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2 Layer Aluminum PCB, Aluminum Backed PCB 2 Layer Manufacturer

March 21st, 2025

What is a 2 Layer Aluminum PCB?

A 2 layer aluminum PCB is a high-performance metal core PCB (MCPCB) designed for applications where heat dissipation and mechanical strength are critical. Unlike FR4-based PCBs, which rely on fiberglass as the core, aluminum PCBs use an aluminum alloy base to improve heat transfer and enhance mechanical support.

In a 2-layer aluminum PCB, two copper layers are stacked on top of a dielectric layer, which is then bonded to the aluminum substrate. Different with double sided aluminum PCB, the two copper trace layers of 2 layer aluminum PCB are on the one side, there is only one side enable to mount components.

Key Features of a 2-Layer Aluminum PCB:

  • Aluminum core for structural support & stable dimensions
  • Two copper layers for improved conductivity
  • Dielectric layers for electrical insulation
  • Efficient heat dissipation to prevent overheating

What Are the Layers of a 2 Layer Aluminum PCB?

A 2 layer aluminum PCB is constructed with the following layers:

  • Copper layer 1 (top layer) – The top conductive layer, where surface-mount components are placed.
  • FR4 material – Provides electrical insulation while allowing heat dissipation to the next layer.
  • Copper layer 2 (bottom layer) – The second conductive layer, allowing for more complex routing compared to single-layer designs.
  • Dielectric layer (thermal conductivity layer) – Filled with dielectric material, aiming to further insulates the second copper layer from the aluminum core.
  • Aluminum Base – A metal core that improves heat dissipation and mechanical durability. Commonly made of 6061, 5052, or 1060-grade aluminum

Additional layers, such as a solder mask and silkscreen, are often applied onto the top copper layer for protection and labeling.

4 vs 2 Layer Aluminum PCB Stack up

A 4-layer aluminum PCB adds more conductive layers to support higher circuit complexity, but it also increases manufacturing costs and thickness. They have different stack ups, but the layers construction is the same, see the stack ups as following:

4 vs 2 Layer Aluminum PCB Stack up

Advantages & Disadvantages of Aluminum PCB

  • Advantages:

✅ Excellent Heat Dissipation – Aluminum conducts heat 8–9 times better than FR4, reducing thermal stress and preventing higher thermal damage to the components.

✅ Better Mechanical Strength – Due to its metal base, it is more durable than traditional PCBs, resistant to bending and cracking.

✅ Higher Circuit Density – Two stacked copper layers allow for more intricate circuit designs.

✅ Reduced PCB Size and Money Saving – Since heat dissipation is built-in, external heat sinks are often not needed, reducing the overall circuit footprint.

✅ Lower Thermal Expansion – Aluminum base has stable dimension and lower thermal expansion, prevents warping or deformation under high temperatures.

✅ Lightweight – Lighter than copper-based PCBs, it is suitable for those weight sensitive projects, such as automotives.

✅ Eco-Friendly – Aluminum is recyclable, making it a greener choice.

  • Disadvantages:

❌ Higher Cost – More expensive than FR4 PCBs due to complex manufacturing.

❌ Limited Multilayer Options – Aluminum PCBs typically do not exceed 4 layers, unlike FR4, which can have up to 40 layers.

What is the Difference Between FR4 and Aluminum PCB?

When our sales talking with customers, there is always be mentioned that what are the differences between normal FR4 pcb and aluminum PCB? Most of them in the design consultation stage are not sure which circuit board is more suitable for their needs. Today, to give more engineers a clear understanding, Best Team listing the different characteristics and parameters between them, hope it is easy to make you sense.

FeatureFR4 PCBAluminum PCB
Core MaterialFiberglass (FR4)Aluminum Metal Base
Thermal Conductivity0.3 – 0.4 W/m·K1.0 – 3.0 W/m·K
Heat DissipationRequires external heat sinksDirect heat dissipation
Mechanical StrengthModerateHigh (resistant to bending)
WeightLightweightSlightly heavier, but lighter than copper-based PCB
Electrical InsulationHighLower (requires dielectric layer)
Manufacturing Cost (under the same design)LowerHigher
Maximum LayersUp to 100 layersTypically 1 – 4 layers
FlexibilityCan be rigid or flexibleCan be rigid and semi-flexible (use special technique)
ApplicationsConsumer electronics, computing
Mainly in LEDl lightings
DurabilityLess resistant to thermal expansionHigh thermal stability

How Thick is the Dielectric Layer of an 2 Layer Aluminum PCB?

As we know, a thinner dielectric layer offers better heat transfer, but lower insulation resistance. Normally, the dielectric layer used in a 2-layer aluminum PCB typically ranges between 75”m to 200”m. Each has its different thermal conductivity, choosing the right thickness depends on current requirements and operating conditions.

Dielectric Thickness (mm)  Thermal Conductivity (W/m·K)Common Application
0.075 mm (75”m)1.0 – 1.5Low-power circuits
0.1 mm (100”m)2.0 – 3.0LED lighting, power modules
0.15 mm (150”m)3.0 – 5.0High-power applications

How to Make a 2 Layer Aluminum PCB?

The manufacturing process of a 2 layer aluminum PCB is different from standard FR4 PCBs due to the presence of a metal core. The following steps detail the fabrication process, show how Best Technology manufacture the 2 layer aluminum PCB:

1. Material Selection

Choosing high-quality materials is the foundation of a reliable 2 layer aluminum PCB.

  • Aluminum Core: Typically 6061, 5052, or 1060-grade aluminum, offering high thermal conductivity and mechanical strength.
  • Copper Foil: 1 oz to 4 oz copper thickness, depending on current-carrying requirements.
  • Dielectric Layer: 75um-200um, depends on the project demand.

2. Manufacture a Double Sided FR4 PCB

Manufacture a double sided FR4 PCB according to the files. Both top and bottom copper traces are plated into the required thickness.

3. Laminate the Dielectric Layer

A dielectric layer is added between the aluminum base and the FR4 PCB, then laminate them into a whole product. The thickness of this layer varies from 0.075 mm to 0.15 mm, depending on the thermal performance required.

4. Circuit Patterning (Imaging & Etching)

  • A photosensitive dry film is applied to define circuit traces.
  • UV exposure and development create the desired circuit pattern.
  • An etching process removes unnecessary copper, leaving behind precise circuit traces.

5. Drilling & Plating

  • Precision drilling creates vias and mounting holes.
  • A plating process is used to form electrically conductive vias, connecting the top and bottom copper layers.
  • The aluminum base is not conductive, so plated through-holes (PTHs) require special insulation to prevent electrical shorts.

6. Solder Mask & Silkscreen

  • A protective solder mask is applied to prevent oxidation and improve insulation.
  • Silkscreen printing is added for component labeling and identification.

7. Surface Finish Application

The surface finish ensures solderability and prevents oxidation. Common options include:

  • HASL (Hot Air Solder Leveling) – Cost-effective but not ideal for fine-pitch components.
  • ENIG (Electroless Nickel Immersion Gold) – Provides a smooth, corrosion-resistant surface.
  • OSP (Organic Solderability Preservative) – Environmentally friendly and cost-efficient.

8. Testing & Quality Inspection

  • Automated Optical Inspection (AOI) verifies circuit accuracy.
  • Electrical testing ensures there are no open circuits or shorts.
  • Thermal testing checks heat dissipation performance.

Once the PCB passes inspection, it is ready for component assembly or shipping to customers. Here is a manufacturing process video of aluminum, hope this is easy for you to understand.

Differences Between 6061, 5052, and 1060 Aluminum Alloy

When manufacturing a 2 layer aluminum PCB, selecting the right aluminum alloy is essential for achieving the desired thermal conductivity, mechanical strength, and corrosion resistance. The three most common aluminum alloys used in PCBs are 6061, 5052, and 1060, each offering different properties suitable for various applications.

Property6061 Aluminum5052 Aluminum1060 Aluminum
Composition  Al-Mg-Si alloyAl-Mg alloyHigh-purity aluminum (≄99.6%)
Thermal Conductivity150 – 170 W/m·K138 – 147 W/m·K230 – 237 W/m·K
Mechanical StrengthHigh (275 – 310 MPa tensile strength)Moderate (190 – 240 MPa tensile strength)Low (60 – 100 MPa tensile strength)
Corrosion ResistanceModerateHigh (excellent saltwater resistance)Low (prone to corrosion)
WorkabilityGood machinability, harder to bendEasy to form and bendVery soft, easy to process
CostHigherModerateLower
  • For high-power applications (e.g., power amplifiers, automotive circuits): 6061 is ideal due to its strength.
  • For outdoor or humid environments (e.g., industrial lighting, marine electronics): 5052 offers the best balance.
  • For cost-effective, high-thermal applications (e.g., LED lighting, heat-sensitive electronics): 1060 is the best choice.

At Best Technology, we have various aluminum base in our storage, whatever you want to use 6061, 5052 or 1060, we can meet your requirements. As a reliable 2-4 layer metal core pcb (mcpcb) aluminum manufacturer, we specialize in custom aluminum-backed PCBs, ensuring high quality, competitive pricing, and fast turnaround times. Whether you need prototyping or mass production, our engineering team is ready to assist you. Contact us right now to get your quotation!

DC and AC Inverters: What You Need to Know

March 20th, 2025

DC and AC inverters are essential components in today’s energy systems. Whether you’re harnessing the power of the sun with solar panels, working with backup power solutions, or simply need a way to power your devices, understanding how these inverters work is crucial. This blog breaks down the purpose, advantages, and practical use of DC and AC inverters, helping you make informed decisions based on your needs.

What is a DC and AC Inverter?

Inverters are electrical devices that convert DC (direct current) to AC (alternating current), or vice versa. Typically, DC power comes from sources like batteries or solar panels, while AC is what you use to power most household appliances. A DC to AC inverter is used to convert the DC power into usable AC power. On the other hand, an AC to DC inverter does the reverse, converting AC power into DC to charge batteries or power DC devices.

In simple terms, a DC to AC inverter allows you to use power from sources like batteries or solar panels in everyday devices that require AC power, such as fans, lights, and even refrigerators. Without inverters, it would be challenging to use energy from renewable sources for traditional home appliances.

DC and AC Inverters: What You Need to Know

What is the Purpose of a DC to AC Inverter?

