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Multilayer Printed Circuit Board PCB Prototypes Metal Core Stack-up

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Multilayer PCB Board

  • High Precision Multilayer PCB Board suppliers

PCB, what we normal call as "printed circuit Board", is the basic for all electronics products. 

If we classify the PCB by layers, there will be single sided PCB, double sided PCB, and multilayer PCB Board.

 

Multilayer PCB Instructions by Linked Electronics

 

Multilayer PCB Board is made up of more than 2 copper layers, and those copper layers are boned by prepeg.  Conductor on different layers are connected with vias.

Compared with doubled sided layers, multilayer circuit board is smaller with higher capacity, faster speed, better durability and greater functionality. For BGA and QNF packages, electronic design engineer will use HDI multilayer PCB. 

 

By category in Linked Electronics, there are multilayer FR4 PCB, multilayer Rogers PCB, multilayer rigid flex PCBs, heavy copper multilayer PCB and HDI multilayer PCB board. 

 

Applications of Multilayer PCBs

 

Mulilayer PCB is used more and more in electronics industries becuse of its unique advantages.

 

Multilayer PCB boards is much more precise and has better performance than double sided PCBs, which is widely used in industrial, medical and communication industries. 

 

 

 

Multilayer Printed Circuit Board PCB Prototypes Metal Core Stack-up

Multilayer Printed Circuit Board PCB Prototypes Metal Core Stack-up
Multilayer Printed Circuit Board PCB Prototypes Metal Core Stack-up Multilayer Printed Circuit Board PCB Prototypes Metal Core Stack-up Multilayer Printed Circuit Board PCB Prototypes Metal Core Stack-up

Large Image :  Multilayer Printed Circuit Board PCB Prototypes Metal Core Stack-up

Product Details:

Place of Origin: China
Brand Name: Linked Electronics
Certification: UL, TS16949, ISO14001, ISO9001
Model Number: LPCB1501

Payment & Shipping Terms:

Minimum Order Quantity: 1pcs
Price: by negotiation
Packaging Details: vacumm package
Delivery Time: 2 days
Payment Terms: T/T, Western Union,Paypal
Supply Ability: 10, 000pcs per month
Detailed Product Description
Material: FR4 PCB Core: FR4 Core
Layers: 4 Layer Quick Turn: Accepted

Multilayer PCB Stack-Up Design & its Lamination Process
 
Multilayer PCB or multilayer printed circuit boards are circuit boards which is composed of three layers or three more conductive layers (copper layers). The copper layer is pressed together by the resin which is normally called as prepreg. Due to the complexity of the multilayer PCB manufacturing process, high x-out rate, and difficulty in PCB rework. Thus, the cost of multilayer PCBs is relatively higher than a single sided PCB and two-layer PCB.
 
Linked Electronics manufactures multilayer PCB up to 56 Layer, from FR4 material, high frequency material or mixed-press materials: Fr4, Rogers, Polyamide, metal core PCBs.
 
Multilayer PCB Manufacturing
 
Multilayer Printed Circuit Board PCB Prototypes Metal Core Stack-up
 
This page will illustrate more information about multilayer PCB. Also this will provide you a guidance into the Multilayer PCB solutions.
 
What is the definition of Multilayer PCB printed circuit board?
 
Multilayer PCB can be referred to as a multi-layer printed circuit board that is composed of three or more layers. This is made up of a substrate layer, which has a conductive metal on top and bottom sides. It also offers enhanced functionality. They are utilized in complex devices which require a very high number of connections.
 
Multilayer PCB boards includes at least three layers of conductive layers. This multilayer PCB laminating process means pressing FR4 core and PP together.
 
Both of them are laminated under high hydraulic press pressure and temperature condition. This process will melt prepreg which later make the prepreg to join these layers together.
 
