Stencil printing

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Stencil printing is the process of depositing solder paste on the printed wiring boards (PWBs) to establish electrical connections. It is immediately followed by the component placement stage. The equipment and materials used in this stage are stencil, solder paste, and a printer.

The stencil printing function is achieved through a single material namely solder paste which consists of solder metal and flux. Paste also acts as an adhesive during component placement and solder reflow. The tackiness of the paste enables the components to stay in place. A good solder joint is one where the solder paste has melted well and flowed and wetted the lead or termination on the component and the pad on the board.

In order to achieve this kind of a solder joint, the component needs to be in the right place, the right volume of solder paste needs to be applied, the paste needs to wet well on the board and component, and there needs to be a residue that is either safe to leave on the board or one that can easily be cleaned.

The solder volume is a function of the stencil, the printing process and equipment, solder powder, and rheology or the physical properties of the paste. Good solder wetting is a function of the flux.

Printing process[edit]

The process begins with loading the board into the printer. The internal vision system aligns the stencil to the board, after which the squeegee prints the solder paste. The stencil and board are then separated and unloaded. The bottom of the stencil is wiped about every ten prints to remove excess solder paste remaining on the stencil.

A typical printing operation has a speed of around 15 to 45 seconds per board. Print head speed is typically 1 to 8 inches per second. The printing process must be carefully controlled. Misalignment of motion from the reference results in several defects, hence the board must be secured correctly before the process begins. A snugger and vacuum holders are used to secure the X and Y axes of the board. Vacuum holders must be carefully used, as they may affect the pin-in-paste printing process if not secured properly.

The longest process is the printing operation, followed by the separation process. Post print inspection is crucial and is usually performed with special 2D vision systems on the printer or separate 3D systems.

Inputs[edit]

Inputs to the process can be classified as: Design Input, Material Input, Process parameter Input. The output of the process is a printed wiring board that meets the process specification limits. These specifications usually are consistent solder paste volume and height, and printed solder paste aligned on the PWB pads. This determines the process yield.

Printed wiring boards[edit]

Design[edit]

Vision systems in the stencil printing machines use global fiducial marks for aligning the PWB. Without these fiducials the printer would not print the solder paste in exact alignment with the pads. The PWB should have close dimensional tolerances so that it mates to the stencil. This is necessary to achieve the required alignment of solder blocks on the pads.

Masking[edit]

The required accuracy in alignment can also be achieved by controlling the flow of solder on the PWB during reflow soldering. For this purpose, the space between the pads is often coated with a solder mask. The solder mask materials have no affinity to the molten solder and hence, no positive bonding is formed between them as the solder solidifies. This process is often referred to as Solder Masking. The mask must be centered correctly. The mask protects the PWB against oxidation, and prevents unintended solder bridges from forming between closely spaced solder pads.

Also the height of the solder mask should be lower than the pad height to avoid gasketing problems as shown. If the height of the solder mask is greater than that of the pad, then some of the solder paste would settle in the empty space between the mask and the pad. This is what is referred to as gasketing. It is a seal that fills the space between two surfaces to prevent leakages. However, in this case, the gasketing is a problem as the excess solder paste around the pad may be more than a nuisance factor for circuits having very small line spacing.

As shown in the adjoining figure, if the height of the mask is greater than the pad, it could create the flow of solder paste around the pad.

Finishing[edit]

The pads on the PWB are made of Copper and are susceptible to oxidization. Surface oxidization on the Copper will inhibit the ability of the solder to form a reliable joint. To avoid this unwanted effect, all exposed Copper is protected with a Surface Finish.

Aperture fill and release[edit]

The core of a well printed PWB lies in the fill and release of solder paste into the aperture. When the stencil is in contact with the PWB, solder paste is applied over the top surface of the stencil using a squeegee. This causes the aperture to fill with solder paste. The PWB is then lowered from the stencil. The amount of solder paste which is released from the stencil apertures and transferred to the PWB pads, determines whether or not the print is good. Ideally, all volumes of solder paste should be equal to the volume of the corresponding stencil aperture. In reality however, this is never the case. Hence, a print is considered to be good if a certain fraction of the paste is released. One way of quantifying print performance is to calculate the Transfer Efficiency. This is mathematically stated as:

Transfer Efficiency=(Volume of printed deposit)/(Theoretical maximum volume)

In the above expression, the Theoretical maximum volume is simply the open volume of the stencil aperture. Ideally, a transfer efficiency of 1 is desired. In reality however, greater the transfer efficiency, better is the print. Now in order to get the aperture full of paste requires sufficient flow rate and sufficient fill time. Apertures which are not completely filled will not release paste onto the board, which results in clogged stencils and defective solder joints. Solder paste release is determined by the separation speed of the board from the stencil. The adhesion of the paste to the board has to provide the shearing force to overcome the adhesion of the paste to the stencil walls. This hydrodynamic shearing force depends on the separation speed.