The primary purpose of a DC to AC inverter is to make DC power usable for AC appliances. Whether you’re working with a solar power system or simply need backup power, inverters are the key to making this energy conversion happen. For example, if you’re using a solar panel setup, you typically generate DC power. Since most home appliances run on AC, you need an inverter to convert that energy into a form you can use.

Inverters are essential in off-grid applications, such as in remote areas, where the electricity grid is unavailable. They provide an efficient way to use stored DC power, converting it into AC electricity for devices that would otherwise be useless.

How Does an Inverter Work When There is No Electricity?

When there’s no grid electricity, inverters can still work by drawing power from other sources like batteries or solar panels. This is particularly helpful in off-grid or emergency situations. The inverter takes the DC power from your stored energy and converts it into AC power to keep your appliances running.

For example, if you have a solar power system with a battery backup, and the power goes out, the inverter allows you to keep your appliances on, as long as your batteries have enough charge. In this way, inverters provide an essential role in maintaining power continuity during outages.

DC Inverter AC Advantages and Disadvantages

DC inverters come with several benefits, particularly in renewable energy applications like solar power systems. They are highly energy-efficient and help convert power from DC sources into usable AC power without much loss. This makes them perfect for off-grid living or areas where solar panels are the primary source of energy.

However, there are some drawbacks. DC inverters may have higher upfront costs, and the complexity of conversion can lead to minor energy losses. They also tend to require more maintenance due to the way they manage energy conversion.

On the flip side, AC inverters are generally more efficient in household and industrial settings because AC power is more compatible with most appliances. Their downside lies in the additional energy needed to convert AC power into usable DC energy when dealing with solar systems or battery charging applications.

Despite these differences, both types of inverters have their place, and their advantages often outweigh the disadvantages when used in the right scenarios.

DC and AC Inverters: What You Need to Know

Which is Better: AC Inverter or DC Inverter?

Choosing between an AC and DC inverter depends on your specific needs. AC inverters are more commonly used for residential and industrial applications, as they are designed to power traditional household appliances. They are easy to integrate into existing power systems and typically provide a reliable power source for most needs.

On the other hand, DC inverters are especially useful for renewable energy applications. If you’re installing solar panels or using a battery backup, a DC inverter is the best choice, as it can convert the stored DC power into AC power for your home. They are also more energy-efficient in off-grid situations, where you rely entirely on solar or battery power.

Ultimately, the “better” inverter is the one that fits your particular power needs. If you’re on the grid or need to power AC devices from a DC source, an AC inverter is the way to go. But for renewable energy setups, DC inverters are a better fit.

How Long Will a 12V Battery Last with an Inverter?

The lifespan of a 12V battery when used with an inverter largely depends on the wattage of the devices you’re powering. Inverters typically drain the battery at different rates based on the energy demand of the connected devices. For instance, if you’re running a light or small appliance, the battery can last for several hours. However, larger appliances like refrigerators or air conditioners will drain the battery much faster.

On average, a 12V battery can provide power for anywhere from 3 to 10 hours with an inverter, depending on the load. It’s essential to size your inverter and battery capacity properly to ensure your system works efficiently. By balancing energy use with battery life, you can maximize the performance of your inverter system.

How to Choose a DC AC Inverter?

Choosing the right DC to AC inverter involves considering several factors. First, determine the type of devices you’ll be powering. Consider the total wattage your devices require. Inverters come in various sizes and capacities, so it’s essential to match the inverter’s output with your needs.

Next, consider the efficiency of the inverter. More efficient models will waste less power and give you better performance, especially if you’re using renewable energy sources like solar power. You should also think about the inverter’s durability, features like surge protection, and whether it has any warranties or support.

The inverter’s voltage rating must also align with your power system. For example, in a 12V system, you should choose a 12V DC to AC inverter. Also, remember to check the inverter’s surge capacity, especially if you’re powering devices with a high initial startup load, like motors.

Why PCB is Important in DC and AC Inverters?

PCBs (Printed Circuit Boards) play a crucial role in both DC and AC inverters by providing the necessary connections and support for various electrical components. Inverters rely on PCBs to ensure proper functionality, reliability, and safety. For DC to AC conversion, the PCB helps in routing the signals between critical components like transistors, diodes, and capacitors, ensuring the conversion process runs smoothly.

In both types of inverters, the PCB also helps dissipate heat, manage power efficiently, and prevent potential short circuits. High-quality PCBs are essential for maintaining the long-term durability and performance of inverters, particularly in energy-intensive applications like solar or backup power systems. The design, material quality, and structure of the PCB can directly affect the efficiency and lifespan of the inverter, making it a key component in any inverter system.

DC and AC Inverters: What You Need to Know

With over 18 years of experience in the PCB manufacturing industry, Best Technology is a trusted name in providing high-quality, reliable PCBs for various applications, including inverters. Our expertise and commitment to innovation allow us to create tailored solutions for both residential and industrial energy systems. Whether you’re looking for robust PCBs for solar inverters, backup power solutions, or any other inverter application, Best Technology ensures precision and durability in every product we deliver. For more information about PCB and PCB assembly, pls feel free to contact us at sales@bestpcbs.com.

FAQs

1. What is the main difference between a DC inverter and an AC inverter?

The main difference is that a DC inverter converts direct current (DC) to alternating current (AC), while an AC inverter converts AC to DC.

2. Can an inverter work without a power source?

Yes, inverters can still function when connected to a backup power source, such as a battery or solar panel, even if there’s no grid electricity.

3. How do you size an inverter for your needs?

The inverter should be sized based on the wattage of the devices you want to power. Make sure the inverter’s output matches or exceeds the required load.

4. What are the typical applications of a DC to AC inverter?

DC to AC inverters are typically used in off-grid applications, renewable energy systems, and backup power solutions.

5. Do DC inverters have better energy efficiency than AC inverters?

Yes, DC inverters are generally more energy-efficient in solar and battery-based systems as they convert stored energy directly without much loss.

Copper Clad Laminate Manufacturing Process

March 20th, 2025

Copper clad laminate (CCL) is crucial in printed circuit boards (PCBs), providing structural integrity and conductivity. Whether you are a PCB designer, engineer, or manufacturer, understanding CCLs will help you choose the right materials for your applications. In this guide, we explore CCL types, uses, and pricing, along with an in-depth look at its manufacturing process.

Best Technology offers comprehensive PCB manufacturing solutions, seamlessly integrating design, prototyping, assembly, component sourcing, and 360° technical support across the entire project lifecycle. Leveraging advanced lamination systems and high-precision CNC drilling machines from Hitachi and Timax, we ensure exceptional accuracy in multilayer PCB fabrication. Backed by a seasoned R&D team and engineers with over 10 years of industry experience, we guarantee a prompt response within 12 hours. Punctual delivery is our commitment, ensuring your projects stay on track. Feel free to reach out to us at sales@bestpcbs.com for any copper-clad laminate PCB needs.

Copper Clad Laminate Manufacturing Process

What is Copper Clad Laminate?

Copper clad laminate (CCL) is a composite material made of a non-conductive substrate (such as fiberglass, resin-impregnated paper), filler, and other chemicals, with a thin copper foil layer bonded to one or both sides. It serves as the foundation for PCB fabrication, ensuring electrical pathways are properly formed while offering mechanical support. CCLs are widely used in consumer electronics, automotive applications, and industrial equipment.

Copper Clad Laminate

What is Flexible Copper Clad Laminate?

Flexible copper clad laminate (FCCL) is a variation of CCL that uses a flexible substrate instead of rigid fiberglass. The most common substrate materials include polyimide or polyester, and FCCL is produced by laminating copper foil onto polyimide film (PI), making FCCLs suitable for bendable and lightweight applications. These laminates are commonly found in wearables, foldable devices, and medical electronics, where flexibility is a key requirement.

Copper Clad Laminate

What is Copper Clad in PCB?

In PCB manufacturing, copper clad laminate acts as the base material that undergoes etching, drilling, and layering processes to create functional circuits. The copper layer allows for efficient electrical conductivity, while the substrate provides insulation and mechanical support. PCBs can have single-sided, double-sided, or multi-layer configurations, depending on design complexity.

What are the Different Types of Copper Clad Laminate?

There are several types of CCLs, each designed for specific performance requirements:

  • FR-4 – The most widely used CCL, composed of woven glass fabric and epoxy resin, offering excellent electrical insulation and thermal resistance.
  • CEM-1 – A cost-effective option with a paper-based core and fiberglass reinforcement, ideal for single-sided PCBs.
  • CEM-3 – Similar to FR-4 but with a finer glass weave, providing better flexibility and processing ease.
Copper Clad Laminate
  • Flexible Copper Clad Laminate (FCCL) – Uses polyimide or polyester as a base, enabling use in applications requiring bending or flexing.
  • Metal Core CCL – Features an aluminum or copper core for better heat dissipation, commonly used in LED lighting and power electronics.
  • High-Frequency CCL – Designed for RF and microwave applications, using PTFE or ceramic-based substrates for improved signal integrity.

What is the Difference Between Copper and Copper Clad?

Copper is a pure metal known for its excellent electrical and thermal conductivity. Copper clad laminate, however, is a composite material where a thin copper layer is bonded to an insulating substrate. While pure copper is used in electrical wiring and heat exchangers, copper clad laminates serve as the base for PCBs, allowing for structured circuit pathways while maintaining mechanical stability.

What is the HS Code for Copper Clad Laminates?

The Harmonized System (HS) code ‌7410.11‌ is widely used for ‌copper clad laminates‌ in international trade. This classification applies to materials consisting of copper foil (printed or unprinted) bonded to an insulating substrate such as fiberglass, epoxy resin, paper, or other dielectric layers.‌

  • 7410.11‌: Covers copper foil laminated with insulating materials, regardless of surface patterning. These laminates serve as core materials for manufacturing printed circuit boards (PCBs), enabling electrical conductivity and structural support.

‌Critical Considerations:‌

  • Regional Variations‌: Some jurisdictions classify PCB-ready laminates (pre-etched or pre-engineered for circuitry) under ‌8547.20‌ (“printed circuits”).
  • Example: China may categorize advanced laminates under ‌8547.20‌ if they are explicitly designed for PCB production.
  • Material-Specific Codes‌: Laminates with plastic-based substrates (e.g., phenolic resin) might fall under ‌3921.90‌ (“plastic laminates”).

Verification‌: Pls consult local customs or a licensed broker for binding rulings in necessary situation, as interpretations vary. For instance:

  • U.S. HTS: May use ‌7410.11.0000‌ for basic laminates.
  • EU TARIC: Could require additional subcodes based on thickness or resin type.
Copper Clad Laminate Manufacturing Process

What is the Price of Copper Clad?

