Posts Tagged ‘Ims pcb manufacturer’

IMS PCB Material Selection & Design Guideline

Tuesday, July 22nd, 2025

Are you worried about how to choose IMS PCB material for your project? Let’s explore its definition, properties, datasheet, types, IMS PCB material selection and design guidelines through this blog.

Wrong choice of substrate material leads to too high thermal resistance?
Is the dielectric layer easy to delaminate during multi-layer IMS design?
Is the dielectric loss too large under high-frequency application?

Best Technology Can Provide:

Provide 5 standardized thermal conductivity levels (1.5~8W/mK); Free sample matching tool, generate selection report in 30 minutes.
Patented resin system, peel strength>1.8N/mm; Support 3-layer lamination process, provide design specification manual.
Df value as low as 0.002 (@10GHz); Equipped with HFSS simulation model library, plug-and-play.

Welcome to contact us if you have any request for IMS PCB or MCPCB: sales@bestpcbs.com.

What Is IMS Material?

IMS material, known as insulated metal substrate, consists of a metal core, typically aluminum or copper, coated with a dielectric insulation layer and a conductive copper layer for circuit traces. This structure delivers outstanding thermal management, with aluminum-based versions achieving thermal conductivity of 1-3 W/(m·K), while copper-based variants exceed 400 W/(m·K) for accelerated heat dissipation.

It serves effectively in high-power applications like LED lighting systems and automotive electronics, where efficient cooling maintains device stability and extends operational lifespan under thermal stress.

IMS PCB Material Properties

Thermal Conductivity – Metal base (aluminum/copper) transfers heat 5-10x faster than FR4, keeping components cooler.
Electrical Insulation– Dielectric layer provides high voltage isolation (1-10kV) while allowing heat flow.
Mechanical Strength – Metal core resists bending/warping, ideal for heavy components or high-vibration environments.
Thermal Expansion – Low CTE (Coefficient of Thermal Expansion) matches components, reducing solder joint stress.
Temperature Resistance – Withstands 150-250℃ operating temperatures without degradation.
Weight Efficiency – Aluminum bases offer lightweight heat dissipation, crucial for automotive/aerospace.
Surface Flatness – Metal substrates ensure precise component mounting, critical for fine-pitch devices.

IMS PCB Board Material Datasheet

Property	Aluminum-Based IMS	Copper-Based IMS	Measurement Standard
Thermal Conductivity	1-3 W/(m·K)	>400 W/(m·K)	ASTM E1461
Dielectric Strength	≥4 kV/mm	≥4 kV/mm	IPC-TM-650 2.5.6
CTE (Z-axis)	12-15 ppm/°C	16-18 ppm/°C	IPC-TM-650 2.4.24
Tg (Glass Transition)	130-150°C	150-170°C	IPC-TM-650 2.4.25
Td (Decomposition)	300-320°C	350-380°C	IPC-TM-650 2.3.40
Volume Resistivity	≥10¹² Ω·cm	≥10¹² Ω·cm	IPC-TM-650 2.5.17
Flexural Strength	100-150 MPa	200-250 MPa	IPC-TM-650 2.4.4

What Are Types of IMS PCB Material?

Aluminum-Based IMS

Thermal Conductivity: 1-2.5W/m·K.
Application: LED lighting, consumer power supplies, and automotive controls where cost efficiency and moderate heat dissipation are prioritized.

Copper-Based IMS

Thermal Conductivity: 3-4W/m·K.
Application: High-power industrial drives, automotive powertrains, and aerospace components requiring extreme thermal performance.

Stainless Steel-Based IMS

Thermal Conductivity: 0.2-0.5W/m·K.
Application: Corrosive environments (e.g., marine, chemical processing) where mechanical durability outweighs thermal needs.

Composite Metal Core IMS

Structure: Aluminum/copper layer bonded to a thin copper circuit layer.
Application: Compact devices like mobile chargers and RF amplifiers needing both heat spreading and fine-pitch circuitry.