Stencils[edit]

Stencils are used to print solder paste on the PCB. They are often made of Stainless Steel or Nickel and are manufactured by different processes described below.

Manufacturing processes[edit]

Laser cutting[edit]

The use of laser technology allows having tighter tolerances and greater accuracy.

The aperture walls can be smoothed through electro-polishing and/or nickel plating. The laser cutting process results in trapezoidal apertures that can create better solder paste release characteristics.

The repeatability of dimensions in laser-cut stencils is generally better than that of chemical etching. With laser cutting, there are no photo films requiring precise alignment or protection from moisture.

E-FAB stencil[edit]

This stencil is formed by the process of electroforming nickel. Hence the name E-FAB. The nickel has better wear characteristics than steel and electroforming creates smooth tapered aperture walls. The process also creates a ridge along the bottom of the stencil that can improve stencil-to-board gasketing and result in more consistent solder paste release.

Stencil design[edit]

Due to the need for fine pitch components, as the size of the aperture becomes smaller and smaller, they become “tall-narrow” apertures. In such cases, the apertures may be filled with solder paste but not completely released, or sometimes not even completely filled and hence get no deposits. In order to counter this problem, aperture walls are made as smooth as possible. Also, molecular layer nano coatings are put on the stencil walls so that the solder paste does not stick. Consistent fill and release is the most important output of stencil printing. When the stencil is down on the board, paste is filling the aperture and it’s in contact with the pad and walls of the stencil. The contact is judged by taking the ratio of these areas i.e. the ratio of the area of the pad to the area of the walls. This is called Area Ratio. The information about the standards for stencil design is available at IPC Specification 7525 and other standards. In general including stencils with tall and narrow apertures, an area ratio greater than 0.66 is recommended.

Illustrations of the various dimensions are provided in the table below:

Pitch Pad Width Aperture Stencil Thickness Aspect Ratio
25 15 12 6 2.0
20 12 9 - 10 5 - 6 1.7
15 10 7 - 8 5 1.4
12 8 5 - 6 4 - 5 1.2

For fine pitch stencils (<20 mils pitch, 10 mils aperture), even with a 5 mils stencil which is the most commonly used stencil thickness, the area ratio is below 1.5. This necessitates the use of a thinner stencil. For BGA/CSP and other very small Apertures, the Area Ratio is used. It should be greater than 0.66, as this ensures a high probability of good fill and release. An area ratio below 0.66 would mean a much less reliable process.

Examples of area ratios for BGAs are shown in the table below:

BGA Pad Aperture Thickness Area Ratio
60 mil 32 30 6 - 8 1.25 - 0.94
50 mil 25 22 6 - 8 0.92 - 0.69
20 mil 12 10 5 - 6 0.50 - 0.42

Aperture size should be smaller than the pad size to avoid the excess solder paste or production of solder balls. A 10-20% reduction in aperture size as compared to the pad size is typical to minimize solder balls. Solder balls can result in malfunctioning of the electric circuit.

Example:

  • A 6 mil stencil is to be designed for 20 mil pitch QFPs and 60 mil BGA.
  • (a) What is the pad and aperture width you would propose for the QFPs? What is the aspect ratio?
  • (b) What diameter would you propose for the pads and apertures for the BGA? What is the area ratio?
  • (a) Pad Width = 12 mils; Aperture Width = 10 mils (based on the first table)
  • Aspect Ratio = w/t = 10/6 = 1.67
  • (b) Pad Diameter = 32 mils; Aperture Diameter = 30 mils; Area Ratio = D/4t = 30/24 = 1.25

Other considerations[edit]

Step down stencils[edit]

A PCB may need varying amounts of solder paste to be applied depending upon the design and size of components. Applying a uniform maximum level of solder may not be a good solution in this case, as these stencils often find use when "pin and paste" technology (i.e., printing solder paste into through-holes to avoid wave soldering) and components of significantly different pitch are used in the same PWB. For this purpose, to achieve a varying solder amount, step down stencils are used.