The price of copper clad laminate varies based on factors like copper thickness, substrate type, and manufacturing complexity. Here are the key factors that impact pricing:

  • Copper Thickness – Thicker copper layers increase cost due to the higher material requirement.
  • Substrate Material – FR-4 is pricier than paper-based laminates like CEM-1.
  • Processing Complexity – Advanced CCLs with high-frequency capabilities cost more to manufacture.
  • Market Demand – Prices fluctuate based on raw material availability and global market trends.
  • Order Volume – Bulk purchases typically come with lower unit costs.

Standard FR-4 CCLs typically range from $5 to $15 per square meter, while high-performance laminates designed for RF applications can cost significantly more.

What is the Manufacturing Process of Copper Clad Laminate?

What is copper clad laminate manufacturing process? Manufacturing copper clad laminate involves precise processes to ensure consistent quality and performance. Here take the double-sided copper clad laminate as a case. The production of double-sided copper clad laminates generally follows these steps:

1. Film Printing – Prepare and print the design film.

2. Board Cutting – Cut the board to size, keeping a 20mm process edge.

3. Drilling – Set the board thickness to 2.0mm or 1.6mm, ensuring the drill tip is 1-1.5mm above the PCB surface. Use Create-DCM software to generate U00 format drill files for CNC machines.

4. Polishing – Remove surface oxidation, oil stains, and burrs from drilling.

5. Hole Inspection – Ensure hole clarity for proper chemical penetration. Inspect the drilled and polished board under light to check if the holes are clear and unobstructed.

6. Pre-soaking – Remove oil, oxidation, and copper powder while adjusting the charge for better carbon particle adsorption.

7. Water Rinsing – Thoroughly rinse with clean water to remove chemical residues.

8. Drying – Eliminate residual moisture inside the holes using a drying oven or electric blower.

9. Activation – Coat the inner hole walls with nano-carbon particles to enhance conductivity.

10. Through-Hole Processing – Remove excess activation liquid to ensure all holes remain open using a vacuum cleaner.

11. Curing – Secure carbon particles to the hole walls and dry them with airflow.

12. Repeat Steps 9-11 for better adhesion.

13. Micro-etching – Remove excess carbon particles and wipe off black residues from the copper surface.

14. Water Rinsing – Clean the board thoroughly.

15. Copper Plating – Immerse in a copper plating bath for 20-30 minutes at a current of approximately 3-4A/d㎡ (adjust as needed). This process ensures electrical conductivity by plating copper on the hole walls.

16. Water Rinsing – Clean the surface after plating.

17. Drying – Dry the board and remove any residual moisture in the holes.

18. Lamination – Apply the dry film using a lamination machine.

19. Exposure – Expose the film to light for approximately 3 minutes.  Align the film (negative film at this stage) with the board first. Ensure correct alignment of the negative film for double-sided circuits.

20. Developing – Remove unexposed film in a developing solution at 45-50°C while observing changes on the board.

21. Water Rinsing – Rinse thoroughly to remove residues.

22. Etching – Etch at 45-50°C to remove unwanted copper.

23. Water Rinsing – Wash off any remaining etchant to prevent further corrosion.

24. Stripping – Use a strong alkaline solution to remove the dry film.

25. Water Rinsing – Rinse thoroughly.

26. Drying – Dry the board completely.

27. Tin Plating – Perform micro-etching, rinsing, and tin plating to protect exposed copper areas from oxidation and improve solderability.

28. Edge Cutting – Trim off excess material from the fabricated board based on the circuit outline and smooth the board edges using a manual grinding tool.

This process ensures high-quality double-sided copper clad laminate for various PCB applications.

Copper Clad Laminate Manufacturing Process

Copper Clad Laminate Manufacturers

Several manufacturers produce high-quality copper clad laminates for different industries. Some of the leading names include:

  • Doosan Corporation Electro-Materials – A global leader in FR-4 and high-performance CCL production.
  • Shengyi Technology – Specializes in advanced CCLs for high-frequency and RF applications.
  • Rogers Corporation – Renowned for high-frequency laminates used in 5G and aerospace applications.
  • ‌DuPont‌ – Known for high-reliability materials like polyimide-based CCLs for flexible circuits and high-temperature applications.

Best Technology Primarily dedicated to PCB manufacturing, we also source and supply copper clad laminates, providing customers with reliable materials tailored to their specific requirements.

In conclusion, copper clad laminate plays a vital role in PCB manufacturing, influencing performance, cost, and durability. Understanding its manufacturing process, types, and pricing helps engineers and buyers make better decisions. Whether you need rigid FR-4 laminates or flexible options for advanced applications, choosing the right material ensures optimal performance and reliability.

For those sourcing copper clad laminates, partnering with a reputable manufacturer guarantees high-quality materials and consistent supply. We provide one-stop PCB manufacture service, including PCB assembly and component purchasing and all-around technical support before and after-sales. Just feel free to reach out to us at sales@bestpcbs.com for any printed circuit board needs.

LED Bulb PCB Design, Prototype & LED Bulb PCB Manufacturer

March 20th, 2025

LED Bulb PCB integrates power supply and heat dissipation to ensure stable and efficient operation. Would you like to know more about it? Let’s learn more about advantages, types, materials and design steps of LED Bulb PCB from this blog.

At Best technology, we focus on high quality LED Bulb PCB design, prototype and manufacturing over 18 years. We adopt lead-free and halogen-free material boards and obtain RoHS environmental certification to achieve no pollution to the environment. And we can provide one-stop PCB solutions services from signal integrity optimization, thermal management simulation to dynamic heat dissipation of aluminum substrates. And we have professional engineer team provides free technical support for board design and brightness scheme adjustment, which can help you reduce BOM costs a lot. If you’re interested in our service, please feel free to contact us sales@bestpcbs.com.

What Is LED Bulb PCB?

LED bulb PCB is a specialized circuit board designed to power and control light-emitting diodes (LEDs) in lighting applications. It acts as the backbone, providing electrical connections, heat dissipation, and mechanical support for LED components. Unlike traditional bulbs, LED PCBs ensure energy efficiency, longer lifespan, and compact designs.

LED Bulb PCB

What Are the Advantages of LED Bulb PCB?

  • High Energy Efficiency‌ – Optimizes power use for brighter light with lower energy consumption.
  • ‌Thermal Management‌ – Aluminum or ceramic substrates prevent overheating.
  • ‌Compact Design‌ – Fits seamlessly into slim LED bulb housings.
  • ‌Long Lifespan‌ – Robust materials ensure 50,000+ hours of operation.
  • ‌Customization‌ – Flexible layouts for unique lighting requirements.
LED Bulb PCB Board

LED Bulb PCB Board

Application of LED PCB Board

  • Household lighting-such as ceiling lamp, desk lamp.
  • Commercial lighting-High-brightness lighting in shopping malls, offices, and other scenarios.
  • Automotive lighting-Vehicle light sources such as headlights and brake lights.
  • Industrial equipment indicators-Device status indicator light, operation panel backlight
  • Smart lighting systems-Home/City Intelligent Lighting System.
LED Bulb PCB

Application of LED Bulb PCB

What Are the Types of LED PCB Board?

  • ‌Aluminum PCB‌ – Superior heat dissipation for high-power LEDs.
  • FR4 PCB-Suitable for Medium and low power LED bulbs.
  • ‌Flexible PCB‌ – Bendable designs for compact or curved fixtures.
  • ‌Ceramic PCB‌ – Extreme thermal stability for industrial us.
LED Bulb PCB

What Are the Types of LED Bulb PCB?

LED Bulb PCB Manufacturer

Choosing the right LED bulb PCB manufacturer is crucial for quality and performance. Best Technology, with over 18 years of experience, specializes in manufacturing high-quality LED PCBs, ensuring superior thermal management, durability, and precision in design. Our advanced production techniques guarantee reliable PCBs for various LED applications, making us a trusted partner for LED lighting solutions. Here are more information about us:

  • Adopt lead-free and halogen-free raw materials with PCB and obtain RoHS and UL certificates.
  • A professional team provides free technical support for circuit and brightness scheme adjustments, helping you save lots of material costs.  
  • Offer one-stop PCB solutions and PCBA service, we can help you purchase all the components you want to purchase.
  • Support rapid prototyping with low MOQ.

If you want to move your design into reality, Best technology will meet your all customized requirements.

What Are the Raw Materials of LED Bulb PCB Board?

Here are LED Bulb PCB raw materials:

  • FR4 epoxy resin substrate
  • Aluminum substrate
  • Ceramic substrate
  • Electrolytic copper foil
  • Gold/nickel plating
  • Prepreg (PP sheet)
  • Solder mask ink (green/white)
  • Fiberglass cloth (E-fiberglass)
  • Polyimide film(PI)
  • Solder (tin-lead/lead-free alloy)
  • Silk screen ink

How to Design LED Bulb PCB Board?

Here are main steps of LED bulb PCB design:

‌Step 1: Circuit Design

  • ‌Schematic Creation‌: Use KiCad or Altium Designer to draft the circuit. Include LEDs, resistors, driver ICs (e.g., LM2596S), and power input ports.
  • ‌Component Selection‌: Choose SMD or COB, resistor values for current limiting, and thermal vias for high-power LEDs.

‌Step 2: PCB Layout Design‌

Component Placement‌:

  • Arrange LEDs evenly for uniform illumination.
  • Position driver ICs and resistors close to LEDs to reduce trace length.

Thermal Design‌:

  • Use aluminum substrates or copper pours for heat dissipation.
  • Add thermal vias under LED pads.

‌Trace Routing‌:

  • Avoid sharp angles (use 45° bends) to minimize EMI.
  • Ensure trace width matches current requirements (e.g., 20–30 mils for 1A).

‌Step 3: PCB Fabrication

‌DIY Method‌:

  • Print circuit on glossy paper and transfer to copper-clad board via heat press.
  • Etch with ferric chloride, drill holes, and clean the board.

‌Professional Fabrication‌:

  • Submit Gerber files to manufacturers(such as Best Technology.)
  • Select substrate material (FR4 for low power, aluminum for high power).

‌Step 4: Component Assembly‌

  • ‌SMD Soldering‌: Apply solder paste, place components with tweezers, and reflow with a hot-air gun.
  • ‌Through-Hole Soldering‌: Manually solder connectors and large components.
  • ‌Post-Assembly‌: Clean flux residues and inspect for cold joints.