How to Choose IMS PCB Material?

IMC PCB Material Selection Guideline:

1. Assess Power Density Requirements

High-Power Applications (e.g., industrial drives, automotive power modules):
Choose copper-based IMS (thermal conductivity 3-4W/m·K) for power densities exceeding 5W/cm².
Standard Applications (e.g., LED lighting, consumer electronics):
Prioritize aluminum-based IMS (1-2.5W/m·K) for power densities below 5W/cm².

2. Align with Budget Constraints

Aluminum-based IMS costs 20-30% less than copper, making it suitable for cost-driven projects like household appliances.
Reserve copper-based IMS for premium sectors (aerospace, medical devices) where long-term reliability outweighs upfront costs.

3. Match Environmental Conditions

Corrosive Environments (marine, chemical processing): Select stainless steel-based IMS for corrosion resistance, despite lower thermal efficiency.
High-Temperature Zones (engine compartments, RF amplifiers): Use copper-based IMS with polyimide insulation (withstanding temperatures >200°C).

4. Account for Spatial Limitations

Compact Devices (mobile chargers, wearables): Choose aluminum composite IMS (0.8mm thickness) to balance heat dissipation and space efficiency.
Multi-Layer Designs: Prioritize copper-based IMS for structural rigidity, preventing warping in complex PCB stacks.

5. Validate Compliance with Standards

Critical Systems (automotive ECU, aerospace): Demand IPC-6013-certified copper-based IMS with documented thermal cycling test results.
Consumer Products (TVs, monitors): Aluminum-based IMS meets 85°C operational requirements for typical use cases.

6. Decision-Making Framework

Start with power density thresholds to narrow material options.
Cross-reference with budget allocation and environmental exposure.
Finalize with space constraints and certification needs.

7. Application Examples

Industrial Motor Control: Copper-based IMS for sustained 100A+ current handling.
Outdoor LED Displays: Aluminum-based IMS with conformal coating for humidity resistance.
Automotive Powertrain: Copper-based IMS + high-temperature dielectric for under-hood reliability.

8. Critical Precautions

Request third-party thermal resistance reports to verify supplier claims.
Avoid materials with unspecified dielectric breakdown voltage in high-voltage applications.
Test prototypes under real-world thermal stress before mass production.

How to Design IMS PCB Board?

IMS PCB Design Guideline:

1. Define Design Objectives

Clarify power density (W/cm²), operating environment (temperature/humidity), space limits, and budget. Example: Automotive ECU board needing 50A current handling in 100°C engine bay.

2. Material Selection Recap

High-Power (>5W/cm²): Copper-based IMS (3-4W/m·K).
Cost-Sensitive: Aluminum-based IMS (1-2.5W/m·K).
Corrosive Environments: Stainless steel-based IMS.

3. Layer Stackup Design

Place metal base directly below high-power components.
Keep dielectric layer thickness ≤100µm for optimal thermal performance.
Example: 2-layer IMS (copper base + 35µm circuit layer).

4. Thermal Management Strategies

Thermal Vias: Use 0.5mm diameter filled vias under hot components, spaced 1mm apart.
Reserved Cooling Zones: Allocate 30-50% of board area as unpopulated metal regions.
Component Placement: Center power devices (MOSFETs/IGBTs) over the metal core; keep ≥2mm spacing between high-power parts.

5. Electrical Layout Optimization

Trace Width: Use 3oz (105µm) copper for traces carrying >50A. Widen traces by 2x near heat sources.
Avoid Sharp Bends: Maintain ≥3x trace width for bend radii to reduce resistance.
Impedance Control: For RF/high-speed signals, keep dielectric thickness consistent (±10µm tolerance).

6. Manufacturing Compatibility

Design Rules: Minimum trace width/spacing ≥0.2mm for aluminum IMS; ≥0.15mm for copper IMS.
Solder Mask: Remove mask in thermal zones to maximize metal exposure.
Panelization: Add 2mm border around boards for handling during assembly.

