IMS PCB: Everything You Need to Know

The metal substrate of IMS PCBs improves mechanical and thermal conductivity. Copper and aluminum are common materials used because they are both inexpensive and light. Copper is more suitable for high-density designs, but it has a lower CTE. A single electrical layer must be sandwiched between a metallic substrate and a prepreg layer in the Integrated Metal Substrate PCB design layout. Typically, these boards are used for simple circuits.

applications of IMS boards

IMS PCBs are suitable for a wide range of applications, including high-power, flammable, and high-temperature environments. They can serve as ground layers to protect sensitive electronic components and directly absorb heat produced by SMD components. These boards are particularly useful in the fields of LEDs, solid-state relays, and power electronics. They do, however, provide additional benefits. If you’re not sure whether IMS PCBs are the right choice for your next project, keep reading to learn more about IMS PCBs and how they can help you make your next project.

IMS PCBs is used in automotive applications because they aid in the cooling of surface-mount components. The dimensional stability of the IMS PCB allows it to operate without cracking in temperatures ranging from 140 to 150 degrees Celsius. Furthermore, its thickness does not increase significantly with temperature, and it can withstand high temperatures. IMS PCBs is frequently more expensive than FR4 PCBs, so choose PCB May if you need high-quality IMS PCBs.

To help manage heat, an IMS PCB has a copper-based base material and a copper-based layer. This layer is made of a copper-based alloy and is either 1.0mm or 1.6mm thick. A single-sided IMS PCB is clear, whereas a double-sided IMS PCB has an aluminum layer on the board’s outside. The IMS PCB is a multilayer PCB regardless of the materials used.

Thermal vias can be counterproductive in some cases because they must be drilled through large areas of well-conducting aluminum. Thermal insulation is insufficient in such cases, and the aluminum cladding alone may suffice. IMS PCBs without thermal vias may be more efficient in this regard because heat is transferred by the aluminum within the carrier. It could even be more efficient than FR4 PCBs.

The thermal management properties of an IMS PCB are one of its most common advantages. A thermally conductive base metal, for example, is a good thermal conductor, reducing the amount of heat that must be transferred. The manufacturer will design and manufacture the board in accordance with these guidelines, and using a standard thickness can help to reduce costs. It is critical, however, to ensure that the material used for the base metal is thermally conductive in order to avoid excessive heat buildup.

Copper, aluminum, and other metals are commonly used to make IMS PCBs. Because of its excellent thermal and electrical properties, copper is frequently used in IMS PCBs. Aluminum is the most common metal substrate and is significantly less expensive than copper. Aluminum is also electrically and thermally conductive, making it an excellent choice for a wide range of applications. However, keep in mind that aluminum is much less resistant to corrosion.

The Advantages of IMS PCBs

When considering the advantages of IMS PCBs, it is useful to understand what distinguishes them from standard boards. A single copper layer is present on a single-layer PCB. On the other side, they are insulated by a metal substrate that also serves as a heatsink. However, if a circuit requires two copper layers, more complex circuits can be integrated. IMS PCBs also include heat transferring vias, which allow heat to be transferred from the top-side components to the bottom-side substrate.

It is critical to consider both the physical and electrical properties of IMS PCBs when using them. The dielectric constant, for example, is used to measure the electrical properties of an IMS PCB by comparing the capacitance of the metal substrate to that of the vacuum. The rate at which the metal substrate changes along the z-axis is another important parameter known as the thermal expansion coefficient. Finally, another important feature is the temperature at which the material transitions to a glass state and decomposition, which determines the material’s heat resistance.

IMS PCBs is constructed from several layers of thermally conductive dielectrics. The circuitry is buried in one or more dielectric layers that serve as thermal and signal vias. Multilayer printed circuit boards are more expensive than single-layer printed circuit boards, but they provide simple heat dissipation for complex circuits. They are an excellent choice for high-end PCs.

Applications of IMS Boards

Because they keep surface-mount components cool, IMS Boards are ideal. The electrical and mechanical properties of IMS PCBs must be thoroughly examined, and the copper thickness must be 0.5 oz. The benefits of the metal substrate and thermal conductivity are completely negated by thick copper. To create the holes for the components, the board must be precisely drilled. The components are then soldered or bonded to the copper surface. Desmearing is required after drilling to remove any melted resin from the drilled holes.

what is IMS PCB

A motherboard and two IMS evaluation modules, which can be configured as a full or half-bridge, comprise the IMS evaluation platform. The evaluation modules support both power levels and include GaN E-HEMTs, gate drivers, DC bus decoupling capacitors, and a heatsink. The evaluation modules can be used to prototype high-power GaN intelligent power modules and in-systems. The board is also intended for high-power applications, making use of vertical space.

Hundreds of control units in modern cars are located around the engine area and are subject to extreme temperatures. Because they can transport heat without the use of discrete heatsinks, industrial IMS PCBs are the ideal solution for applications like this. Solid-state relays, which are small circuits made up of an optocoupler and a MOSFET, are an excellent example of how IMS PCBs are used to transfer heat.

IMS PCBs is also well-known for providing effective thermal dissipation. They can reduce power losses and improve overall product performance because they can be made of thin copper sheets. This allows for higher packing densities on the board, improved overall security, and longer operating times. It is also suitable for use in single-board computers. This simplifies the production of double-sided boards with metal cores.

High-power IMS printed circuit boards are ideal for high-power, high-temperature, and combustible environments. IMS PCBs also serves as an electromagnetic shield and a ground layer. Because of these benefits, IMS PCBs is a popular choice for a variety of applications, including power electronics, solid-state relays, and LEDs. IMS PCBs also enables more compact designs that are less prone to catching fire.

IMS PCBs is more expensive than FR4 PCBs, despite their superior thermal conductivity. Copper-based PCBs have more layers than FR4 PCBs, which can also have multiple layers. PCBs of various thicknesses can be produced using standard machinery. Copper-based boards, on the other hand, are more expensive than their counterparts and have inferior thermal and electrical properties.

About Salman Zafar

Salman Zafar is the CEO of BioEnergy Consult, and an international consultant, advisor and trainer with expertise in waste management, biomass energy, waste-to-energy, environment protection and resource conservation. His geographical areas of focus include Asia, Africa and the Middle East. Salman has successfully accomplished a wide range of projects in the areas of biogas technology, biomass energy, waste-to-energy, recycling and waste management. Salman has participated in numerous national and international conferences all over the world. He is a prolific environmental journalist, and has authored more than 300 articles in reputed journals, magazines and websites. In addition, he is proactively engaged in creating mass awareness on renewable energy, waste management and environmental sustainability through his blogs and portals. Salman can be reached at salman@bioenergyconsult.com or salman@cleantechloops.com.
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