PCB 설계를 위한 4가지 황금률

10월 25, 2022/0 코멘트/카테고리: 블로그 /작성자: [email protected]

PCB 설계를 위한 4가지 황금률

When designing a PCB, there are several golden rules that you must follow. These include the Design rule check (DRC) as often as possible, grouping components, separating traces, and the Thermal relief pattern. All of these will make the design process go more smoothly and reduce costs. Moreover, these rules will help you save time and money by making stock decisions easier.

Design rule check (DRC) as often as you can bear it

Design rule checking (DRC) is an important process that helps engineers avoid costly design errors. It helps them identify flaws before they are implemented into their PCB designs. Design rule checking is an efficient way to check that a design meets its specifications and that it will not cause any problems for the final assembly.

PCB designers can run a DRC on their schematic and layout designs to identify and fix errors. These tools generate a comprehensive report detailing any violations. These reports include details such as the rules violated and the specific components involved by reference designator. These tools can also be used manually. However, you should keep in mind that they are not a replacement for a DRC.

While the DRC on PCB design takes some time, it can save you a lot of headache later on. Even if your PCB design is simple, checking it frequently will save you hours of tedious work. It is a good habit to get into, especially if you are working on a complex PCB.

Grouping components

Grouping components is an important part of PCB design. Components with similar functions should be placed together. For example, power management ICs should be grouped with LDOs and other similar devices. In addition, power management ICs and other devices with high currents should be separated from analog and digital parts. Also, keep components with high switching frequencies and high electromagnetic noise separate from other parts. By grouping components by function, you will have a better control over the return path, and you’ll also be able to avoid overheating certain components.

Grouping components in a PCB design is essential to avoid crosstalk and interference between digital and analog signals. Crosstalk is a problem that can compromise the integrity of the signal. To prevent this problem, grouping non-homogeneous components into distinct areas is the simplest solution. This way, the analog and digital masses won’t confuse each other.

The placement of components is important because it affects the overall process and the overall design of the product. Improper placement can result in poor functionality, manufacturability, and maintenance. Some signals may also be corrupted if they are placed incorrectly. The correct placement of components can improve the design process and save a lot of time.

Separating traces

The process of PCB design involves separating traces. The exact width and number of traces will depend on the nature of the signal being transmitted. Thin traces are usually used for low-current TTL signals that don’t need noise protection or high current carrying capacity. They are the most common type of traces on a circuit board. However, some PCB designs will need thicker traces to carry high-power signals and other power-related functions.

Trace geometry is of great importance for proper circuit operation. Because traces are used to carry electrical signals, they must be the right width to prevent overheating and minimize the area of the PCB. There are many calculator tools online that will help you calculate the proper width of a trace.

When designing a PCB, it’s vital to separate analog signals from digital signals. These signals can interfere with each other, and it’s important to keep them separated to prevent crosstalk.

Thermal relief pattern

A thermal relief pattern helps circuit boards dissipate heat across a large area. This is useful when soldering through-hole devices. It is important that the circuit board be designed to minimize the risk of heat buildup during the soldering process.

Thermal relief patterns should be used at any place where a component plate meets a via or a ground plane. They also provide additional support for the component and help reduce thermal stress. Thermal reliefs should be checked regularly during the design phase. Caught early, problems can be minimized or avoided entirely.

It is also important to note that the size of the thermal reliefs must match the width of the power trace. Too small a thermal relief can result in excessive heat and a burned-out connection. A better thermal relief design is one that features enough metal and fewer spokes.

맞춤형 인쇄 회로 기판 제작을 위한 5가지 팁

10월 13, 2022/0 코멘트/카테고리: 블로그 /작성자: [email protected]

맞춤형 인쇄 회로 기판 제작을 위한 5가지 팁

If you’re looking to create a custom printed circuit board, there are four key tips you need to follow. These include choosing the right circuit board design software and components early in the design process. Choosing the right materials is another important step to take. Finally, make sure your components are physically and electrically close to one another in the schematic.

Choosing the right circuit board design software

There are several different software solutions to choose from. Choosing the right software for your project can make designing your printed circuit boards easier. Some options provide more advanced features than others. For example, OrCAD PCB Designer includes libraries for signal integrity, schematic capture, auto-routing, and constraint management. It also supports a wide variety of electronic solutions, the English language, and Windows operating systems.