7. Validation & Testing

Thermal Imaging: Test under max load to identify hotspots. Junction temp should stay ≤85°C.
Electrical Testing: Verify current capacity and signal integrity (e.g., <5% voltage drop).
Reliability Testing: Conduct thermal cycling (-40°C to +125°C, 100 cycles) and vibration tests (2G RMS).

IMS PCB Board Design Considerations

Thermal Management‌

Base Material Selection‌: Aluminum (1-3 W/mK) suits cost-sensitive, moderate-heat applications like LED lighting. Copper (>400 W/mK) is ideal for high-power modules requiring rapid heat dissipation.
Dielectric Thickness‌: Thinner layers (50-100μm) improve heat transfer but reduce voltage isolation. Match thickness to operational voltage (e.g., 100μm for <1kV).
Component Placement‌: Position high-heat components (e.g., power ICs, LEDs) directly over the metal core to maximize thermal path efficiency.

Electrical Performance‌

Trace Width/Spacing‌: Wider traces reduce resistance for high-current paths. Maintain ≥0.3mm spacing for 1kV isolation in standard designs.
Via Usage‌: Avoid thermal vias in the dielectric layer, they disrupt heat flow. Route signals through peripheral non-metal zones.
High-Frequency Limits‌: IMS materials exhibit higher dielectric loss than FR-4. Limit use in RF circuits (>500MHz).

Mechanical Design‌

Board Thickness‌: Standard metal cores (1.0-3.0mm) prevent flexing but increase weight. For lightweight needs, consider 1.0mm aluminum.
Mounting Hardware‌: Use insulated standoffs to prevent short circuits with the metal base. Account for CTE mismatch, aluminum expands 23ppm/°C versus 17ppm/°C for copper.
Cutouts & Edges‌: Smooth, rounded edges minimize stress concentrations. Internal cutouts require laser processing to avoid burrs.

Manufacturing & Cost‌

Fabrication Tolerance‌: IMS requires specialized drilling (carbide bits) due to metal hardness. Allow ±0.1mm for hole positioning.
Panel Utilization‌: Standard panel sizes (18″×24″) optimize cost. Odd shapes increase waste.
Finish Options‌: HASL is cost-effective but limits thermal performance. ENIG (Ni/Au) enhances solderability for fine-pitch components.

Application-Specific Tips‌

LED Arrays‌: Use 1.5mm aluminum cores with 80μm dielectric to balance cost and heat dissipation (ΔT<15°C at 5W/cm²).
Automotive Inverters‌: Copper cores with 150μm dielectric handle 10-15A/mm² current density and 125°C ambient temperatures.
Aerospace‌: Stainless steel bases provide vibration resistance but require thermal interface materials (TIMs) to offset lower conductivity.

How to Select A Reliable IMS PCB Manufacturer?

Tips for selecting a reliable IMS PCB manufacturer:

Confirm Thermal Management Expertise‌: Verify experience with aluminum/copper cores and UL-certified dielectric materials for effective heat dissipation in high-power applications‌.
Demand Precision Manufacturing Capabilities‌: Ensure ≤50μm laser drilling accuracy for microvias and tight tolerances (±25μm) critical for thermal performance‌.
Require Relevant Quality Certifications‌: Prioritize IATF 16949 (automotive) or ISO 13485 (medical) certified suppliers with documented thermal cycling tests (-40°C to +150°C)‌.
Evaluate True Production Speed‌: Compare realistic lead times. Proven manufacturers deliver prototypes in 7 days, 30% faster than industry norms without compromising quality‌.
Insist on Transparent Costing‌: Avoid hidden fees. Competitive suppliers offer fixed pricing with 5-15% savings through efficient material utilization‌.
Check Scalability from Prototype to Volume‌: Choose partners handling orders from 5 panels to mass production seamlessly within their facilities‌.
Prioritize Technical Partnership‌: Select manufacturers providing free 24-hour DFM feedback and thermal simulation support to optimize your design‌.
Experience the Best Technology Advantage‌: Get a rapid quote for your IMS PCB project today. We combine certified quality, 7-day prototype turnaround, and cost-competitive pricing—ensuring your thermal management solution excels. Request your quote now.

