1.2mm pcb

For over two decades, MTI has been dedicated to providing comprehensive OEM/ODM manufacturing services to customers worldwide. With our extensive expertise in PCB assembly, we have established strong collaborative relationships with authorized component distributors. This allows us to source any required components at competitive prices, ensuring cost-effectiveness for our clients.

Product name 1.2mm pcb
Keyword 10 layer pcb fabrication,1.6mm pcb stackup,2.4 ghz pcb antenna design,pcb fab,16 layer pcb stackup
Place of Origin China
Board Thickness 2~3.2mm
Applicable Industries consumer electronics, etc.
Service OEM/ODM manufacturing
Certificate ISO-9001:2015, ISO-14001:2015,ISO-13485:2012.UL/CSA
Solder Mask Color Red
Advantage We keep good quality and competitive price to ensure our customers benefit
Sales country All over the world for example:Guam,Liechtenstein,Uzbekistan,Svalbard,Qatar,Trinidad and Tobago

 

One of our Hardware Design Services is small-batch manufacturing, which allows you to test your idea quickly and verify the functionality of the hardware design and PCB board.

Your deliverables are always ahead of schedule and of the highest quality.

We have rich experience engineer to create a layout using a software platform like Altium Designer. This layout shows you the exact appearance and placement of the components on your board.

FAQs Guide

1.Can PCBs have multiple power planes?

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Yes, PCBs can have multiple power planes. Power planes are layers of copper on a PCB that are used to distribute power and ground signals throughout the board. Multiple power planes can be used to provide different voltages or to separate sensitive analog signals from noisy digital signals. They can also be used to increase the current carrying capacity of the board. The number and arrangement of power planes on a PCB will depend on the specific design requirements and can vary greatly.

2.What is the minimum distance required between components on a PCB?

We have advanced production equipment and technology to meet the needs of customers, and can provide customers with high quality, low priced 1.2mm pcb products.
The minimum distance required between components on a PCB depends on various factors such as the type of components, their size, and the manufacturing process used. Generally, the minimum distance between components is determined by the manufacturer’s design rules and guidelines.

For surface mount components, the minimum distance between components is typically 0.2mm to 0.3mm. This distance is necessary to ensure that the solder paste does not bridge between the pads during the reflow process.

For through-hole components, the minimum distance between components is typically 1mm to 2mm. This distance is necessary to ensure that the components do not interfere with each other during the assembly process.

In high-speed and high-frequency applications, the minimum distance between components may need to be increased to avoid signal interference and crosstalk. In these cases, the manufacturer’s design rules and guidelines should be followed closely.

Overall, the minimum distance between components on a PCB should be determined based on the specific requirements of the design and the capabilities of the manufacturing process.

3.How do PCBs support the integration of different electronic components?

We actively participate in the 1.2mm pcb industry associations and organization activities. The corporate social responsibility performed well, and the focus of brand building and promotion.
PCBs (Printed Circuit Boards) are essential for the integration of different electronic components in electronic devices. They provide a platform for connecting and supporting the various components, allowing them to work together seamlessly. Here are some ways in which PCBs support the integration of different electronic components:

1. Electrical connections: PCBs have a network of copper traces that connect the different electronic components on the board. These traces act as conductors, allowing electricity to flow between the components and enabling them to communicate and work together.

2. Mounting surface: PCBs provide a stable and secure mounting surface for electronic components. The components are soldered onto the board, ensuring that they are firmly attached and will not move or become loose during operation.

3. Space-saving: PCBs are designed to be compact and space-saving, allowing for the integration of multiple components on a single board. This is especially useful in small electronic devices where space is limited.

4. Customization: PCBs can be customized to accommodate different types and sizes of electronic components. This allows for flexibility in design and the integration of a wide range of components, making it easier to create complex electronic devices.

5. Signal routing: PCBs have multiple layers, with each layer dedicated to a specific function. This allows for efficient routing of signals between components, reducing interference and ensuring that the components can communicate effectively.

6. Power distribution: PCBs have dedicated power planes that distribute power to the different components on the board. This ensures that each component receives the required amount of power, preventing damage and ensuring proper functioning.

7. Thermal management: PCBs also play a crucial role in managing the heat generated by electronic components. They have copper layers that act as heat sinks, dissipating heat and preventing the components from overheating.