‌Step 5: ‌Electrical Checks‌&‌Operational Testing‌:

  • Use a multimeter to verify voltage/current at key nodes (e.g., LED terminals).
  • Test continuity to detect short circuits.
  • Power the circuit and check LED brightness uniformity.
  • Monitor temperature with an IR thermometer; ensure no overheating (>80°C).

If you want to do LED Bulb PCB prototype to verify your design, welcome to contact Best Technology.( The email is at the beginning of this blog.)

FAQ of LED Bulb PCB Board

1. What is the ideal thickness for an LED PCB?
The ideal thickness varies based on the design, but commonly ranges from 1.0mm to 1.6mm for standard LED applications.

2. How does thermal management affect LED PCB performance?
Efficient thermal management prevents overheating, extends the LED’s lifespan, and maintains consistent light output.

3. Can LED PCBs be waterproof?
Yes, LED PCBs can be coated with protective layers such as conformal coating or encapsulation to achieve waterproofing.

4. What is the difference between single-layer and multi-layer LED PCBs?
Single-layer PCBs are cost-effective and used for basic LED bulbs, while multi-layer PCBs allow for complex circuits and better heat dissipation in high-power applications.

5. How do I test an LED bulb PCB before mass production?
Testing methods include electrical continuity testing, thermal testing, and functional performance evaluation to ensure reliability.‌

In conclusion, through this blog, we can learn about meaning, advantages, types and design steps of LED Bulb PCB Board. If you have any other issues about LED bulb PCB board, welcome to leave a message below this blog. Looking forward to hearing from you!

Aluminum PCB for LED, Aluminum PCB For LED Light

March 20th, 2025

Are you looking for the best aluminum PCB for LED? Let’s Learn about its advantages, types , materials, design process and how to find a reliable PCB supplier.

At Best Technology, we focus on one stop aluminum PCB solution for LED, including aluminum LED PCB design, prototype and manufacturing. We have a stable supply chain and automated production lines that can achieve 72 hours fast delivery. And we have professional engineer teams who can provide you DFM analysis and free technical support to save production cost a lot. Feel free to contact us sales@bestpcbs.com if you have any request for aluminum LED PCB.

What is Aluminum PCB For LED?

Aluminum PCB for LED is a metal-based printed circuit board specifically designed for LED lighting. It achieves efficient heat dissipation by combining an aluminum substrate with insulating layers, ensuring the stable operation of high-power LED fixtures and extending their lifespan.

Aluminum PCB For LED Light

What Are the Advantages of Aluminum PCB For LED?

Here are main advantages of aluminum PCB for LED:

  • Efficient heat dissipation: quickly export the heat generated by the LED, reduce the operating temperature and extend the service life.
  • ‌High current carrying capacity: carry higher current than traditional PCB at the same thickness, suitable for high-power scenarios.
  • ‌Lightweight: lightweight aluminum material, simplifying installation and reducing the overall weight of the equipment.
  • ‌Process compatibility: adapt to SMT mounting technology to simplify mass production process
  • ‌High mechanical strength: impact and vibration resistance, adaptable to harsh working environments.
  • ‌Electromagnetic shielding: effectively reduce electromagnetic interference and improve circuit stability.
  • ‌High voltage resistance: support voltage above 3000V to ensure safe operation.
  • ‌Environmentally friendly and recyclable: aluminum material is non-toxic and recyclable, meeting environmental standards.
 Aluminum PCB For LED

Aluminum PCB For LED

Application of Aluminum PCB For LED

Here are application of aluminum PCB for LED:

  • LED bulbs-home and commercial lighting fixtures to prevent overheating and burning.
  • Automotive lighting-headlights, brake lights, fog lights, high temperature resistance and vibration resistance.
  • Advertising display screen-outdoor LED large screen, resistant to temperature changes and rain erosion.
  • Industrial lighting-factory high-brightness searchlights, 24-hour stable operation.
  • Medical equipment lights-surgical lights, detector light sources, fast heat dissipation to ensure safety.
  • Traffic lights-traffic lights, street lights, adapt to extreme weather.
  • Solar lights-garden lights, landscape lights, resistant to outdoor environment aging.
  • Stage lighting– high-power spotlights.
  • Household appliances– smart lamps, refrigerator backlight, thin and easy to install.

What Are the Types of Aluminum PCB For LED Light?

The aluminum PCB For LED light is divided into these types:

  • Fluorescent lamp aluminum substrate: used for fluorescent lamps and other lighting equipment.
  • ‌Street lamp aluminum substrate: used for street lamps and other outdoor lighting equipment.
  • ‌Downlight aluminum substrate: used for downlights and other embedded lighting equipment.
  • ‌Wall lamp aluminum substrate: used for wall lamps and other wall lighting equipment.
  • ‌Spotlight aluminum substrate: used for spotlights and other directional lighting equipment.
Aluminum PCB For LED Light

Aluminum PCB For LED Light

Aluminum PCB Board For LED Manufacturer

When uneven heat dissipation of LEDs causes accelerated light decay and a halved lifespan – what you lack is not just an aluminum substrate, but a full supply chain service from design to mass production! Best Technology as an aluminum PCB board for LED manufacturer over 18 years who can provide you one-stop PCB solutions from design, prototype and production. Here are some information about our company:

  • Made of high-quality aluminum raw materials, it has high thermal conductivity, fast heat dissipation, and extends the life of LEDs.
  • With a stable supply chain and automated production lines, it can quickly respond to customer needs and achieve fast delivery (samples can be delivered in 72 hours at the fastest)
  • Support DFM analysis, it can predict problems that may be encountered in the production process in advance during the design stage to reduce production costs a lot.
  • Support low MOQ diversified customization services to create exclusive customization
  • Provide free technical support, 24-hour professional engineer team will answer your questions online one-on-one.

If you’re interested in our services, welcome to leave a message below this blog.

What Are the Materials of Aluminum PCB Board For LED?

Here are the materials of aluminum PCB board for LED:

  • Substrate LayerAluminum(such as 6061 Aluminum alloy)
  • Insulation layerFR4 for normal thermal conductivity; ceramic powder mixture (such as alumina), silicone or special polymer for high thermal conductivity
  • Conductive layerCopper foil (1oz~6oz thickness), used for circuit routing.
  • Surface treatment layerOSP, HASL, silver/gold plating
  • Additional coatingWhite solder mask ink (high reflection), black solder mask (anti-light interference)
Aluminum PCB Board For LED

Aluminum PCB Board For LED

How to Design Aluminum PCB Board For LED?

Aluminum PCB for LED Design is mainly divided into five steps:

‌1. Basic design

  • ‌Select single/double-sided board‌: single-sided board (aluminum base + insulation layer + copper foil) for simple circuits, double-sided board for complex wiring.
  • ‌Aluminum base thickness‌: conventional 1.0~1.5mm, high power 2.0~3.0mm (such as 5052/6061 aluminum).

‌2. Circuit layout‌

  • ‌LED arrangement‌: evenly distributed, spacing ≄3mm (to prevent heat concentration).
  • ‌Line width calculation‌: Formula: Line width (mm) = current (A) / (copper thickness × 0.038).
  • ‌Wiring rules‌: Low voltage line spacing ≄ 0.2mm, high voltage (>50V) ≄ 1.0mm; Sharp angle routing is prohibited (arcs or 45° fold lines are preferred).

‌3. Pad design

  • ‌Size‌: 0.2~0.5mm larger than the LED pin (compatible with soldering process).
  • ‌Surface treatment‌: OSP is selected for general use, and immersion gold/silver plating is used for high reliability.

‌4. Thermal management

  • ‌Thermal conduction path‌: The aluminum base directly contacts the heat sink (insulating gasket is prohibited).
  • ‌Thermal resistance target‌: Total thermal resistance <5℃/W (high power requires <3℃/W).
  • ‌Verification method‌: Infrared thermal imager measures temperature rise (full load T<30℃).

‌5. Design output

  • ‌Gerber file‌: Insulation layer thickness, copper foil parameters, and Mark points are marked.
  • ‌DFM check‌: Line width error <±10%, pad and aluminum base edge >1mm.

FAQ of Aluminum PCB For LED

Q1: Why use aluminum PCB instead of FR4 for LED applications?
Aluminum PCBs offer superior heat dissipation, improving LED efficiency and longevity compared to FR4.

Q2: What is the typical thickness of an aluminum PCB for LED?
The standard thickness ranges from 1.0mm to 3.0mm, depending on application requirements.

Q3: Can aluminum PCBs be customized for different LED designs?
Yes, manufacturers like Best Technology provide custom solutions for various LED applications.

Q4: How does aluminum PCB improve LED lifespan?
Efficient heat dissipation reduces LED degradation, ensuring consistent performance over time.

Q5: What surface finishes are recommended for aluminum PCB?
ENIG, HASL, and OSP are common surface finishes, each offering different benefits in terms of durability and solderability.

In conclusion, that’s all about aluminum PCB for LED. If you want to learn more, welcome to leave a message below this blog. Looking forward to your message!

PCB Assembly Manufacturer, Quality-Focused PCBA Service

March 18th, 2025

PCB Assembly plays a crucial role in modern electronics, turning bare circuit boards into functional devices. Without proper assembly, even the most advanced PCB designs cannot perform as expected. Whether for consumer electronics, automotive applications, or aerospace systems, high-quality PCBA ensures reliability and performance. In this guide, we explore everything about PCB assembly, from types and materials to design considerations and industry applications. By the end, you’ll understand why Best Technology is the right partner for your PCB assembly needs.

At Best Technology, we specialize in precision-driven PCB assembly services, offering turnkey PCBA solutions, rigorous quality control, and advanced manufacturing capabilities to meet diverse industry needs. With over 18 years of experience, Best Technology provide cost-effective, high-accuracy printed circuit board assembly solutions tailored to your requirements. Feel free to contact us at sales@bestpcbs.com for any doubts or queries you might have.

PCB Assembly Manufacturer, Quality-Focused PCBA Service

What is a PCB Assembly?

PCB assembly (PCBA) is the process of placing and soldering electronic components onto a printed circuit board (PCB) to create a functional electronic device. The assembly process involves multiple steps, including surface-mount technology (SMT), through-hole technology (THT), soldering, and quality inspections. Unlike a bare PCB, a fully assembled PCB has all the necessary components installed, making it ready for integration into electronic systems.

What Are the Different Types of PCB Assembly?