Ready to start your project?‌ Contact ‌Best Technology‌ today for competitive pricing, guaranteed fast delivery, and certified quality. Let’s optimize your thermal management solution together: sales@bestpcbs.com.

Tags:ims pcb, Ims pcb manufacturer, IMS PCB material
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Insulated Metal Base PCB, IMS PCB Manufacturer

Monday, July 21st, 2025

Insulated Metal Base PCB is a type of circuit board designed for high heat dissipation. It features a metal core—usually aluminum or copper—covered by a thin insulating layer and a copper circuit layer. This structure allows heat to transfer away from components quickly, making it ideal for high-power applications like LED lighting, power supplies, and automotive systems.

Insulated Metal Base PCB, IMS PCB manufacturer

What is IMS in PCB?

IMS stands for Insulated Metal Substrate. It’s a specific type of printed circuit board designed to transfer heat away from high-power components.

Unlike traditional boards made of FR4 or fiberglass, IMS PCBs have a metal base layer, typically aluminum or copper. Above this, there’s a thin dielectric insulation layer that separates the metal from the copper circuitry. This structure allows the board to carry electrical signals while efficiently pulling heat away from components.

What’s the IMS PCB definition?

In simple terms, an IMS PCB is a single-layer PCB with a metal backing that provides better thermal conductivity than standard materials.

This type of board is especially common in high-power applications like LED drivers, power supplies, automotive lighting, and industrial equipment.

The insulation layer, though thin, plays a critical role. It ensures the circuit functions properly while still allowing heat to pass through to the metal core. This sandwich-like structure is what sets IMS PCBs apart from standard designs.

What materials are used in IMS board PCB production?

Here’s what goes into a high-performance IMS board PCB:

Metal Base Layer: Most commonly aluminum, though copper is used in high-demand environments. Aluminum is preferred for its cost-efficiency, lightweight nature, and good thermal performance.

Dielectric Layer: This is the heart of heat transfer. It must be thin enough to allow thermal flow, yet strong enough to withstand voltage stress.

Copper Foil Layer: The circuit layer, typically 1–3 oz thick. It’s where your electronic components connect and signals travel.

Surface Finish: Surface treatments like ENIG (Electroless Nickel Immersion Gold) or OSP (Organic Solderability Preservatives) ensure strong soldering and prevent oxidation.

At BEST Technology, we tailor each IMS board to your exact needs. Whether you need copper or aluminum base materials, custom thicknesses, or unique finishes, we deliver to your standards.

How does IMS manufacturing work?

The IMS manufacturing process is precise and tailored. Here’s how we do it at BEST Technology:

Base Preparation: We start with high-purity aluminum or copper plates. These are cleaned and prepped to remove any contaminants.

Lamination: A dielectric material is laminated onto the metal base. This insulation controls both heat transfer and electrical isolation.

Copper Cladding: A copper foil is applied on top of the dielectric. It forms the base of your circuit paths.

Imaging and Etching: Using UV exposure, we apply your circuit pattern. Then we etch away excess copper to leave behind only your desired traces.

Drilling and Plating: Holes for mechanical support or electrical connections are precisely drilled and plated.

Solder Mask and Finish: A solder mask is applied, followed by a surface finish that fits your assembly method.

Testing: Electrical testing ensures every circuit functions perfectly. Our factory performs 100% inspection before shipment.

How does IMS PCB handle heat?

The beauty of IMS PCBs lies in their thermal path. Heat from components passes through the copper trace into the dielectric layer, and from there, it’s transferred to the metal base. The base, often aluminum, quickly spreads and dissipates the heat across the board or into a heat sink.