Circuit board design software is a vital part of any electronic product design. It helps engineers visualize and analyze electronic circuitry. It also helps them share their designs with mechanical engineers. A good PCB design software has an extensive library of components to choose from. With a library of pre-defined components, you don’t need to reinvent the wheel every time you create a new part.

While there are many EDA tools out there, the best ones are not free. They are premium tools with robust features. It can be difficult to choose the right one for your needs. The most important thing to consider is the community support of the software you choose. Choosing the right software for your custom printed circuit boards can make your design easier to produce.

Choosing components early in the design process

While creating custom printed circuit boards, it is crucial to choose components early on in the design process. Early selection of components will help you avoid problems with PCB layout and manufacturing. The design process includes several steps to ensure your board is suited to your needs. The first step is to define your PCB’s scope. This is the process in which you specify all components and their locations on the board.

The size of your custom circuit board will determine the components that are most appropriate. Choosing the right size will depend on the final functionality of your circuit. For example, you may want to choose a circuit board that is a certain size in order to fit the entire device. Also, larger circuits may not fit on a single copper layer, so you may need to choose two layers of copper. In such a case, traces will need to be routed on both sides of the PCB.

Early selection of components is critical for the performance and longevity of your PCB. Component placement can affect heat distribution, weight, and performance. While you should adhere to industry best practices when designing custom PCBs, it is a good idea to inject some of your personal style into the design process as well. By integrating your personal ideas, style, and creativity into the design process, you will be able to make your custom PCBs stand out from the competition.

Conducting a design rule check

Conducting a design rule check (DRC) is an important process for engineers creating custom printed circuit boards. It allows them to identify potential errors and fix them before manufacturing begins. Design rule checks should be carried out frequently to ensure that the board design meets all manufacturing parameters. For example, DDR rules will check whether the PCB contains any traces with differential impedances, which must be symmetrical.

By conducting a design rule check, engineers can determine whether the board meets the requirements of the customer. A design rule check can also help improve the manufacturability of a custom board. In modern PCB design, thousands of components and connections must be managed. Some boards may have multiple layers, so a design rule check is essential to ensure an acceptable manufacturing yield.

A DRC runs the design and layout together, allowing for a tight collaboration between the two. By doing so, designers can ensure the PCB meets the required design rules and avoid any unexpected SI, EMI, or safety violations. They can also modify tests to accommodate design requirements and minimize costly board failures. These improvements can increase the product time to market and maximize profitability.

Choosing materials

When it comes to choosing materials for your custom printed circuit boards, you need to take several factors into consideration, including the environment and application where your PCB will be used. You should also consider industry-specific standards and regulatory requirements. For example, you may need to comply with strict requirements relating to fire and heat safety. Choosing materials with the right properties will help you achieve the desired performance at an affordable price.

The material used for PCBs is crucial to the overall performance of your finished product. Different PCB materials have different electrical properties, which will determine their suitability for your particular application. For instance, if you’re designing a circuit board for high-frequency transmission, you need to choose a material with low thermal expansion (CTE) values.

The first step to choosing a material for your custom PCB is to understand how the circuit board is made. A PCB is made of two components, a substrate and a laminate. The substrate provides the structure and foundation of the circuit board, which includes the copper foil and other surface materials. Some boards also include a core material.

회로 기판은 어떤 역할을 하나요?

10월 6, 2022/0 코멘트/카테고리: 블로그 /작성자: [email protected]

회로 기판은 어떤 역할을 하나요?

There are many components and parts that make up a circuit board. This article will discuss the components and functions of printed circuit boards. It will also cover the layout of a circuit board. Once you have a basic understanding of these components and parts, you can better understand how circuit boards work. If you have any questions, please don’t hesitate to contact us! Our friendly staff is always happy to answer your questions! We hope this article will be helpful for you!

인쇄 회로 기판

Printed circuit boards are the backbone of most electronic devices, from cellphones to computers. These circuit boards are made of metal layers with conductive pathways between them. They’re usually made of layers etched separately and laminated together to create a pattern. Printed circuit boards also contain traces, which are the paths where signals travel through the board and carry information between different components.

These layers are created using special equipment called plotters. This machine creates photo films of the PCB and can achieve precise detail and high-quality printing. The plotter prints ink that resembles the different layers on the PCB. The substrate is usually made of glass fibre or epoxy resin. Next, copper is bonded to one or both sides of the panel. Once this is done, the photosensitive film is added to the panel.