1. Surface-Mount Technology (SMT) Assembly – The most common assembly method, SMT involves mounting components directly onto the surface of the PCB. It allows for smaller, more compact designs and is ideal for high-density applications.
2. Through-Hole Technology (THT) Assembly – THT involves inserting component leads into pre-drilled holes on the PCB and soldering them in place. It provides strong mechanical connections and is used in applications requiring durability.
3. Mixed Assembly – A combination of SMT and THT, mixed assembly is used when a design requires both surface-mounted and through-hole components.
4. Single-Sided & Double-Sided Assembly – Single-sided assembly involves placing components on one side of the PCB, while double-sided assembly places components on both sides, maximizing space and functionality.
5. Box Build Assembly – This type of assembly goes beyond the PCB level, including wire harnesses, enclosures, and full system integration.
6. Turnkey PCB Assembly – A complete service where the manufacturer handles everything from PCB fabrication to component sourcing, assembly, and testing, providing a ready-to-use product.
7. Prototype PCB Assembly – Used for product development and testing before full-scale production.

PCB Assembly Manufacturer

What Materials Are Used to Make PCB Assembly?

Several materials are used in PCB assembly to ensure reliability and performance:

  • PCB Substrate – The base material of the PCB, commonly made from FR4 (fiberglass epoxy), metal core, or ceramic for high-performance applications.
  • Copper Traces – Thin layers of copper form the conductive pathways for electrical signals.
  • Solder Mask – A protective layer applied over copper traces to prevent oxidation and short circuits.
  • Silkscreen Layer – Used for labeling component positions and reference markings.
  • Solder Paste – A mixture of flux and metal alloy used in SMT assembly to attach components before reflow soldering.
  • Electronic Components – Resistors, capacitors, ICs, diodes, and other essential parts that enable the PCB to function.
  • Solder Wire & Flux – Used in THT assembly to create strong electrical connections between components and the PCB.

How to Design PCB Assembly?

  • Component Placement – Arrange components efficiently to optimize space, signal integrity, and heat dissipation.
  • Layer Stack-Up – Define the number of PCB layers to meet electrical and mechanical requirements.
  • Trace Routing – Ensure proper trace width, spacing, and routing strategies to minimize signal interference.
  • Power & Ground Planes – Design stable power distribution and ground layers for noise reduction.
  • Thermal Management – Use thermal vias, heat sinks, and copper pours to manage heat dissipation.
  • DFM (Design for Manufacturability) – Optimize the PCB layout for efficient assembly, reducing potential defects and rework.
  • DFT (Design for Testing) – Include test points and accessibility for automated testing.
  • Bill of Materials (BOM) Creation – List all required components, their specifications, and sourcing details.
Quality-Focused PCBA Service

What Are the Benefits of PCB Assembly?

  • Compact Design – Enables smaller, lightweight devices with high functionality.
  • Cost-Effective Production – Automated assembly reduces labor costs and increases efficiency.
  • High Reliability – Advanced soldering techniques and quality checks ensure long-lasting performance.
  • Scalability – Suitable for both low-volume prototypes and high-volume manufacturing.
  • Customization – Supports specialized requirements, such as high-speed, high-frequency, or high-temperature applications.

What Are the Applications of PCB Assembly?

  • Consumer Electronics – Smartphones, tablets, laptops, and wearable devices.
  • Automotive – Engine control units, infotainment systems, and safety sensors.
  • Medical Devices – Patient monitoring systems, diagnostic tools, and imaging equipment.
  • Aerospace & Defense – Avionics, communication systems, and radar technology.
  • Industrial Automation – Robotics, control systems, and power electronics.
  • Telecommunications – Networking equipment, signal processing, and wireless communication devices.

Why Choose Best Technology as Your PCB Assembly Manufacturer?

  • Experience & Expertise – Over 18 years of experience in PCB manufacturing and PCB assembly. Best Technology is a leading PCB Assembly Manufacturer, providing manufacturing and sale service of various types of printed circuit boards and quality-focused PCBA Service.
  • Comprehensive Services – Full turnkey, partial turnkey, and consignment assembly options. We provide one-stop service, including PCB assembly and component purchasing and all-around technical support before and after-sales.
  • Quality Assurance – Stringent IPC and industry-standard testing, including AOI, X-ray, and functional testing. The pursuit of quality and innovation is the driving force of Best Technology. Every stage, from sourcing raw materials to production, inspection, packaging, and even sales and marketing, strictly follows ISO quality standards to ensure consistency and reliability.
  • Reliable Component Sourcing – Direct partnerships with trusted suppliers to prevent counterfeit parts. We procure all components exclusively from manufacturers or trusted distributors like Digikey, Mouser, Future, TTI, Avnet, and Arrow, ensuring authenticity.
  • State-of-the-Art Equipment – Advanced assembly machines ensure precision and efficiency. By leveraging cutting-edge technology and advanced PCB assembly equipment, we constantly refine our manufacturing processes, enhance testing and measurement techniques, and optimize our quality management system.
  • On-Time Delivery – Expedited services available for urgent orders. No matter where you are, we guarantee on-time delivery for every order.
  • Competitive Pricing – Cost-effective solutions without compromising quality.
  • Customer Support – Dedicated one-on-one sales assistance for a smooth collaboration. With exceptional team, Best Technology ensures prompt responses within 12 hours.

In conclusion, choosing the right PCB assembly manufacturer ensures product reliability, cost-effectiveness, and timely delivery. Best Technology offers expert solutions for various industries with a focus on quality and efficiency. Whether you need a simple prototype or a high-volume production run, our team is ready to support your project. Just feel free to reach out to us at sales@bestpcbs.com to discuss your PCB assembly needs!

 PCB Assembly Manufacturer

FAQs of PCB Assembly

1. What is the difference between PCB and PCB assembly?

  • A PCB (Printed Circuit Board) is the bare board with copper traces, while a PCB Assembly (PCBA) includes all the necessary electronic components soldered onto the board, making it a fully functional unit ready for use.

2. What is the purpose of a pick and place drawing in the SMT process?

  • A pick and place drawing provides detailed guidance for automated SMT machines, specifying component placement, orientation, and reference designators on the PCB. It ensures accurate positioning (including polarity indicators for diodes and capacitors) and facilitates post-assembly inspection.

3. What are counterbores and countersinks?

  • Counterbore: A cylindrical recess with a flat bottom, designed to allow a screw head to sit flush with the PCB surface. Commonly used with flat-head screws to ensure secure mounting, such as for attaching heatsinks or connectors.
  • Countersink: A conical recess that matches the angle of a tapered screw head, such as self-tapping screws. Helps create a smooth, low-profile surface, often used when securing PCBs within enclosures.

The key difference is that counterbore provides a level surface by embedding the screw head within the material. Countersink features a tapered design that aligns the screw and evenly distributes stress.

4. How to distinguish the PTH & NPTH?

  • PTH is PLATING Through Hole, it has copper in the holes inside, which can be conductive.  NPTH is Non PLATING Through Hole, which don’t have copper inside the holes. Through holes means through the top and bottom on the PCB, it could be PTH and NPTH.

Dipole Antenna PCB Design, Dipole Antenna PCB Manufacturer

March 18th, 2025

As one of the most widely used antenna designs, a dipole PCB antenna plays a critical role in radio transmission, IoT devices, and RF applications. Whether it is used in Wi-Fi routers, mobile networks, or radar systems, the dipole antenna PCB ensures stable and reliable signal transmission.

What is a Dipole Antenna PCB?

A dipole antenna PCB is a printed circuit board-based antenna designed with two conductive elements that serve as radiating arms. The word “dipole” means “two poles,” which describes the two symmetrical elements that make up the antenna. The length of these elements is typically half the wavelength of the frequency it operates on, which is why it is often called a half-wave dipole antenna.

This type of antenna is widely used in RF applications due to its simple construction, ease of manufacturing, and effective radiation properties. A dipole antenna PCB is commonly found in wireless communication systems, radio transmitters, satellite communication, and IoT devices. The radiation pattern of a dipole antenna is omnidirectional, making it ideal for applications that require uniform signal coverage.

Dipole Antenna PCB Design, Dipole Antenna PCB Manufacturer

Dipole PCB Antenna Design

Same as others antenna PCBs, designing a dipole PCB antenna requires careful consideration of factors such as frequency, impedance, substrate material, and radiation efficiency. The key aspects of designing a dipole PCB antenna include:

1. Determining the Antenna Length

The total length of a half-wave dipole antenna is calculated using the formula:

Where:

  • L = Length of the dipole antenna
  • λ = Wavelength of the signal
  • c = Speed of light (3 × 10^8 m/s)
  • f = Operating frequency

For example, for a 2.4 GHz Wi-Fi application, the length of a half-wave dipole antenna would be approximately 62.5 mm.

2. Choosing the Substrate Material

The choice of PCB substrate material affects the antenna’s efficiency and performance. The most common substrates used in dipole antenna PCB design include:

  • FR-4: Low-cost but has higher dielectric loss, suitable for general applications.
  • Rogers RO4000 Series: Low-loss, high-performance material for RF applications.
  • PTFE (Teflon): Ideal for high-frequency applications due to its low dielectric constant.

3. Impedance Matching

A standard dipole antenna has an impedance of 73 ohms in free space. To maximize power transfer, the impedance of the antenna must be matched with the feedline and transmitter, typically using a 50-ohm transmission line. This can be achieved through matching networks or baluns (balanced-to-unbalanced transformers).

4. Feed Mechanism

  • A dipole PCB antenna can be fed using:
  • Coaxial Feed: A direct connection to a 50-ohm coaxial cable.
  • Microstrip Feed: Uses a microstrip transmission line on the PCB for integration with circuits.
  • Balun Feed: Improves performance by converting an unbalanced signal into a balanced one.

Working Principle of Dipole Antenna PCB

A dipole antenna PCB operates based on the principle of electromagnetic radiation. It typically consists of two symmetrical conductive elements, arranged in a straight or semicircular configuration, which function as the transmitting and receiving elements. These two conductor arms are fed at the center, forming a half-wavelength antenna. The current distribution on the dipole antenna resembles that of an open transmission line, with current nodes appearing at both ends.