This keeps the board cooler, even under high-power loads.

Compared to standard FR4 boards, IMS PCBs have up to 10 times better thermal conductivity. This directly reduces component stress, avoids early failure, and boosts long-term reliability.

What are the benefits of IMS PCB?

Superior Heat Dissipation: IMS PCBs are engineered to manage heat—fast and efficiently.

Compact Design: With better thermal control, components can be placed closer together. This allows for smaller, lighter devices.

Longer Lifespan: Cooler components last longer. That means fewer repairs, better reliability, and a higher-quality end product.

High Mechanical Strength: The metal base adds stiffness and reduces vibration. Ideal for automotive, aerospace, and outdoor equipment.

Cost Savings Over Time: While slightly more expensive upfront, IMS boards can reduce the need for extra cooling systems.

High Power Density: Great for applications like LED drivers, where compact, powerful systems are a must.

In short, IMS PCBs deliver power, durability, and efficiency—the perfect trio for demanding industries.

What is an IMS board PCB used for?

IMS PCBs are extremely versatile and can be used in systems where heat and power are a concern. Common uses include:

LED lighting modules: Street lights, automotive headlights, stadium lighting.
Power electronics: Converters, adapters, power distribution units.
Automotive systems: Brake systems, engine control units, infotainment panels.
Industrial control: Motor drivers, automation panels, heavy machinery.
Medical devices: Imaging equipment, surgical lighting, diagnostic systems.
Telecom equipment: Base stations, antennas, and signal amplifiers.

These boards shine in any place where compact size and high power must coexist safely.

What is the best PCB manufacturer?

When you’re sourcing IMS boards, the manufacturer you choose makes all the difference.

BEST Technology stands out as one of the most reliable IMS PCB manufacturers in China. Here’s why:

Established expertise: Since 2006, we’ve focused on MCPCBs and IMS boards, delivering quality without compromise.

Certified reliability: We hold certifications like UL, ISO9001, ISO13485, IATF16949, and SGS—backing our quality promise.

Full turnkey service: From PCB design to assembly, we manage it all. This shortens lead times and streamlines your workflow.

Strong factory support: Our 30,000㎡ plant and 229+ staff allow for large-scale production with consistent results.

Competitive pricing: We manage costs smartly to give you maximum value for your investment.

Most importantly, we believe in partnerships. Our team works closely with yours, offering one-on-one assistance, custom solutions, and a 48-hour technical response policy.

Conclusion:

Whether you’re designing compact LED modules or building industrial power units, an IMS board offers the reliability and performance you need.

As a professional IMS PCB manufacturer, BEST Technology can provide trusted expertise, service and quality. With over 19 years of experience, comprehensive certifications and a customer-first philosophy, we are proud to be a reliable supplier for all your IMS board needs.

Have a project in mind? Reach out to us today at sales@bestpcbs.com

Tags:IMS manufacturing, Ims pcb definition, Ims pcb manufacturer, Insulated Metal Base PCB
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What is IMS PCB? IMS PCB Stack-up

Wednesday, June 4th, 2025

What is IMS PCB?

IMS PCB stands for Insulated Metal Substrate Printed Circuit Board. It’s a specialized type of PCB designed to manage heat more effectively than standard boards. At its core, an IMS board is made of three main layers: a metal base (usually aluminum), a thermally conductive dielectric layer, and a copper circuit layer on top.

This unique construction gives IMS boards exceptional heat transfer capabilities. Unlike standard FR4 boards, where heat may accumulate and degrade performance over time, an IMS PCB actively channels heat away from components and dissipates it through the metal base. This process helps protect sensitive parts and improves overall device longevity.

IMS PCBs are commonly used in LED lighting systems, power converters, automotive electronics, solar inverters, and industrial control systems. Any circuit that generates significant heat can benefit from the enhanced thermal management of an IMS PCB.