Multilayer PCB Manufacturing Steps
 
The manufacturing process of multilayer circuits takes several complicated steps which much more difficult and complex than doubled sided PCBs.
PCB Layout
Printed Circuit boards should be rigorously compatible with, a PCB layout created by the engineer designer using PCB design software. Here is some of the commonly-used PCB EDA software, Altium Designer, OrCAD, Pads, KiCad, Eagle etc. NOTE: Before the PCB fabrication, designers should inform their contract manufacturer about the PCB design software version used to design the circuit since it helps avoid issues caused by discrepancies.
 
 
Once the PCB design is approved for production, designers export the design into format that PCB manufacture accepts and the frequently used program is called extended Gerber in the format IX274X.
 
 
The PCB industry birthed extended Gerber as the perfect output format. Different PCB design software possibly calls for different Gerber file generation steps, they all encode comprehensive vital information including copper tracking layers, drill drawing, apertures, component notations and other options. All aspects of the PCB design undergo checks at this point. The software performs oversight algorithms on the design to ensure that no errors go undetected. Designers also examine the plan with regard to elements relating to track width, board edge spacing, trace and hole spacing and hole size.
 
 
After a thorough examination, designers forward PCB file to PC Board Houses for production. To ensure the design fulfills requirements for the minimum tolerances during manufacturing process, almost all PCB Fab Houses run Design for Manufacture (DFM) check before printed circuit board fabrication.
 
Printing of the PCB Design
 
PCB printing begins after designers output the PCB schematic files and manufacturers conduct a DFM check. The PCB manufacturers use a printer called a plotter, which makes photo films of the PCBs, to print circuit boards. PCB manufacturers will use the films to image the PCBs. Although it's a laser printer, it isn't a standard laser jet printer. Plotters use incredibly precise printing technology to provide a highly detailed film of the PCB design.
 
 
The final product results in a plastic sheet with a photo negative of the PCB in black ink. For the inner layers of PCB, black ink represents the conductive copper parts of the PCB. The remaining clear portion of the image denotes the areas of non-conductive material. The outer layers follow the opposite pattern: clear for copper, but black refers to the area that'll be etched away. The plotter automatically develops the film, and the film is securely stored to prevent any unwanted contact.
 
 
Each layer of PCB and solder mask receives its own clear and black film sheet. In total, a two-layer PCB needs four sheets: two for the layers and two for the solder mask. Significantly, all the films have to correspond perfectly to each other. When used in harmony, they map out the PCB alignment.
 
 
To achieve accurate alignment of all films, registration holes should be punched through all films. The exactness of the hole occurs by adjusting the table on which the film sits. When the tiny calibrations of the table lead to an optimal match, the hole is punched. The holes will fit into the registration pins in the next step of the imaging process.
 
 
Print the Copper Utilized for the Interior Layer
 
This step is the first while making the inner layer of the PCB. You print the multilayer PCB design; then copper is re-bonded to the FR4 or PP that serves as the PCB structure.
Discard unwanted copper
With the photo resist removed and the hardened resist covering the copper that needs to be kept, the board manufacturing steps into the next stage: unwanted copper removal. Just as the alkaline solution removed the resist, a more powerful chemical preparation wash away the excess copper. The copper solvent solution bath removes all of the exposed copper. Meanwhile, the desired copper remains fully protected beneath the hardened layer of photo resist.
 
 
Not all copper boards are created equal. Some heavy copper boards require larger amounts of copper solvent and varying lengths of exposure. As a side note, heavier copper boards require additional attention for track spacing. Most standard PCBs rely on similar specification.
 
 
Now that the solvent removed the unwanted copper, the hardened resist protecting the preferred copper needs washing off. Another solvent accomplishes this task. The board now glistens with only the copper substrate necessary for the PCB.
 
Lamination of the PCB Layers
 
AOI will be performed to check that there will be zero defects for the traces. Those can be bonded together. You can achieve this process in two spes, which includes the lay-up and the laminating.
The entire operation undergoes an automatic routine run by the bonding press computer. The computer orchestrates the process of heating up the stack, the point in which to apply pressure, and when to allow the stack to cool at a controlled rate.
 
Drilling
 
Before you drill, the drill spot is located with an x-ray machine. This helps in securing the PCB stack.
PCB Plating
This process helps in fusing the different PCB layers making use of a chemical.
 
