Month: March 2020

PCB Assembly Manufacturer Top Failure Analysis Techniques

PCB assembly manufacturer understands the importance of the Printed Circuit Board. They know that PCBs are a critical part of modern electronics. Incorporating good quality PCBs into machines will ensure the quality and reliability of the equipment.

Despite this, it is difficult to avoid Printed Circuit Board failures. The PCB failures are unique in one way or the other. However, analyzing these failures can help point towards the root cause. To ensure the quality and reliability of a Printed Circuit board, you use should some failure analysis techniques.

In the course of this article, we are going to discuss some common failure analysis techniques. These techniques will help you find the root cause of the failure. They will also ensure high quality and reliable Printed Circuit Boards.

Effective Failure Technique Analysis for PCB Assembly Manufacturer

Incorporating these techniques into the production process promises high-quality, robust and reliable Printed Circuit Boards.

Appearance Inspection

This is among the most common and easy techniques for inspecting the Printed Circuit Board. You would have to visually, inspect the Printed Circuit Board with or without instruments. Magnifying glasses, metallographic microscopes, and stereo microscopes are among the few analyzing instruments.

You use these instruments to check the appearance of the Printed Circuit boards. They help you determine the parts that are causing the failure and its physical evidence. These simple, yet effective instruments help find the failures as well as discover PCB’s failure mode.

With appearance inspection, you can check the location of the explosion board, along with corrosion and pollution. In addition, the manufacturer checks the regularity of the failure along with the circuit wiring with a visual inspection.

Manufacturers often discover certain PCB failures after the PCB is assembled into a PCBA. These failures can be due to bad assembling process or due to the material. Therefore, it is imminent to carefully, inspect the material.

X-ray Fluoroscopy – PCB Assembly Manufacturer

X-ray Fluoroscopy is an excellent way to determine internal defects. Something, you might not be able to find using the visual inspection. For instance, you need to use X-ray Fluoroscopy to determine the defects of a PCB’s through holes.

X-ray Fluoroscopy technique uses different materials with different densities and thickness to absorb X-rays. It uses different principals to transmit light. In order to inspect the defects that are inside the PCB, X-ray Fluoroscopy is a good option.

It helps you find failure inside the through-holes, PCBA solder joints and the defective solder joints positioning. Initially, the X-ray Fluoroscopy used only two-dimensional imaging equipment. However, advancement has led to three-dimensional imaging and X-ray Fluoroscopy can reach below one micron.

Manufacturers now have the option of 5D equipment for packaging inspection. Nevertheless, these 5D X-ray Fluoroscopy are not only expensive, but they also have limited use in the industry. Due to these factors, they are not a good investment.

Slice Analysis

Another great PCB failure analysis technique is the Slice Analysis. Slice analysis provides you with rich and accurate information about the microstructure of the Printed Circuit Board. With Slice analysis can you gather information about the cross-section structure of a PCB.

You would use a series of methods including observation, corrosion, polishing, slicing, inlaying, and sampling to gather information. This information would act as a base to determine the quality of the next batch of PCB.

Although the method provides accurate information, yet it is destructive. After sectioning the sample, you cannot use it. You will have to destroy the sample. In addition, the techniques demand high and extensive sample preparation. These preparations take a lot of time, effort and energy. You would even need a trained technician to, successfully complete the inspection.

Scanning Acoustic Microscope

For assembly analysis and electronic packaging, PCB assembly manufacturers use an ultrasonic scanning acoustic microscope (C mode). To image the polarity, phase, and the amplitudes changes, the ultrasonic scanning equipment uses ultrasonic reflection with high frequency.

You will find the information along the XY plane and the Z-axis shows the scanning method. Thus, it is possible to determine several components and material defects using this technique. Some of the common defects include voids, inclusions, delamination, and cracks.

With sufficient width of the scanning acoustics, it is possible to determine the internal defects of the solder joints. To indicate the existence of defects, the acoustic image appearance in red instead of the usual color.