In summary, PCBs provide a robust and efficient platform for integrating different electronic components. They enable the components to work together seamlessly, ensuring the proper functioning of electronic devices.

4.What are the different types of through-hole mounting techniques used in PCBs?

We have flexible production capacity. Whether you are large orders or small orders, you can produce and release goods in a timely manner to meet customer needs.
1. Through-Hole Plating: This is the most common through-hole mounting technique, where the holes in the PCB are plated with a conductive material, usually copper, to create a connection between the layers of the board.

2. Through-Hole Soldering: In this technique, the components are inserted into the plated holes and then soldered to the pads on the opposite side of the board. This provides a strong mechanical connection and good electrical conductivity.

3. Through-Hole Riveting: In this method, the components are inserted into the plated holes and then secured with a rivet or pin. This is commonly used for high-power components or in applications where the board may experience high levels of vibration.

4. Through-Hole Press-Fit: This technique involves inserting the component leads into the plated holes and then pressing them into place using a specialized tool. This provides a strong mechanical connection without the need for soldering.

5. Through-Hole Wave Soldering: In this method, the components are inserted into the plated holes and then passed over a wave of molten solder, which creates a strong solder joint between the component leads and the PCB pads.

6. Through-Hole Reflow Soldering: This technique is similar to wave soldering, but instead of passing over a wave of molten solder, the board is heated in a controlled environment to melt the solder and create a strong joint.

7. Through-Hole Hand Soldering: This is a manual method of soldering where the components are inserted into the plated holes and then soldered by hand using a soldering iron. This is commonly used for small-scale production or for repairs.

8. Through-Hole Pin-in-Paste: This technique involves inserting the component leads into the plated holes and then applying solder paste to the holes before reflow soldering. This provides a strong mechanical connection and good solder joints.

9. Through-Hole Pin-in-Hole: In this method, the component leads are inserted into the plated holes and then bent to form a right angle, creating a secure mechanical connection. This is commonly used for components with large leads, such as electrolytic capacitors.

10. Through-Hole Hand Assembly: This is a manual method of assembly where the components are inserted into the plated holes and then secured with hand tools, such as screws or nuts. This is commonly used for large or heavy components that require additional support.

5.What are the key features of a PCB?

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1. Substrate: The base material on which the circuit is printed, usually made of fiberglass or composite epoxy.

2. Conductive Traces: Thin copper lines that connect the components on the PCB.

3. Pads: Small copper areas on the PCB surface where components are soldered.

4. Vias: Holes drilled through the PCB to connect the different layers of the circuit.

5. Solder Mask: A layer of protective material that covers the copper traces and pads, preventing accidental short circuits.

6. Silkscreen: A layer of ink that is printed on the PCB to label the components and provide other useful information.

7. Components: Electronic devices such as resistors, capacitors, and integrated circuits that are mounted on the PCB.

8. Mounting Holes: Holes drilled on the PCB to allow it to be securely attached to a larger device or enclosure.

9. Copper Pour: Large areas of copper that are used to provide a common ground or power plane for the circuit.

10. Edge Connectors: Metal contacts on the edge of the PCB that allow it to be connected to other circuits or devices.

11. Solder Bridges: Small areas of exposed copper that allow for the connection of two or more traces.

12. Test Points: Small pads or holes on the PCB that allow for testing and troubleshooting of the circuit.

13. Silkscreen Legend: Printed text or symbols on the silkscreen layer that provide additional information about the PCB and its components.

14. Designators: Letters or numbers printed on the silkscreen layer to identify specific components on the PCB.

15. Reference Designators: A combination of letters and numbers that identify the location of a component on the PCB according to the schematic diagram.

What are the key features of a PCB?

6.How does the type of PCB connection (wired or wireless) impact its design and features?

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The type of PCB connection, whether wired or wireless, can have a significant impact on the design and features of the PCB. Some of the key ways in which the type of connection can impact the PCB design and features are:

1. Size and form factor: Wired PCBs typically require physical connectors and cables, which can add to the overall size and form factor of the PCB. On the other hand, wireless PCBs do not require physical connectors and cables, allowing for a smaller and more compact design.