When an alternating current (AC) signal is applied at the feed point, the current oscillates along the dipole arms, generating an electric field. This interaction with the surrounding environment results in the propagation of electromagnetic waves. The efficiency of radiation depends on the length and shape of the conductors. Typically, a dipole antenna is designed with a length of 1/2 or 1/4 of the wavelength of the intended signal to maximize radiation performance. The working process shows as below:

Working Principle of Dipole Antenna PCB

In PCB design, placing a ground layer beneath the antenna can create a mirror effect, enhancing its performance. Additionally, careful PCB layout adjustments and ground layer configurations can optimize the antenna’s radiation efficiency and directivity, improving overall signal strength and stability.

Dipole Antenna PCB Advantages

  • Simple structure and easy to manufacture: The dipole antenna consists of two conductors of equal length, with a simple structure, easy to manufacture and maintain, and low cost.
  • Omnidirectional radiation: Dipole antenna can form a strong radiation field in two opposite directions, with omnidirectional radiation characteristics, suitable for applications that require uniform coverage of the surrounding environment, such as Wi-Fi hotspots or mobile base stations.
  • Standard impedance matching: It can easily achieve standard impedance matching of 50Ω or 75Ω, simplifying the connection with other RF components.
  • Good radiation pattern: The radiation pattern of the dipole antenna is relatively uniform in the horizontal direction and symmetrical in the vertical direction, which is suitable for some communication systems that require balanced feeding.
  • Higher gain: The gain of the dipole antenna is generally higher than that of the monopole antenna, especially in the vertical direction, which is more symmetrical and can provide a more uniform radiation field.
  • Wide Frequency Range: Can be optimized for different frequency bands.
  • Scalability: Can be designed for small devices like IoT sensors or large-scale communication systems.

Dipole Antenna Radiation Pattern

The radiation pattern of a dipole antenna is typically omnidirectional in the H-plane (horizontal plane), meaning it radiates energy uniformly in all directions. However, in the E-plane (vertical plane), it exhibits a figure-eight pattern, with maximum radiation perpendicular to the dipole elements. It always shows as below:

Dipole Antenna Radiation Pattern

This characteristic makes dipole antennas ideal for applications requiring uniform signal distribution around the antenna’s axis.

Types of Dipole Antennas

1. Half-Wave Dipole Antenna: The most common type, where the total length is half the wavelength.

2. Folded Dipole Antenna: Features an additional conductor for higher bandwidth and impedance matching.

3. Short Dipole Antenna: Uses a shorter length but requires additional tuning for better efficiency.

4. Multi-Band Dipole Antenna: Designed for multiple frequency bands, useful in telecommunications and radar applications.

Applications of Dipole PCB Antenna

  • Wireless Communication: Wi-Fi, Bluetooth, and RFID systems.
  • IoT Devices: Smart home automation, industrial sensors, and medical wearables.
  • Broadcasting: AM/FM radio and television transmission.
  • Aerospace and Defense: Satellite communication, radar systems, and UAVs.
  • Automotive: Vehicle-to-vehicle (V2V) and vehicle-to-infrastructure (V2I) communication.

Best Dipole Antenna PCB Manufacturer

Choosing the right dipole antenna PCB manufacturer is crucial for achieving optimal performance. Best Technology has over 18 years of experience in manufacturing high-frequency RF PCB and microwave PCBs, specializing in custom dipole PCB antennas for wireless communication and IoT applications. We can provide:

  • High-Precision Manufacturing: Advanced fabrication techniques ensure accurate antenna designs.
  • Premium RF Materials: Uses high-performance PCB materials like Rogers and PTFE.
  • Customization Options: Designs tailored to your specific frequency and impedance requirements.
  • Reliable Performance: Ensures consistent signal transmission with high efficiency.
  • Global Shipping: Trusted by clients worldwide for RF PCB solutions.

For custom dipole PCB antenna solutions, contact Best Technology today to get a free consultation!

RGB LED PCB Design, Prototype&RGB LED PCB Manufacturer

March 18th, 2025

RGB LED PCB is an important part in modern lightening system, It can be seen everywhere in our lives, such as the breathing light strips of smart homes, dynamic special effects of stage lighting and so on. Would you like to get more information about RGB LED PCB? In this blog, let’s explore information about feature overview of RGB LED PCB , and how to design, how to select a PCB supplier together.

Best technology specialize in high quality RGB LED PCB design, prototype and manufacturing over 18 years. We provide one-stop PCB solutions services from signal integrity optimization, thermal management simulation to dynamic heat dissipation of aluminum substrates. And we support PWM precise dimming protocol, integrated EMC protection and impedance matching design. It can ensure 24-bit color restoration accuracy. We can meet the strict demands of stage lighting, architectural lighting, and smart home fields for full-color LED PCBs, helping you seamlessly transition from optical design to mass production. If you’re interested in our service, welcome to contact us at sales@bestpcbs.com.

What Is RGB LED PCB?

RGB LED PCB is a type of printed circuit board (PCB) that integrates Red, Green, and Blue LEDs. It achieves a wide variety of color effects by mixing the light of these three colors (the primary colors of light) and is commonly used in lighting, decoration, and display devices.

RGB LED PCB

What Are the Advantages of RGB LED PCB Board?

  • Excellent heat dissipation performance– Adopting aluminum substrate design and suitable for high-power RGB LED applications
  • ‌Precise color control and diversity-supports dynamic gradient and breathing light and can mix a million of colors.
  • ‌High integration and design flexibility-‌ integrate multiple RGB LEDs, driver chips and control circuits and support modular design
  • ‌Energy saving and environmental protection– 80% energy saving compared to traditional light sources‌ and adopt recyclable aluminum substrate and LED does not contain harmful mercury.
  • ‌High reliability and stability-‌resistant to high temperature, moisture and impact, and can adapt to complex environments (such as outdoor display screens and industrial equipment).
  • ‌Fast response and dynamic performance-‌ LED response speed reaches nanoseconds, and with high-speed PCB signal transmission, smooth dynamic effects (such as game lighting synchronization) can be achieved.
  • ‌Wide application scenarios-‌ decorative lighting (ambient lighting, advertising screens), electronic equipment (keyboard backlight), industrial indication and so on.
rgb led light pcb

Advantages of RGB LED PCB Board

What Is the Use of LED RGB PCB board?

  • Decorative lighting– Ambient lighting, holiday decorative lights, dynamic color gradient, breathing lights, music-synchronized lighting effects.
  • ‌Electronic equipment-‌ Keyboard backlight, computer case lighting effects, status indication of  mobile phones/headphones, personalized lighting feedback of mouse, monitor.
  • ‌Display and advertising– ‌LED large screen(stage, shopping mall, stadium), full-color dynamic display of billboards and signboards.
  • ‌Industrial and signal indication -‌ Equipment status indicator (operation/fault/warning) and multi-color prompts for traffic signals and security systems.
  • ‌Smart home -ceiling lights, table lamps with adjustable color temperature/color.
  • ‌Art and entertainment– ‌Stage lighting, art installations, interactive light shows, background light adjustment for movies/studios.
  • ‌Automotive lighting-‌ Interior atmosphere lights, chassis lights.
LED RGB PCB board

What Is the Use of LED RGB PCB board?

RGB LED PCB Manufacturers

Selecting the right RGB LED PCB manufacturer ensures high-quality PCBs for efficient LED performance. Reputable manufacturers provide design support, high-precision manufacturing, and customized solutions. Best Technology, a leading PCB manufacturer, offers expert engineering services and high-quality RGB LED PCBs tailored to specific applications. Here are more information about our company:

  • Technology leadership-Utilizes aluminum-based board with high-precision Surface Mounted Technology(SMT) , supporting monochrome/full-color RGB solutions.
  • One stop PCB solution: provide a wide range of RGB LED PCBs (including RGB LED strip PCB ) and matching electronic components, such as RGB LED driver PCB and RGB LED controller PCB.
  • Customized Solutions-Provide customized service( including custom logo) with low MOQ( one piece)
  • Quick Respond to Customers-Professional team online 24 hours, providing full process tracking from scheme design to prototyping and mass production.
  • Fast Delivery-Have a electronic manufacturing supply chain, providing one-stop solutions and PCBA services.

What Are the Materials of RGB LED light PCB?

  • Aluminum substrate– Suitable for high-power RGB LED scenarios (outdoor displays, wall washers).
  • FR4 board – Suitable for low-cost, low-power solutions (advertising light boxes, indoor decorative lights).
  • Flexible substrate (PI base material) : Suitable for bendable scenarios (LED strip lights, curved decorations).
  • Copper substrate– Suitable for high-power precision equipment (industrial equipment, high current modules).
  • Double-sided fully fiberglass PCB board-Suitable for high stability scenarios (commercial lighting, moisture resistance requirements).
rgb led strip pcb

Materials of RGB LED light PCB

How To Design RGB LED PCB?

1. Select LED and drive solution ‌

‌LED model‌: Prioritize models with integrated driver IC (such as WS2812B) to reduce peripheral circuits.

Diver Mode: Low power suitable for Direct MCU PWM drive (such as Arduino). High power suitable for Constant current driver chip (such as TLC5940) or MOSFET+resistor.

‌Interface type‌: Determine common anode or common cathode, and unify circuit logic.

‌2. Circuit schematic design ‌

‌Power input‌: Indicate voltage (5V/12V/24V) and maximum current.

Series control: short signal line + data flow direction mark (such as DIN→DOUT of WS2812B).

Parallel control: independent PWM signal line grouping.

‌Filter design‌: Add capacitor (10ÎŒF~100ÎŒF) to the power supply end, and add RC filter (100Ω+100pF) to the signal line.

‌3. PCB layout planning‌

‌LED arrangement‌: uniform spacing (avoid light spots), high-power LED spacing ≄10mm. Close to the edge of the PCB (reduce heat impact on sensitive components).

‌Component partitioning‌: the power module is away from the signal line. The MCU/driver chip is centrally arranged to shorten the signal path.

‌4. Power and ground wiring‌

‌Power line‌: line width ≄1mm/1A current, avoid right-angle routing.

‌Ground copper laying‌: full board laying to reduce noise and impedance.

‌Single-point grounding‌: digital ground, analog ground, and power ground are connected through 0Ω resistors or magnetic beads.

‌5. Signal line optimization‌

‌Signal priority‌: high-frequency signals (such as PWM) are given priority to short and straight routing.

Avoid parallel long-distance power lines (anti-interference).

‌Impedance control‌: add termination resistors (22~100Ω) when necessary.

‌6. Add test and debug interface‌

‌Power test point‌: VCC and GND reserved pads or through holes.

‌Signal test point‌: Key PWM signal lines are led out to the pin header.

‌Reserve jumper next to LED‌: Convenient for disconnection detection in case of fault.