Microscopic Infrared Analysis

With microscopic infrared analysis, you can effortlessly analyze the compound composition of the material. The technique combines a microscope with an infrared spectrum. To analyze the composition, it uses infrared’s different absorption principles by different materials.

Mostly, the materials are organic substances. You can find the infinitesimal organic pollution using microscopic infrared analysis. After all, the technique combines the visible light of the microscope with infrared light within the visible field of the view.

In case, you do not combine a microscope with infrared technology, it will not be able to generate greater results. You can use the Infrared spectrum without a microscope for analyzing large sample volumes.

It is almost impossible to determine the trace pollution of a PCB. The trace pollution leads to poor solderability of the Printed Circuit Board. However, with the infrared spectrum of the microscope, you can resolve this problem.

Micro-infrared analysis’s main objective is to the cause of poor solderability and corrosion. It also focuses on finding and analyzing the surface of the joint or the organic pollutants of the welded surface.

Scanning Electron Microscope

SEM or formally known as the scanning electron microscope is the most useful and commonly used technique for conducting failure analysis. It basically is a large-scale electron microscopy imaging system. The technique offers a wealth of information regarding the Printed Circuit Boards.

It uses the anode to accelerate the beam emitted by the cathode. It then uses a magnetic lens to focus and form a beam with a diameter of several tens. The beams help creates a point-by-point scanning movement. Thus, helping you gather rich and accurate information about the Printed Circuit Board.

The technique is effective in analyzing the mechanical failure of the Printed Circuit Board or the Solder joints. It is highly efficient when it comes to analyzing the solder joint’s metallographic structure. In addition, it observes the solderable coating, measurement of intermetallic, and the surface pads’ morphology. It can even help find failure with the measurement of the tin whisker.

With SEM, you will not get a colorful image. On the contrary, the analysis technique generates a black and white image. Also, ensure that the sample of the SEM should be conductive. In case, it non-conductive, you will have to spray some carbon or gold. The same holds true for certain semiconductors.

In case, you fail to do the spray, the technique will not generate accurate results. The reason being, the accumulation of charge on the sample surface has an adverse effect on the sample observation. Moreover, the SEM image has a greater depth of field in comparison to the optical image.

Something that further enhances its outcome and overall analysis. SEM is an excellent and effective technique for uneven samples including tin whisker, microfracture and metallographic.

X-Ray Energy Spectrum

X-Ray Energy Spectrum is another excellent analysis technique that major PCB assembly manufacturer incorporate. It generates accurate and authentic information effortlessly.  The method incorporates different scanning methods of the electron beam. Thus, it has the capability to perform surface point analysis along with surface and line analysis.

It can also gather information on a number of element distributions. The line analysis performs analysis of elements present on the specified line at one time. Similarly, to get all elements of a point, use the point analysis. Lastly, the surface analysis focuses on analyzing the elements that are present on a specific surface.

Photoelectron Spectroscopy XPS

In order to perform not only quantitative but also qualitative analysis of the sample surface, XPS is an excellent choice. It can conduct in-depth analysis of the shallow surface elements. Likewise, you can gather information regarding the element’s chemical valence. This information is based on the chemical shift of the binding energy.

With XPS, you can gather information regarding the surface layer’s atomic valence as well as its surrounding elements. It is possible to perform the analysis of the insulating sample without causing any sort of damage to the sample.

You can perform multiple layers of longitudinal element distribution analysis in the case of argon ion peeling. In addition,  XPS allows rapid multi-element analysis as well. In short, the photoelectron spectroscopy is excellent for performing the analysis of the contamination as well as the quality of the pad coating. It is also effective for performing the oxidation degree analysis. It will help find the root cause of poor solderability.

Takeaway

PCB assembly manufacturer have been incorporating these failure analysis techniques to ensure the highest quality and reliable Printed Circuit Boards. Every analysis technique is different and is used for finding different problems.

A good manufacturer such as the KingPCB uses most of these techniques to ensure the highest quality printed circuit boards. They understand that failure in the PCB would lead to the failure of your product. Thus, they deliver only the highest quality Printed Circuit Boards.

