed introduction:   Definition and Function   In the PCB manufacturing process, multiple PCBs are often fabricated on a single large panel for convenience in processing and production. The PCB depaneling machine cuts or separates these interconnected PCBs from the panel, making them ready for subsequent assembly, testing, and other processes.   Types and Working Principles   Laser Depaneling MachinesLPKF Laser & Electronics: These machines use laser technology to cut the PCBs. They can achieve stress - free, dust - free, and even carbonization - free processing. For example, LPKF's laser depaneling machines use clean - cut technology to provide high - quality cut edges with high flexibility and are suitable for various materials such as FR4, FPCBs, ceramics, etc. Router Depaneling Machines: Also known as milling cutter depaneling machines, they use a rotating milling cutter to cut along the pre - designed cutting lines on the PCB panel. This type of machine can achieve high - precision cutting and is suitable for various types of PCBs. For example, Seprays' GAM 336AT in - line automatic PCB router depaneling machine can automatically load and unload panels and perform cutting operations. V - cut Depaneling Machines: These machines are used for PCBs that have been pre - scored with a V - cut. They use a pneumatically driven or electric - controlled mechanism to separate the PCBs along the V - cut lines. For example, the SAM SM - 4000 is a V - cut depaneling machine that can separate PCBs without causing bending or tension stress, and is suitable for PCBs with components close to the edges.   Characteristics and Advantages   High Precision: Can ensure accurate separation of PCBs, with a positioning accuracy that can reach up to ±20 µm or even higher in some advanced modelsLPKF Laser & Electronics. No Damage to PCBs: Advanced depaneling machines can minimize stress and mechanical damage to PCBs during the separation process, protecting sensitive components on the PCBs. High Efficiency: Can complete the depaneling operation quickly, improving production efficiency, especially suitable for mass - production scenarios. Flexibility: Can be adapted to different sizes, shapes, and materials of PCBs, with certain programmability and adjustability.   Application Scope   PCB depaneling machines are widely used in various fields of the electronics industry, including consumer electronics, automotive electronics, aerospace, and medical electronics, etc. They are an essential part of the PCB manufacturing and assembly process.