2. Power consumption: Wired PCBs require a constant supply of power to function, whereas wireless PCBs can operate on battery power. This can impact the power consumption and battery life of the device, which in turn can affect the overall design and features of the PCB.

3. Flexibility and mobility: Wireless PCBs offer greater flexibility and mobility as they do not have physical connections that restrict movement. This can be advantageous in applications where the device needs to be moved or used in different locations.

4. Data transfer speed: Wired PCBs typically have faster data transfer speeds compared to wireless PCBs. This can impact the design and features of the PCB, as certain applications may require high-speed data transfer.

5. Cost: The type of connection can also impact the cost of the PCB. Wired PCBs may require additional components such as connectors and cables, which can add to the overall cost. Wireless PCBs, on the other hand, may require more advanced technology and components, making them more expensive.

6. Reliability: Wired PCBs are generally considered more reliable as they have a physical connection, which is less prone to interference or signal loss. Wireless PCBs, on the other hand, may be more susceptible to interference and signal loss, which can impact their reliability.

Overall, the type of PCB connection can significantly impact the design and features of the PCB, and it is important to carefully consider the specific requirements of the application when choosing between wired and wireless connections.

7.How does the type of solder mask used affect the PCB’s performance?

We have broad development space in domestic and foreign markets. 1.2mm pcbs have great advantages in terms of price, quality, and delivery date.
The type of solder mask used can affect the PCB’s performance in several ways:

1. Insulation: Solder mask is used to insulate the copper traces on a PCB, preventing them from coming into contact with each other and causing a short circuit. The type of solder mask used can affect the level of insulation provided, which can impact the overall reliability and functionality of the PCB.

2. Solderability: Solder mask also plays a crucial role in the soldering process. The type of solder mask used can affect the surface tension and wetting properties of the solder, which can impact the quality of the solder joints and the overall reliability of the PCB.

3. Thermal resistance: Solder mask can also act as a thermal barrier, protecting the PCB from excessive heat. The type of solder mask used can affect the thermal resistance of the PCB, which can impact its ability to dissipate heat and its overall thermal performance.

4. Chemical resistance: Solder mask is also exposed to various chemicals during the PCB manufacturing process, such as flux and cleaning agents. The type of solder mask used can affect its resistance to these chemicals, which can impact the overall durability and reliability of the PCB.

5. Electrical properties: The type of solder mask used can also affect the electrical properties of the PCB, such as its dielectric constant and dissipation factor. These properties can impact the performance of high-frequency circuits and signal integrity.

Overall, the type of solder mask used can have a significant impact on the performance, reliability, and durability of a PCB. It is essential to carefully select the appropriate solder mask for a specific application to ensure optimal performance.

8.What are the factors to consider when choosing the right PCB material for a specific application?

We are centered on customers and always pay attention to customers’ needs for 1.2mm pcb products.
1. Electrical properties: The electrical properties of the PCB material, such as dielectric constant, loss tangent, and insulation resistance, should be carefully considered to ensure optimal performance for the specific application.

2. Thermal properties: The thermal conductivity and coefficient of thermal expansion of the PCB material are important factors to consider, especially for applications that require high power or operate in extreme temperatures.

3. Mechanical properties: The mechanical strength, stiffness, and flexibility of the PCB material should be evaluated to ensure it can withstand the physical stresses and strains of the application.

4. Chemical resistance: The PCB material should be resistant to any chemicals or solvents that it may come into contact with during its use.

5. Cost: The cost of the PCB material should be considered, as it can vary significantly depending on the type and quality of the material.

6. Availability: Some PCB materials may be more readily available than others, which can affect production timelines and costs.

7. Manufacturing process: The chosen PCB material should be compatible with the manufacturing process, such as etching, drilling, and plating, to ensure efficient and reliable production.

8. Environmental factors: The application environment, such as humidity, moisture, and exposure to UV light, should be taken into account when selecting a PCB material to ensure it can withstand these conditions.

9. Signal integrity: For high-frequency applications, the PCB material should have low signal loss and good signal integrity to prevent interference and ensure accurate signal transmission.

10. RoHS compliance: If the application requires compliance with environmental regulations, such as the Restriction of Hazardous Substances (RoHS) directive, the PCB material should be chosen accordingly.

 

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