Solder paste stencil life[edit]

Ideally, a solder paste should have, at minimum, a 4-hour stencil life. The stencil life is defined as a time period in which there will be no significant change in the solder paste material characteristics. A solder paste with a longer stencil life will be more robust in the printing process. Actual stencil life for a paste should be determined from the manufacturers' specifications and on-site verification.

Handling and storage of stencils[edit]

Some general guidelines for stencil handling are mentioned below. They are particularly useful for improved life and better performance of stencils.

  1. Clean stencils after use, remove any solder paste on them or within the apertures.
  2. Store the clean stencils in a designated area. They should not be left out, as they are more likely to be damaged.
  3. Inspect stencils for wear or damage before using them.
  4. Identify stencils with job numbers. This reduce the mishandling or misplacing of stencils.
  5. Before printing the solder paste on pcb, need to place nitto tape on pcb for trial purpose.

Squeegee[edit]

Squeegees are used to spread solder over the stencil and to fill all apertures consistently. Squeegees come in two different types, namely Metal and Polyurethane. Metal squeegees are preferred over polyurethane[citation needed] and they should be used if possible. They produce very consistent solder volumes and are resistant to scooping the solder paste out of the apertures when printing. In addition, they have better wear characteristics, leading to longer life.

Handling and storage[edit]

The general guidelines for improved life of squeegees are:

  1. Clean squeegee after use
  2. After cleaning, store them in designated areas
  3. Inspect for wear and any other damage before use every time

Common difficulties[edit]

Insufficient solder paste[edit]

Insufficient solder paste may cause poor bonds and contact between components and the board. The common causes of insufficient solder paste are poor gasketing, clogged stencil apertures, insufficient solder paste bead size, paste/stencil being used beyond recommended life span, stencil not wiped clean, or low squeegee pressure.

Smudging/bridging[edit]

The main causes of smudging/bridging are excessive squeegee pressure, inadequate stencil wiping, poor contact between the board and stencil, high temperature or humidity, or low solder paste viscosity.

Misalignment print[edit]

A typical misalignment print is usually caused by the vision system not spotting fiducials, PWB or stencil stretch, poor contact between the board and the stencil, or weak board support.

Statistical process control[edit]

More than 50% of defects in electronics assembly are due to solder paste printing problems. There are many parameters involved in this process, making it difficult to find the specific problem and to optimize the process. A careful statistical study of the process may be used to improve output significantly. The number of opportunities for a defect characterizes defects, not the actual number of defective parts.

Example:

If solder paste is printed on pads for a 68-pin QFP, then
Total Number of Opportunities for Defects= 68 pins + 1 for the component = 69 possible defects for printing only

Hence, there are 69 opportunities for defects to produce one defective component. Counting the defect opportunities is the most valid process monitor. Processes are typically rated in terms of number of defects per million opportunities (DPM). As an example, a process resulting in 100 defects when given 1 million defect opportunities would have a rating of 100 DPM. World class printing processes have defect levels around 20 DPM.

A low DPM printing process may be achieved by employing statistical techniques to determine the effects of individual parameters or interactions between different parameters. Important process parameters can then be optimized using design of experiments (DOE) techniques. These optimized parameters can then be implemented and process bench marking can begin. Statistical process control can then be used to continuously monitor and improve printing DPM levels.

See also[edit]

References[edit]

Further reading[edit]

  • Lasky, Ronald; Hall, W. James; Hickey, Katherine; Tate, Jennifer (2014). Handbook of Electronics Assembly and A Guide to SMTA Certification (1 ed.). Surface Mount Technology Association (SMTA). ISBN 978-0-98888731-2. ISBN 0-98888731-2. [1]
  • Tarr, Martin (2013). "Screen and stencil printing". Online postgraduate courses for the electronics industry. UK: University of Bolton. Archived from the original on 2014-05-28. [2]
  • Padmanapan, Sakthivel (2014-05-30). "Workshop on SMT Stencils" (PDF). Chennai: Surface Mount Technology Association (SMTA). Archived (PDF) from the original on 2018-06-17. Retrieved 2018-06-17.
  • Mersits, Christopher (2012). "Investigation of aperture filling and release for modern developments of the solder paste stencil printing process". State University of New York, Binghamton / ProQuest Dissertations Publishing. pp. 4–5, 9–10. 1535200.