‌7. Silkscreen and marking‌

‌Polarity mark‌: All LEDs are marked with “+” or “-” poles.

‌Interface marking‌: Clearly define the position of power, signal, and ground wires (such as “VIN”, “DIN”, “GND”).

‌Version number‌: The version is marked in the corner of the PCB (such as V1.0).

‌8. DRC rule check‌

‌Line width/spacing‌: Comply with PCB factory process (for example: minimum line width 0.2mm, spacing 0.15mm).

‌Short circuit/open circuit‌: EDA tool automatically checks (such as KiCad, EasyEDA).

‌Heat dissipation verification‌: Ensure that there are no dense traces in high-power areas.

‌9. Prototyping and test verification

‌After you made a RGB LED PCB prototype, you can do some functional and heat tests with it.

‌Color switching: Check whether the RGB mixing is normal.

Brightness consistency: Measure the voltage/current of each LED.

‌Heat test‌: Run continuously for 1 hour in a high-power scenario and measure the temperature rise (recommended ≀60℃)

FAQs of RGB LED PCB

  • What is the lifespan of an RGB LED PCB?
    RGB LED PCBs can last over 50,000 hours, depending on heat management and component quality.
  • Can RGB LED PCB be customized?
    Yes, RGB LED PCBs can be customized in terms of size, shape, and control features based on application needs.
  • What is the difference between RGB LED FR4 PCB and RGB LED aluminum PCB?
    RGB LED aluminum PCB offer better heat dissipation, while RGB LED FR4 PCB are more cost-effective and suitable for low-power LEDs.
  • How do I control the colors in an RGB LED PCB?
    Colors are controlled using PWM (Pulse Width Modulation) technology via an LED driver or microcontroller.
  • Where can I buy high-quality RGB LED PCBs?
    Best Technology provides high-quality RGB LED PCBs with expert design and manufacturing services.

In conclusion, that’s all about RGB LED PCB. If you want to know more about RGB LED PCB design, prototype and production, please feel free to contact Best Technology.(The email is at the beginning of this blog). Looking forward to hearing from you soon!

Special PCB Design, Prototype, Special PCB Manufacturer

March 18th, 2025

Special PCB is a customized circuit board designed for unique applications where standard PCBs do not meet the required performance, durability, or environmental conditions. These PCBs are used in industries such as aerospace, medical, telecommunications, and automotive, where factors like heat dissipation, high frequency, and miniaturization are crucial. Whether it’s a high-speed PCB, HDI PCB, or heavy copper PCB, each type serves a specific purpose to enhance electronic performance.

Best Technology excel in providing customer-centric support in PCB industry. The team offers special PCB design optimization, material selection guidance, and manufacturing feasibility analysis to the customers. Whether you need a special PCB prototype or full-scale special PCB manufacturing, just feel free to reach out to us at sales@bestpcbs.com, we work closely with you to meet your exact specifications.

Special PCB Design, Prototype, Assembly, Special PCB Manufacturer

What is Special PCB?

A special PCB is a customized printed circuit board that differs from standard PCBs in design, materials, or functionality. It is engineered to meet specific requirements such as high power handling, extreme temperatures, or unique form factors. These boards ensure stability, reliability, and efficiency in demanding applications.

What Are the Different Types of Special PCBs?

Special PCBs can be classified into three main categories based on their materials, functionality, and structure.

1) Material-Based Special PCBs

These PCBs are defined by the materials used to enhance their performance under specific conditions.

Heavy Copper PCB – Uses thick copper layers (≄3 oz) for high current applications and improved thermal management.

Special PCB Design

High Tg PCB – Made with high glass transition temperature (Tg) materials to withstand extreme heat and mechanical stress.

2) Function-Based Special PCBs

This category includes PCBs designed for specific electrical or performance characteristics.

High-Speed PCB – Designed with low-loss materials and controlled impedance for fast signal transmission in networking and computing.

Impedance Control PCB – Maintains precise impedance levels for RF, microwave, and high-frequency circuits.

RF Board – Uses low-loss materials to minimize signal interference in wireless communication, radar, and satellite applications.

Bus Bar PCB – Incorporates embedded copper bars for high current carrying capacity in power distribution systems.

3) Structure-Based Special PCBs

These PCBs are categorized based on their physical design and layout innovations.

HDI PCB – Features microvias, fine traces, and multiple layers for compact, high-density applications like smartphones and laptops.

Extra Thin PCB – Ultra-thin boards designed for compact and flexible electronic devices.

Special PCB Prototype

IC Substrate – Specialized interconnects used to bridge semiconductor chips with larger PCB assemblies.

What Materials Are Used to Make Special PCBs?

The choice of materials in special PCBs determines their electrical performance, heat resistance, and mechanical durability. Here are the key materials used:

1) FR-4

A fiberglass-reinforced epoxy laminate that offers a balance of cost, durability, and electrical insulation. It is commonly used in High Tg PCBs, HDI PCBs, and Impedance Control PCBs where thermal resistance and signal integrity are crucial.

2) High-Tg FR-4

An advanced version of FR-4 with a higher glass transition temperature (Tg), making it suitable for High Tg PCBs and High-Speed PCBs that operate under extreme thermal conditions.

Special PCB Assembly

3) Polyimide

This material provides exceptional thermal stability and flexibility. It is widely used in Extra Thin PCBs and HDI PCBs, where space-saving and durability under heat are essential.

4) PTFE (Teflon)

A low-loss, high-frequency material that is ideal for RF Boards and High-Speed PCBs. Its excellent dielectric properties help maintain signal integrity in wireless and microwave applications.

5) Copper

  • Heavy Copper PCB – Uses thick copper layers (≄3 oz) to support high current loads and enhance heat dissipation.
  • Bus Bar PCB – Features embedded copper bars for efficient power distribution in industrial and automotive applications.

6) BT (Bismaleimide Triazine) Epoxy Resin

This material is used in IC Substrates for its excellent electrical insulation, high-temperature resistance, and mechanical strength. It ensures reliable connections in semiconductor packaging.

7) Low-Dk (Low Dielectric Constant) and Low-Df (Low Dissipation Factor) Materials

These are specialized dielectric materials used in Impedance Control PCBs and High-Speed PCBs to reduce signal loss and maintain consistent impedance for high-frequency applications.

How to Design a Special PCB?

1) Define Requirements

Start by determining the electrical, thermal, and mechanical specifications needed for the application.

2) Select Materials

Choose the right substrate, copper thickness, and surface finish based on operating conditions and performance needs.

3) Create a Schematic

Develop a circuit diagram to define component placement and electrical connections.

4) Layout Design

Optimize routing, layer stack-up, and impedance matching to ensure signal integrity and manufacturability.

5) Prototyping & Testing

Before mass production, test a prototype to validate functionality, thermal management, and reliability.

What Are the Benefits of a Special PCB?

1) High Performance

Custom designs ensure superior electrical and thermal efficiency.

2) Enhanced Durability

Robust materials and specialized coatings increase lifespan, even in harsh environments.

3) Miniaturization

Advanced designs, such as HDI and extra thin PCBs, enable compact, lightweight devices.

4) Reduced Signal Loss

Impedance control and RF materials enhance signal integrity, crucial for high-speed and wireless applications.

What Are the Applications of Special PCBs?

1) Aerospace & Defense

Used in satellite systems, avionics, and military-grade electronics that require reliability under extreme conditions.

2) Automotive Electronics

Essential for EV power systems, engine control units, and ADAS (Advanced Driver Assistance Systems).

3) Medical Devices

Supports high-precision diagnostic equipment, wearable health monitors, and implantable devices.

4) Telecommunications

Used in 5G infrastructure, networking hardware, and high-speed data transmission systems.

Special PCB Manufacturer

Why Choose Best Technology as Your Special PCB Manufacturer?

1) Industry Expertise

With 18 years of experience, Best Technology specializes in manufacturing high-quality special PCBs tailored to unique requirements.

2) Multi-Variety PCB Manufacturing

Electronics manufacturers often require diverse PCB types within a single project. Best Technology offers a wide range of special PCBs, including Heavy Copper, Bus Bar, High-Speed, IC Substrate, Impedance Control, Extra Thin, High Tg, HDI, and RF Boards. Our ability to handle multiple PCB types under one roof simplifies the supply chain, reduces lead times, and ensures consistency across different PCB designs.

3) High Quality

Each special PCB undergoes rigorous testing to meet international quality and reliability standards.

4) Custom Solutions

As a leading special PCB manufacturer, we offer complete customization based on your project needs from special PCB design to special PCB assembly. Not only provide top quality requirements of Special Printed circuit Board and PCBA service for the market but also meet customer special customized requests.

Small-Batch Production

At Best Technology, we specialize in low-volume special PCB manufacturing, ensuring that even small orders receive the same level of precision and quality as mass production. This allows customers to test new designs, reduce risks, and accelerate product development.

FAQs Of Special PCB

1. What is the maximum operating temperature for PCBs?
Typically, the working temperature for standard PCB materials is 105-130°C. For high-temperature materials, such as those made with 7316D, the working temperature can reach 150-170°C. However, this material requires a higher MOQ.
2. Is the smallest copper trace width you can do 4mil?
Yes.
3. What PCB material brands do you use?
We use brands like Shengyi, KB, ITTEQ, GDM, and etc.
4. What is the maximum board size you can produce?
The maximum size we can produce is 610mm x 610mm.
5. What is the maximum copper thickness for a PCB?
We can produce a maximum copper thickness of 30oz (1050um).

In conclusion, special PCBs are essential for high-performance, reliable, and efficient electronic applications. Whether you need heavy copper PCBs for power applications or HDI boards for miniaturized devices, selecting the right manufacturer is crucial. Best Technology provides industry-leading expertise, top-notch quality, and tailored solutions to ensure your project’s success. Pls feel free to contact us at sales@bestpcbs.com to get started on your special PCB requirements!

SMD LED PCB Board Design,Prototype&SMD LED PCB Manufacturer

March 18th, 2025

SMD LED PCB board design is very important in electronic products industry. From precise pad layout to efficient heat dissipation solutions, every detail is related to light efficiency and life. Whether it is rapid iteration in the prototype verification stage or cost optimization in the mass production stage, professional design needs to integrate electrical performance and process compatibility. In this blog, let’s learn together how to design SMD LED PCB boards and how to choose a good SMD LED PCB manufacturer.

