> High thermal conductivity – up to 170 W/mK

> Withstands flexing without cracking

> Good dielectric insulation up to 3kV

> Lightweight – up to 3 times lighter than FR4

> Compatible with standard PCB processes

> RoHS-compliant and UL-approved materials

1. Base Material: The base material of the flexible aluminum PCB is usually made of polyimide, a high-temperature resistant and flexible polymer material.

2. Conductive Layers: The conductive layers are made of thin sheets of aluminum, which provide high thermal conductivity and excellent electrical performance.

3. Solder Mask Layer: The solder mask layer is a protective layer that covers the conductive traces and pads on the PCB, preventing oxidation and corrosion of the metal surfaces.

4. Coverlay Layer: The coverlay layer is a flexible polymer material that provides a protective coating over the top of the PCB, protecting it from damage during handling and use.

> Base aluminum layer – 0.1mm to 0.3mm thick

> Polyimide dielectric layer – 0.025mm to 0.05mm

> Copper foil layer – 12μm to 35μm

> Protective coverlay on traces

1. Flexibility: Flexible Aluminum PCBs can be bent, twisted, and folded without damaging the circuitry or the board itself. This flexibility allows for the creation of unique shapes and sizes, making it ideal for applications where space is limited.

2. High Thermal Conductivity: The aluminum substrate used in Flexible Aluminum PCBs has excellent thermal conductivity, allowing for efficient dissipation of heat generated by high-power components. This feature is especially important in applications such as LED lighting, automotive electronics, and power electronics.

3. Light Weight: Flexible Aluminum PCBs are lightweight, which makes them an ideal choice for products that require a high degree of portability, such as wearable devices or portable medical equipment.

4. High Durability: The use of high-quality materials and manufacturing processes in Flexible Aluminum PCBs ensures high durability, which makes them less prone to damage from vibration, shock, or impact.

5. Cost-Effective: Despite their unique characteristics and advantages, Flexible Aluminum PCBs can be cost-effective due to their ability to reduce material usage and increase manufacturing efficiency.

6. Increased Design Flexibility: Flexible Aluminum PCBs provide greater design flexibility compared to traditional rigid PCBs, allowing designers to create more complex and unique designs that would otherwise be impossible to achieve.

7. Reduced Assembly Time: Flexible Aluminum PCBs can be assembled quickly and efficiently, reducing assembly time and making them ideal for high-volume production.

1. LED Lighting: Flexible Aluminum PCBs are used extensively in LED lighting applications due to their high thermal conductivity, which allows for efficient dissipation of heat generated by high-power LED components.

2. Automotive Electronics: Flexible Aluminum PCBs are used in automotive electronics for their high durability and ability to withstand vibration, shock, and extreme temperatures.

3. Wearable Devices: Flexible Aluminum PCBs are an ideal choice for wearable devices due to their flexibility, lightweight, and compact size.

4. Medical Devices: Flexible Aluminum PCBs are used in medical devices for their high durability, reliability, and resistance to harsh chemicals and sterilization processes.

5. Consumer Electronics: Flexible Aluminum PCBs are used in a wide range of consumer electronics, including smartphones, tablets, and laptops, for their ability to reduce space requirements and improve performance.

6. Aerospace and Defense: Flexible Aluminum PCBs are used in aerospace and defense applications due to their high reliability, resistance to harsh environments, and ability to reduce weight and size requirements.

7. Power Electronics: Flexible Aluminum PCBs are used in power electronics for their high thermal conductivity, which allows for efficient dissipation of heat generated by high-power components.

1. Designing: The first step in the manufacturing process of Flexible Aluminum PCBs is designing the PCB layout using computer-aided design (CAD) software. The layout specifies the location of components, traces, and other features on the PCB.

2. Material Selection: The next step is selecting the appropriate materials for the PCB, including the base material, conductive layers, solder mask, and coverlay. The materials used depend on the specific requirements of the application.

3. Drilling: The PCB layout is transferred to a copper-clad aluminum sheet, and holes are drilled in the sheet at locations specified in the design. These holes are used for component placement and electrical connections.

4. Etching: After drilling, the copper layers are etched to remove the unwanted portions, leaving only the conductive traces and pads.

5. Lamination: The base material, conductive layers, and coverlay are laminated together using heat and pressure, forming a multilayered PCB.

6. Solder Mask Application: A solder mask is applied to the surface of the PCB, covering the exposed copper traces and pads to prevent oxidation and corrosion.

7. Surface Finishing: The surface of the PCB is finished with a protective coating, such as gold, silver, or nickel, to enhance its durability and prevent oxidation.

8. Testing and Inspection: The finished Flexible Aluminum PCB is tested and inspected to ensure its electrical and mechanical performance meets the design specifications.

1. Thickness: The thickness of the Flexible Aluminum PCB should be specified based on the application requirements. Generally, the thickness of the base material ranges from 0.1mm to 3mm, and the overall thickness of the PCB can range from 0.2mm to 3mm.

2. Copper Thickness: The thickness of the copper layer on the Flexible Aluminum PCB should be specified based on the current-carrying capacity and the application requirements. Generally, the copper thickness can range from 0.5oz to 10oz.

3. Minimum Trace Width/Spacing: The minimum trace width and spacing on the Flexible Aluminum PCB should be specified based on the application requirements and the manufacturing process. The minimum trace width and spacing can range from 0.1mm to 0.3mm.

4. Surface Finish: The surface finish on the Flexible Aluminum PCB should be specified based on the application requirements and the manufacturing process. Common surface finishes include HASL, ENIG, OSP, and immersion tin.

5. Thermal Conductivity: The thermal conductivity of the aluminum substrate used in Flexible Aluminum PCBs is an important parameter that needs to be considered for applications that generate a significant amount of heat.

6. Peel Strength: The peel strength of the coverlay used in Flexible Aluminum PCBs should be specified based on the application requirements. The peel strength should be high enough to prevent delamination during use.

7. Bend Radius: The bend radius of the Flexible Aluminum PCB should be specified based on the application requirements. The minimum bend radius should be specified to prevent damage to the circuitry during bending or flexing.

8. Tensile Strength: The tensile strength of the coverlay and the adhesive used in Flexible Aluminum PCBs should be specified based on the application requirements. The tensile strength should be high enough to prevent tearing or damage during use.

1. Design Support: We provide design support services to our customers to ensure that the PCB layout and design meet the specific requirements of their application. Our experienced engineers can work closely with customers to optimize the PCB layout and design for optimal performance and reliability.

2. Material Selection: We work with our customers to select the appropriate materials for their PCB based on their specific requirements. Our materials include high-quality base materials, conductive layers, solder masks, and coverlay.

3. Manufacturing Capabilities: Our state-of-the-art manufacturing facility has advanced manufacturing capabilities that enable us to produce high-quality Flexible Aluminum PCBs with fast turnaround times. Our capabilities include drilling, etching, lamination, surface finishing, and testing.

4. Quality Control: We have a strict quality control process in place to ensure that our Flexible Aluminum PCBs meet the highest standards of quality and reliability. Our quality control process includes visual inspection, electrical testing, and mechanical testing.

5. Customization: We offer customization services to our customers to meet their unique requirements. Our customization services include specific PCB thickness, copper thickness, surface finish, and other technical parameters.

6. Competitive Pricing: We offer competitive pricing for our Flexible Aluminum PCB manufacturing services without compromising on quality. Our pricing is based on the customer’s specific requirements, and we offer flexible pricing options to accommodate different budget requirements.