Features of IMS PCB

IMS PCBs are favored in demanding applications because of their distinct advantages. Below are some of the standout features:

1. The dielectric layer in an IMS PCB has much higher thermal conductivity compared to FR4.

2. Once heat reaches the metal base, it is dispersed across a larger surface area or transferred to a heatsink.

3. The metal base not only helps with heat but also strengthens the board. This added rigidity reduces the chances of warping, especially in environments with temperature cycling or mechanical stress.

4. Components perform better and last longer when they remain within optimal temperature ranges.

5. Most IMS boards are single-sided, simplifying the layout and making them easier to manufacture. However, advanced designs may include multilayer configurations when required.

6. The metal base can also serve as a shield against EMI interference, which is useful in sensitive analog or RF applications.

Types of IMS Boards

Different IMS boards are used for different applications depending on the metal type and overall construction. Here are the three primary types:

Aluminum-Based IMS PCB

This is the most popular type and often the first choice for LED lighting and consumer electronics. Aluminum is lightweight, affordable, and has decent thermal performance. It strikes a balance between cost and functionality for a wide range of applications.

Copper-Based IMS PCB

Copper has better thermal and electrical conductivity than aluminum. These boards are used in high-end applications where superior thermal management is critical, such as power modules, solar inverters, and automotive control systems. However, copper is more expensive and heavier than aluminum.

Steel-Based IMS PCB

Less common but useful in environments where mechanical durability is crucial. Steel doesn’t conduct heat as efficiently as copper or aluminum but provides maximum rigidity and resistance to deformation. It’s mainly used in industrial or military electronics.

Each type of IMS PCB is selected based on the specific needs of your project. Aluminum offers a good starting point, copper pushes performance higher, and steel provides strength for the harshest conditions.

IMS PCB Stack-up

A critical element in IMS board design is the stack-up, which refers to how the different layers of the board are arranged. The typical IMS PCB stack-up includes the following:

1. Copper Layer

This is where all the electronic traces and pads are formed. The copper thickness usually ranges from 1 oz to 3 oz per square foot, depending on current requirements. It serves as the pathway for electrical signals and power.

2. Dielectric Layer

This is the thermally conductive but electrically insulating layer that separates the copper and the metal base. It’s usually made of a polymer filled with ceramic particles. The dielectric plays a vital role in transferring heat efficiently while preventing short circuits. The thickness typically ranges from 0.075 mm to 0.2 mm, with thermal conductivity from 1 to 7 W/m·K, depending on material grade.

3. Metal Base

This is typically made of aluminum, copper, or steel. The metal provides mechanical support and acts as the main heat dissipation path. Its thickness usually ranges from 1 mm to 2 mm, but thicker bases are used in heavy-duty applications.

Some advanced designs may include additional dielectric and copper layers to create double-layer or multilayer IMS PCBs, though this increases cost and complexity.

How Thick is an IMS PCB?

The total thickness of an IMS PCB is influenced by the materials used and application requirements. On average, the board thickness ranges from 0.8 mm to 3.2 mm, but custom configurations are available.

Here’s a breakdown of each layer’s contribution to overall thickness:

Copper Layer: 35–105 µm (1–3 oz)
Dielectric Layer: 75–200 µm
Metal Base Layer: 1.0–2.0 mm (for aluminum or copper)

Applications requiring high current typically demand thicker copper layers and sometimes thicker base metals. Likewise, if better insulation is needed, the dielectric layer can be made thicker, but this may reduce heat transfer efficiency. Engineers must balance electrical, thermal, and mechanical requirements to define the most suitable thickness.

What is the Difference Between IMS PCB and FR4 PCB?