Flexible PCB Manufacture: Simple Analysis of the Manufacturing Process

Flexible PCB manufacturers understand that modern technology requires enhanced and sophisticated Printed Circuit boards. Therefore, they are investing immense time in designing and developing state of the art Printed Circuit Boards.

The modern technology demands the continuous expansion of Flexible PCB. Over the years, we have seen tremendous growth in terms of flexible PCB application scope and application field. In addition, the prospect of development of both national and international markets further enhances its importance.

It seems that in no time, Flexible Printed Circuit boards will be as important complex and complicated as the rigid printed boards. There will be a significant improvement in terms of structure, types, verities, and grades.

In the course of this article, we are going to present you with a simple analysis of the flexible Printed Circuit Board’s manufacturing process. So, without any further delays, let us get straight to it.

Manufacturing Process of Flexible Printed Circuit Board

The picture below shows the manufacturing process of Multilayer FLEX-PCB along with the Common Double-Side Flex Printed Circuit Board.

Blanking: Material Preparation – Flexible PCB Manufacturer

The first step in the manufacturing process is the preparation of the material, blanking. This step mainly includes reinforcing pate, cladding layer, and flexible copper clad laminate. Likewise, the separation of the main auxiliary materials that the manufacturer uses for lamination takes place in this step.

Then comes silicon rubber plate, or conformal material, absorption of the in, coated paper among others.

Drilling –  Flexible PCB Manufacturer

Drilling requires attention and effort. Regardless of the material, may it be cladding layer or the copper-clad laminate, It is difficult to drill them. Yes, they are soft and thin, yet accurate drilling is challenging.

A good idea is to stack boards before you drill. You stack-up multiple pieces of copper clad laminate or cladding layer before you drill them. Put them on top of each as you would put the books.

Pitting and Desmear –  Flexible PCB Manufacturer

After the drilling process, some sort of dirt might accumulate in the PCB holes. Thus, you need to clean these holes properly. To ensure the quality of the plated-through role, it is imperative to keep the holes completely dust-free.

For the double-sided copper-clad laminate, it is critical to do the desmear and pitting. Only after that should you carry out the PTH.

PTH and Pattern Platting

First comes then desmear and pitting, then you have the electroless plating, after then comes electrical plating, imaging and finally pattern plating.

 

Electroless Plating

Electroless Plating pretreatment solution should be alkaline ionic palladium instead of the acidic colloid palladium. The alkaline would generate better and more refined results.

Also, the important thing here is to ensure that both speed and the reaction time needs to be kept in check. Make sure that the is not very fast nor is it takes too long for the reaction time. In case both of these factors do not have a balance, it will lead to multiple holes. Thus, the flexible PCB manufacturers will end up with the copper layer’s poor mechanical properties.

 Electrical Plating: Flexible PCB Manufacturer

If the flexible PCB ends up with poor mechanical properties, for instance, the ductility, it will not offer robustness. The electroless copper plating layer might not be able to withstand the thermal shock and it will end up being broke or damaged.

So, a good rule of thumb is to carry out the electrical plating immediately after the copper plating layer reaches up to 0.3~0.5um. When you instantly carry out the electrical plating, it would thicken the entire panel to 3-4um. Thus, it will make the hole sturdy and strong. The integrity of the holes will remain intact in the proceeding processing steps.

 

Pre-cleaning and Imaging

Pre-cleaning is a prerequisite for the imaging. The flexible PCB manufacturer ensures that a proper cleaning takes place before they go on imaging the Printed Circuit Board.

There is no difference between the pre-cleaning process of the rigid PCB and the Flexible PCB. One of the major reasons for using electrolytic cleaning process or chemical cleaning process for a flexible substrate is because it easily bends and deforms.

The process also uses either the special pumice stone paint or manual pumice board machine Another thing that is similar to the right PCB is the process of exposure and developing along with the process of sticking the dry film.