기능

A circuit board is made of different components that work together to complete a specific function. The main components are capacitors, resistors, and transistors. These components allow electrical current to flow from a higher voltage to a lower voltage, ensuring that an appliance receives the proper amount of power.

구성 요소

One of the most important components on a circuit board is a transformer. Transforms electrical energy, allowing the circuit to function, by changing the voltage. These devices can have many different configurations and expert circuit designers often consider the process of voltage transformation when designing a circuit. A transformer typically consists of a metal core surrounded by a series of coils. One of these coils is known as the secondary coil, while the other is the primary coil.

Other PCB components include switches and relays. These devices are used to regulate and turn on and off power. One type of semiconductor switch is the Silicon Controlled Rectifier (SCR), which can control large amounts of power using a small input. Passive devices such as capacitors and resistors are also found on a PCB.

Layout

The layout of circuit boards is an important part of PCB design. This is a complex process that involves determining the placement of various components and holes on the board. There are many different types of circuit boards, including industrial ones and consumer electronics circuits. Although these types of circuit boards are mostly similar, the PCB layout designer must consider the specific requirements for each technology and the environment in which the boards will be used.

전자기 호환성

Electromagnetic compatibility (EMC) is an important concept when designing electronic circuitry. It deals with the problem of electromagnetic noise, which can interfere with the signals in a circuit. It is essential to consider EMC in the early design phase, as it can have a substantial impact on the finished product. The right PCB design can avoid EMC issues and ensure a system’s functionality.

Circuit boards should comply with EMC standards and guidelines to prevent electromagnetic interference from affecting their functionality. The most common EMC problems stem from improperly-designed circuits. They can result in incompatible signals interfering with each other and causing the circuit board to fail. This can be avoided by following EMC design principles, which should be outlined in the circuit design.

Durability

PCB 내구성은 전자 설계에서 중요한 고려 사항이며, 특히 PCB가 열악한 환경에 노출될 경우 더욱 그렇습니다. 예를 들어 산업용 PCB는 견고하고 내구성이 뛰어나야 할 수 있습니다. 또한 고온을 견뎌야 할 수도 있습니다. 산업용 PCB는 스루홀 기술과 같은 특수 조립 공정이 필요할 수도 있습니다. 산업용 PCB는 종종 전기 드릴 및 프레스와 같은 장비에 전원을 공급하는 데 사용됩니다. 다른 용도로는 DC-AC 전력 인버터 및 태양열 열병합 발전 장비가 있습니다.

패시브 부품과 장치를 통합하여 PCB 내구성을 향상시킬 수 있습니다. 펄스 내구성은 패시브 및 액티브 디바이스를 선택할 때 고려해야 할 가장 중요한 파라미터 중 하나입니다. 펄스 내구성은 최대 전력 손실과 펄스 서지 후 발생하는 저항 변화를 결정하는 데 도움이 됩니다. 이는 펄스 회로의 유용성을 결정하는 데도 도움이 될 수 있습니다. 회로 기판의 내구성을 향상시키기 위해 박막 저항기를 표면에 제작하거나 PCB에 내장할 수 있습니다. 한 가지 예로 FR-4 라미네이트의 니켈-인 합금을 들 수 있습니다. 시트 저항은 25 O/sq입니다.

안전

회로 기판은 모든 전자 기기의 중요한 구성 요소입니다. 회로 기판이 오작동하면 기기가 제대로 작동하지 않거나 심지어 완전히 고장날 수도 있습니다. 소비자 시장의 수요가 증가함에 따라 엔지니어들은 더 작고 효율적이며 유연한 회로 기판을 설계하기 위해 노력하고 있습니다. 또한 엄격한 시장 출시 기한을 준수해야 합니다. 이는 설계 실수로 이어져 제품의 평판에 해를 끼칠 수 있습니다.

작업장의 안전과 직원들의 적절한 교육이 중요합니다. PCB에 노출되면 눈과 피부 자극, 호흡기 자극 등 건강에 심각한 결과를 초래할 수 있습니다. 직원들은 호흡보호구와 장갑을 포함한 보호복을 착용해야 합니다. 또한 EPA 지침에 따라 유해 화학물질을 적절히 보관하고 폐기해야 합니다.