Though both are used in electronic devices, the differences between IMS PCB and FR4 PCB are quite substantial:

Parameter	IMS PCB	FR4 PCB
Full Name	Insulated Metal Substrate PCB	Flame Retardant Grade 4 PCB
Base Material	Metal core (usually aluminum or copper)	Fiberglass-reinforced epoxy (FR4)
Thermal Conductivity	High (1–7 W/m·K, depending on dielectric)	Low (typically 0.3–0.4 W/m·K)
Heat Dissipation	Excellent, through metal base	Limited, requires heatsinks or fans
Layer Structure	Usually single-sided	Can be single, double, or multilayer
Mechanical Strength	High (due to metal base)	Moderate (flexible but less rigid)
Weight	Heavier (due to metal core)	Lighter
Manufacturing Cost	Higher	Lower
Applications	Power electronics, LEDs, automotive, solar	Consumer electronics, IoT, communication devices
Thermal Resistance	Low (better heat flow)	High (poor thermal path)
Electrical Insulation	Through thermally conductive dielectric	Provided by FR4 material itself
Common Copper Thickness	1–3 oz	1–2 oz
Typical Board Thickness	0.8–3.2 mm	0.6–2.0 mm
Design Complexity	Lower (usually single-layer)	Higher (multilayer and complex routing possible)
Price Range	Mid to High	Low to Mid

What is the Thermal Resistance of IMS Board?

Thermal resistance (Rθ) refers to a material’s resistance to heat flow. In IMS PCBs, it is mainly influenced by the dielectric layer. A lower Rθ means better heat transfer and lower temperature rise.

The thermal resistance of an IMS board is calculated using:

Rθ = t / (k × A)

Where:

t = dielectric thickness

k = thermal conductivity

A = surface area

Typical values for IMS PCBs range from 0.2°C/W to 1.0°C/W, depending on materials and layout. Advanced dielectric materials with high k-values can push this number lower, helping improve performance in high-power applications.

Designers often select materials with k ≥ 3 W/m·K and limit the dielectric layer to under 150 µm to achieve low thermal resistance.

Best Technology – Reliable IMS PCB Manufacturer

If you’re sourcing IMS PCBs and want consistent quality, Best Technology is your go-to IMS PCB manufacturer. We have a dedicated production line for metal-core PCBs, including aluminum, copper, and hybrid metal boards.

Why Choose Best Technology?

✅ Professional Engineering Support: Our experienced team helps optimize stackups, select dielectric materials, and improve thermal paths in your layout.

✅ ISO Certifications: We are certified with ISO9001, IATF16949, ISO13485, and AS9100D, serving a wide range of industries including medical, automotive, and aerospace.

✅ MES Traceability: Every board is tracked using our MES system to ensure complete traceability from raw materials to final shipment.

✅ Flexible Volumes: Whether you need a prototype batch or full-scale production, we offer scalable solutions.

✅ Comprehensive IMS PCB Assembly: Beyond PCB fabrication, we also offer full assembly including component sourcing, reflow soldering, inspection, and testing.

From concept to finished product, we work closely with clients to deliver high-performance IMS PCBs that meet electrical, mechanical, and thermal demands.

FAQs

1. What does IMS PCB stand for?

It stands for Insulated Metal Substrate Printed Circuit Board, a high-performance board for heat-sensitive applications.

2. Can IMS PCB be double-sided?

Yes, though less common. Double-sided IMS PCBs require more advanced fabrication and cost more, but they’re available for complex designs.

3. Is IMS PCB good for automotive systems?

Absolutely. Automotive systems generate a lot of heat and require reliability. IMS PCBs are ideal for ECUs, power converters, and headlight controls.

4. What thermal conductivity should I choose for my dielectric layer?

It depends on the heat generated. For moderate power, 1–2 W/m·K is enough. For high-power LEDs or power modules, choose ≥3 W/m·K.

5. How do I request a quote from Best Technology?

Send your Gerber files, stackup requirements, and assembly needs to our team, and we’ll respond with a customized quote within 24 hours.

Tags:Ims pcb assembly, Ims pcb definition, Ims pcb manufacturer
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