Establishment:

KIEE PCB was founded in 2017 with a clear and unwavering mission — to transform innovative ideas into reliable, production-ready electronic solutions that perform consistently in real-world environments. From the very beginning, our objective has never been limited to simply designing circuits that function in simulation software or laboratory testing. Our vision has always been larger: to engineer electronic systems that operate safely, efficiently, and dependably under real industrial conditions where reliability is not optional but essential.

Over the past 8+ years, KIEE PCB has developed strong hands-on expertise in PCB design, power electronics engineering, industrial control systems, and embedded electronics development. Our experience is built on practical exposure to demanding applications such as induction heating systems, switching power supplies, high-current controllers, automation boards, and custom industrial electronics. This real-world involvement has shaped our engineering philosophy — one that prioritizes durability, stability, and manufacturability above theoretical perfection.

We understand that electronic products do not operate in ideal conditions. They operate in environments where voltage fluctuations, thermal stress, mechanical vibration, electrical noise, and long operating hours are common. A design that performs perfectly in software simulation may fail when exposed to these real-world stresses. That is why our approach focuses on comprehensive engineering practices rather than isolated circuit design.

At KIEE PCB, we believe that a Printed Circuit Board (PCB) is not merely a physical platform that connects electronic components. It is the structural and functional backbone of an entire electronic system. Every routing decision, every copper thickness calculation, every grounding strategy, and every component placement directly influences the product’s performance and longevity. A poorly designed PCB can cause overheating, electromagnetic interference, signal distortion, power instability, or premature component failure. Therefore, each project we undertake is approached with precision, discipline, and long-term responsibility.

Our engineering process integrates electrical design principles with manufacturing feasibility and cost awareness. From the earliest concept discussions to the final Gerber file release, we ensure that every stage of development aligns with real production requirements. We do not design for prototypes alone — we design for scalable production and sustained field performance.

From concept development to final Gerber file generation, KIEE PCB supports startups, product innovators, industrial manufacturers, and small to medium-scale enterprises with precision-engineered PCB solutions. Whether the requirement is a custom control board, a high-current power module, or a multi-layer industrial PCB, we provide structured development support tailored to the application’s complexity and operating environment.

Our process begins with detailed requirement analysis. We carefully evaluate functional specifications, voltage and current ratings, switching frequencies, environmental conditions, safety requirements, cost targets, and mechanical constraints. Understanding these parameters at the initial stage enables us to design circuits that are not only technically sound but also commercially viable.

During schematic development, we prioritize component reliability, appropriate ratings, and electrical safety margins. Proper component selection is critical in industrial electronics, especially in high-voltage and high-current applications. Underrated components or insufficient safety margins can result in system instability or failure under load conditions. Therefore, our designs always include conservative engineering margins to enhance operational safety.

Once the schematic design is validated, we move to PCB layout development — a stage where performance optimization becomes central. PCB layout is not just about connecting nodes; it is about controlling current flow, managing heat, minimizing electromagnetic interference, and maintaining signal clarity. We apply EMI/EMC-aware routing strategies, ensuring that switching noise is contained and sensitive signals are protected from interference.

High-current trace design is another area where precision is crucial. Copper thickness, trace width, and current density calculations must align with real operating conditions. Improper current handling can lead to localized heating, copper degradation, and eventual board failure. At KIEE PCB, we calculate trace geometry based on load requirements and ambient conditions, ensuring long-term reliability.

Thermal management is a fundamental consideration in power electronics and industrial PCB design. Components such as MOSFETs, IGBTs, voltage regulators, and rectifiers generate significant heat during operation. Without proper heat dissipation planning, internal temperatures can rise rapidly, reducing component lifespan. We implement copper pours, thermal vias, heat spreader design techniques, and optimized component placement to distribute heat effectively across the board.

Our approach focuses not only on circuit functionality but also on performance stability, electrical safety, thermal resilience, and manufacturability. Safety mechanisms such as overcurrent protection (OCP), overvoltage protection (OVP), short-circuit safeguards, and thermal shutdown strategies are integrated wherever required. These protective features are essential in industrial applications where system failure can cause operational downtime or equipment damage.

Manufacturability remains a cornerstone of our development philosophy. A technically sound design must also be production-friendly. We prepare clear and organized Gerber files, drill data, pick-and-place files, assembly drawings, and Bill of Materials (BOM) documentation to ensure seamless coordination between design and fabrication teams. Proper documentation eliminates ambiguity, reduces production errors, and accelerates assembly timelines.

Component placement strategy is another critical factor in production optimization. Logical grouping of components, consistent orientation, and adequate spacing improve assembly efficiency and reduce soldering defects. By aligning layout decisions with manufacturing processes, we enhance overall production quality and repeatability.

In addition to technical robustness, cost efficiency is carefully evaluated during design. Component selection considers availability, lifecycle status, and sourcing practicality. We avoid overcomplicated layouts that increase manufacturing costs unnecessarily. Instead, we aim to achieve the optimal balance between performance, durability, and cost control.

KIEE PCB has extensive experience in industrial heating systems and power electronics applications. Designing control boards for induction heating machines and high-frequency switching systems requires deep understanding of transient behavior, gate drive timing, and electromagnetic interference. These systems operate under heavy electrical stress, and therefore PCB layout accuracy becomes critical. By minimizing loop areas, optimizing return paths, and isolating high-voltage sections, we enhance system efficiency and reduce noise-related issues.

Our development support extends beyond initial design stages. We assist clients during prototyping, helping identify improvements based on testing results. Prototype validation often reveals practical adjustments that further refine the design. Through iterative improvement, we ensure the final production version is stable and field-ready.

We also understand that industrial clients often require long-term technical consistency. Product upgrades, PCB redesigns, or reverse engineering services may become necessary when components become obsolete or performance improvements are desired. KIEE PCB provides structured redesign services that maintain functional integrity while improving performance or manufacturability.

Communication transparency is another key aspect of our service approach. Engineering collaboration works best when expectations are clearly defined and updates are consistently shared. We maintain structured communication with clients to ensure alignment at every stage of development. This reduces misunderstandings and builds long-term professional relationships.

Ultimately, our mission remains centered on engineering integrity. We are committed to converting innovative concepts into stable, scalable, and production-ready electronic systems. By combining disciplined engineering methodology with practical industry experience, we ensure that each PCB design supports long-term product success.

At KIEE PCB, reliability is not a marketing statement — it is a design principle. Every trace width calculation, every isolation clearance, every component selection decision reflects our responsibility toward the final product’s performance in the market.

Electronic products represent more than technology; they represent the trust of end users and the reputation of manufacturers. We take that responsibility seriously.

Our journey since 2017 has been defined by continuous learning, practical exposure, and disciplined improvement. Each project has strengthened our understanding of industrial electronics challenges and reinforced our commitment to engineering excellence.

As we move forward, KIEE PCB continues to refine its capabilities in PCB design, power electronics development, and industrial control systems. We remain dedicated to providing dependable, manufacturable, and scalable electronic solutions that empower innovation and support sustainable growth.

Because at the end of the day, a PCB is not just a board.
It is the foundation on which your entire product stands.

Our designs follow international PCB manufacturing guidelines defined by the IPC standards organization.

We consider electromagnetic compatibility guidelines based on international standards such as those referenced by IEC.

And at KIEE PCB, we engineer that foundation to last.