If you want to move design to prototype and manufacture, Best technology can meet your all requirements for SMD LED PCB Board. Because we specializing in SMD LED PCB Board design, prototyping and production over 18 years, and we have an experienced PCB designers team who can give you free technical support. And we can provide you PI Analysis, SI Analysis, EMC Testing with the SMD LED PCB you designed. Then we can provide you with customized services (including customized Logo) with low MOQ (one piece is okay) at reasonable prices. You can feel free to contact us sales@bestpcbs.com if you have any request for SMD LED PCB.

What Is SMD LED PCB Board Design?

SMD LED PCB board design refers to the process of designing printed circuit boards that support Surface Mount Device (SMD) LEDs. These boards are commonly used in lighting applications, display panels, and electronic signage. Unlike through-hole LEDs, SMD LEDs are mounted directly onto the PCB surface, enhancing efficiency and reducing assembly costs.

SMD LED PCB Design Software 

Here are common SMD LED PCB design software:

  • ‌Altium Designer-Offers comprehensive PCB design tools with 3D visualization.
  • KiCad: A free, open-source option for designing SMD LED PCBs.
  • EAGLE: User friendly and widely used in hobbyist and professional projects.
  • Cadence Allegro: Suitable for High-speed signal design field

SMD LED PCB Design Layout

The design layout of SMD LED PCBs mainly includes the following aspects:

  • Heat dissipation priority‌: copper is laid in the concentrated area of ​​LED for heat dissipation, away from high-temperature components to avoid heat accumulation.
  • ‌Wire optimization‌: the power line is short and wide to reduce impedance; the signal line and the power line are layered or spaced to prevent interference.
  • ‌Uniform arrangement‌: the LED spacing is consistent, avoiding obstructions to ensure that the light-emitting surface faces the same direction.
  • ‌Pad matching‌: the pad is designed according to the package size to avoid cold soldering; sufficient soldering spacing is reserved.
  • ‌Polarity identification‌: clearly mark the positive and negative poles of the LED to avoid reverse patch; leave debugging marks on the board.

SMD LED PCB Design Layout

SMD LED Circuit Board Diagram

Here is an example of SMD LED Circuit Board Diagram for reference:

This picture is only for reference, please refer to the actual SMD LED Circuit board design diagram. If you need support on this aspect, please contact us.( the email is at the beginning of this blog)

SMD LED PCB Board Manufacturer

When you have finished the design and want to find a SMD LED PCB Board Manufacturer to verify your design. At Best Technology, we can provide affordable prototyping cost with fast delivery, Here are more information about us:

  • Focus on SMD LED PCB Board design, prototype and manufacturing over 18 years and have an experienced designers team. We can provide you professional and free technical support quickly.
  • Have a complete electronic manufacturing supply chain, providing one-stop solutions and PCBA services. All components you needed we can help you purchase and assemble with PCB.
  • Strong process capability

Here is a chart of our process capabilities:

Base materialAluminum/Copper/Iron Alloy
Thermal Conductivity  0.8, 1.0, 1.5, 2.0, 3.0 W/m.K.
Board Thickness0.5mm~3.0mm(0.02″~0.12″)
Copper thickness:0.5 OZ, 1.0 OZ, 2.0 OZ, 3.0 OZ, up to 10 OZ
Outline:Routing, punching, V-Cut
Solder mask:White/Black/Blue/Green/Red Oil
Legend/Silkscreen Color:Black/White
Surface finishing:Immersion Gold, HASL, OSP
Max Panel size: 600*500mm(23.62″*19.68″)
Packing:Vacuum/Plastic bag
Samples L/T:4~6 Days
MP L/T:5~7 Days

How To Design SMD LED PCB Board?

1. Parameter confirmation and selection ‌

  • Single LED operating voltage (such as 3V), current (20mA) and maximum power consumption (power = voltage × current).
  • Series/parallel configuration: series voltage superposition (total voltage = single voltage × quantity), parallel connection requires current equalization design.
  • Materials For general scenario‌: FR4 board (cost-effective, temperature resistance 130℃).
  • Materials For high power scenario‌: Aluminum substrate (thermal conductivity ≄2.0W/m·K, temperature resistance 150℃).

‌2. Layout design‌

  • ‌Similar LED spacing‌ rule: ≄0.3mm (to prevent solder bridging).
  • ‌Dissimilar device spacing‌ rule: calculated according to the formula ‌0.13×height difference (mm)+0.3mm‌ (such as LED height 1mm, resistor height 0.5mm, spacing = 0.13×0.5+0.3≈0.365mm).
  • All LEDs have the same long axis direction and are perpendicular to the reflow soldering direction (to prevent hot air from causing deviation).
  • The distance between the component and the edge of the PCB is ≄3mm. If it cannot be avoided.
  • V-Cut board division‌: Cut after extending the board edge, and wiring is prohibited at the cut.
  • ‌Stamp hole board division‌: Separated by a 0.8mm diameter hole array, the hole center is ≄1.5mm from the board edge

‌3. Routing and power design‌

  • ‌Line width calculation‌: Under 1oz copper thickness, line width (mil) = current (A) Ă· 0.024 (such as 1A current requires ≄42mil).
  • ‌Copper plating stiffener: The LED negative pad is connected to a large area of ​​copper plating (to reduce impedance and assist heat dissipation).
  • Filter capacitor layout‌: Each LED is connected in parallel with a 0.1ÎŒF ceramic capacitor (mounting distance ≀5mm).
  • Add 10ÎŒF~100ÎŒF electrolytic capacitors to the power inlet (to suppress low-frequency ripple).
  • ‌Ground plane division‌: Single-point connection between digital ground and power ground to avoid noise coupling.

‌4. Thermal management design‌

  • Heat dissipation hole array‌: 0.3~0.5mm diameter through holes (1~2mm spacing) are drilled directly below the high-power LED, and the inner wall of the hole is metallized (to enhance thermal conductivity).
  • Copper foil area expansion‌: The copper area under the LED is ≄ 3 times the pad area (the aluminum substrate can be omitted).
  • The distance between LED and heating components such as driver IC and MOS tube is ≄ 5mm.
  • Avoid arranging electrolytic capacitors in high-temperature areas.

‌5. Design for manufacturability (DFM)‌

  • ‌Pad design‌: The pad size is 0.2mm larger than the LED pin (e.g. LED pin is 1.6×0.8mm, and the pad design is 1.8×1.0mm).
  • The solder mask opening is 0.05~0.1mm wider than the pad (to prevent the solder mask from covering the pad).
  • Polarity mark‌: Add a “+” symbol or silk screen frame next to the LED pad (to prevent reverse connection).
  • Mark point: a solid copper point with a diameter of 1mm is arranged diagonally, and there is no component within 3mm around it. ‌

‌6. Test and debugging reservation‌

  • Reserve a 30mil diameter circular test point for each LED string circuit (connect to the positive pole of the power supply, ground and dimming signal).
  • The test point spacing is ≄2mm to avoid probe short circuit.
  • Reserve ≄1.5mm channels in dense LED arrays to facilitate hot air gun rework.

7. Design verification and simulation‌

  • ‌Thermal simulation‌: Use ANSYS Icepak or similar tools to verify the high temperature area (the temperature rise of the aluminum substrate should be ≀30℃).
  • ‌Power integrity simulation‌: Check the power ripple through Sigrity or HyperLynx (target ≀5% rated voltage).
  • ‌DRC inspection‌: Focus on checking line spacing (≄0.2mm), aperture (≄0.3mm), and pad and through-hole avoidance (≄0.15mm).

‌8. Production file output‌

  • ‌Gerber file‌: Contains circuit layer, solder mask layer, silk screen layer, and drilling file (aperture tolerance ±0.05mm).
  • Process marking‌: Clearly specify the solder mask color (white is preferred), surface treatment (immersion gold/OSP), and whether the aluminum substrate needs an insulation layer.

Lastly, you can move the production file to the make a SMD LED PCB board prototype.

What Are SMD LED PCB Board Design Rules?

  • Minimum spacing rule: When SMD layout is in progress, ensuring a certain spacing between components can reduce the probability of problems such as cold soldering, bridging, and shadow effects during welding.
  • PCB edge requirements: SMD components should not be laid out within 3mm from the two sides of the SMD PCB. This is because the guide groove of the placement machine requires that no components are allowed within 3 to 5mm of the PCB board edge. If this size cannot be guaranteed, consider using V-grooves or stamp holes to lengthen the board, and then remove the excess board after welding.
  • Arrangement direction: The arrangement direction of the same components should be as consistent as possible, and a test point with a diameter of 30mil must be left on the same gold track. In addition, the arrangement direction of CHIP, SOT, and SOIC components should be perpendicular to the tinning direction as much as possible to avoid shadow effects.
  • Shadow effect: When wave soldering is used, components with large height differences should not be arranged close together to prevent the shadow effect of high components from affecting the soldering of low components.
  • Test point requirements: When a right-angle (vertical) arrangement is required, sufficient tinning space must be reserved. The distance of this space should be 0.635mm.
What Are SMD LED PCB Board Design Rules?

SMD LED PCB Board Design Rules

FAQ of SMD LED PCB Board Design

1. ‌Improper pad design leads to welding defects‌

  • Use “water drop” routing transition to avoid right-angle connection of pads.
  • Symmetrically design the pad size to ensure balanced heat capacity on both sides.

2. ‌Insufficient heat dissipation leads to shortened LED life‌

  • Lay a sufficient area of heat dissipation copper foil (≄50mmÂČ/W) under the LED and add heat dissipation through holes.
  • Aluminum substrate or metal core PCB is preferred for high-power scenarios.

3. ‌Uneven current distribution of parallel LEDs‌

  • Use star topology wiring to ensure that the length and impedance of each parallel branch are consistent.
  • Use constant current driver chip instead of traditional resistor current limiting solution.

4. ‌Process problems caused by overly dense component layout‌

  • Ensure that the LED spacing is ≄0.5mm and is more than 3mm away from the board edge.
  • During wave soldering, adjust the LED arrangement direction perpendicular to the tinning direction, and use a stepped steel mesh to control the amount of solder paste.

5. ‌Polarity marking error or silk screen blocking the pad‌

  • Clearly mark the LED polarity (such as the “+” symbol), and keep the silk screen away from the edge of the pad by ≄0.2mm.
  • During design verification, check whether the solder mask opening fully exposes the pad.

To sum up, the above is about SMD LED PCB design and how to select a good PCB supplier. If you have any other questions about designing SMD LED PCB, please leave a message below our blog. Looking forward to hearing from you soon!