Once the polymerization reaction takes place, there is a visible difference between the then binding force of the copper foil. The dry film becomes brittle due to developing and this results in the decrease of copper foil’s binding force. Thus, after developing the dry film becomes more focused on the prevention of it from peeling and warping.

Etching – Flexible PCB Manufacturer

The flexible substrates tend to have several long parallel wires at their bend. It is imperative to pay close heed to the spraying direction of the etching solution. After all, this is going to have a direct impact on the consistency of etching.

In addition to the spraying direction, the manufacturer needs to pay heed to the pressure along with the position of the PCB. PCB’s transmission direction also holds great importance. You need to consider all these factors during the etching process.

Another important thing is to attach a rigid substrate in front of the flexible substrate in order to full the substrate forward. To ensure better and efficient results, use the fluid automatic regeneration system for the etching of Flexible Printed Circuit Boards.

Cladding Layer Positioning

Before the cladding layer positioning becomes, it is necessary for the PCB to do the surface treatment. After etching, the binding force needs to be reinstated for the success of the cladding layer positioning.

There is a difference between the amount of moisture the flexible PCB can absorb after etching and the cladding layer after drilling. Thus, to make sure that both these materials have the same absorption level, they need to be baked for 24 hours in the drying oven.

After they are fully dried, the next step is to laminate them. In addition, the flexible PCB manufacturer should ensure that the stack height does not exceed 25mm.

Lamination

Next is lamination, it is also an important and critical step in the manufacturing of the flexible Printed Circuit Board.

Cladding Layer Lamination

The heating time, lamination time, pressure along with the value of other parameters greatly depends upon the type of flexible substrate that you use. Different flexible substrates have different values of parameters.

Below are the basic parameters of the process

• Upper Template
• Separating Film Matera
• Blotting Coated paper or paper
• Separating Film Material
• Cladding material
• Separating Film Material
• Workpiece
• Separating Film Material
• Cladding material
• Separating Film Material
• Blotting Coated paper or paper
• Separating Film Material
• Bottom Template

 

Key Points: Lamination time is basically the net pressure time. It should be 60 minutes under full pressure. Similarly, for the heating rate, the temperature should rise from room temperature to 173℃ in just ten or twenty minutes. The pressure should take about 5 to 8 seconds to reach 150N-300N/cm².

Gasket Material

To ensure high-quality lamination, the flexible PCB manufacturer often chooses the gasket material. It is no doubt an excellent material. However, you need to ensure that the gasket material itself is of fine quality. It should have low fluidity, good formability, and a good cooling process.

It should not shrink, and there is no deformation. After all, the occurrence of deformation leads to bubbles in the material during the lamination. Both rigid, as well as the flexible system, contains the Gasket materials. For instance, the rigid system majorly comprises of glass cloth. To, further enhance its useability, the glass cloth is then reinforced using a good quality silicon rubber.

Flexible system on the other end includes the radiation polyethylene film or the PVC film. It also contains thermoplastic materials.

Baking Flexible PCB Manufacturer

To ensure that no moisture is left, the manufacturer needs to bake everything completely. The right time of baking will remove all the moisture.

Hot melting or HASL

To prevent the welting of the Printed Circuit board, it is imperative to carry out the hot melting or the HASL process right after the drying of PCB. If there is any delay, it can lead to a decrease in the quality of the Printed Circuit Board.

Sharp Processing

Usually, sharp processing takes place in the mass production of PCBs. For Flexible Printed Circuit Board Sharping processing is the seamless use of precision steel dyes. It can be either a multi-cavity mold or the manufacturer can use a mold a cavity.

Packing and shipping

The Flexible PCB manufacturer uses the vacuum packaging machine for the right and correct packing of flex-PCB. To extend the storage time, add a desiccant to the vacuum packaging bag. There are several ways to ship flexible Printed Circuit Boards. However, it majorly depends upon the manufacturer.

For instance, KingPCB, a leading PCB manufacturer, tends to offer several methods of shipping including DHL, FedEx and many more. You can reach out to them and they will deliver the highest quality Printed Circuit Boards at your doorstep.