Imaging and Plating of the Outer Layer
 
By doing this you are guarding the copper found on the outer layer by applying the photoresist.
 
Final Etching
 
To protect the copper during the process, a tin guard is utilized. This gets rid of unwanted copper. This also ensures properly established PCB connections.
 
Applying Solder Mask
 
After cleaning the PCB panels, soldermask is applied onto both sides of the PCBs
Silk print is printed onto the PCBs
 
The nearly completed board receives ink-jet writing on its surface, used to indicate all vital information pertaining to the PCB. The PCB finally passes onto the last coating and curing stage.
 
Electrical and Testing Reliability
 
A technician performs electrical tests on the PCB. The automated procedure confirms the functionality of the PCB and its conformity to the original design. At linked electronics, we offer an advanced version of electrical testing called Flying Probe Testing, which depends on moving probes onto the pads to test electrical performance of each net on a bare printed circuit board. Another advanced testing is fixture which is faster but expensive for prototypes. The pins of the fixture will touch the pads and check the conformity of the boards.
 
Mechanic Process
 
PCBs will be routed as per customer’s mechanic file after flying probe test. For PCB using fixture test, the PCB will be routed out before mechanic process.
 
FQC
 
Final inspection will be performed. This includes board thickness, board warp and twist, any scratches etc. The errors rectified before it is sent for delivery.
 
 
Materials Used in the Manufacturing of Multilayer PCB
 
 
The different materials utilized in manufacturing multilayer PCBs are boards, copper foil, resin system, substrate, infused fiberglass sheet. Using an alternating sandwich, you can laminate these materials together.
All the planes of copper are etched and the plating through of all internal vias is done before the layers.
 
 
Multilayer PCB: Advantages
 
Multilayer PCBs come with lots of great benefits. Some of them include:
Higher assembly density
Provision of high speed and high capacity, as a result of their electrical properties
Weight reduction of devices
Elimination of connectors needed for multiple separate PCBs, thereby simplifying its construction.
Multilayer PCB: Product Use
Multilayer PCBs can be used in many areas
They are used in manufacturing CAT scan, heart monitors, and modern x-ray equipment.
Utilized in the production of high-speed circuits due to their functionality and durability
Used for headlight switches and onboard computers due to their high functionality and heat resistant ability
The running of machinery and industrial control system utilize them due to their small size and durability.
Consumer electronics such as microwaves and smartphones also make use of multilayer PCBs as a result of their small size and functionality.
Satellite applications, GPS, and signal information, also make use of multilayer PCBs
Used in the production of computer electronics that are utilized in motherboard servers due to its performance and space-saving attributes.
 
 
Identifying a Multilayer PCB
 
 
You can identify a multilayer PCB through the following
How your electronic equipment operates briskly, as well as the ultimate board’s operational setting
The configuration, layer count, and the value of the board’s building also play a role in the identification
The board routing density
The operating capacity, speed, parameters, and functionality, distinguishes if the PCB is a multilayer one
They make use of simple production techniques, but still focusing on performance and quality.
Multilayer PCBs are usually difficult to style, in contrast to single-layer ones that have an easy production process
Single-layer PCBs are usually produced in large quantities and can also be ordered in bulk. This helps in reducing the price per board thereby ensuring that producing these devices are less expensive. For multilayer PCBs, producing them are usually tedious, and it may be difficult producing them in large qualities at once.
 
 
Components Used in the Construction of Multiple PCBs
 
 
The most common parts used the multilayer PCB includes:
Led
Capacitor
Transistor: Utilized in amplifying charge
Resistors: Control the electric current when it passes through
Diode: Diodes allow the passing of current through one direction only
Battery: provides the circuit its voltage
 
 
Why are Multilayer PCBs Usually Widely Used?
 
 
Multilayer PCBs are widely used in many areas for the following reasons:
Multilayer PCBs are made utilizing high technology. This is why it is highly trusted due to the skills, processes, and designs required to manufacture it.
You can also attribute it to the fact that users always want something modern.
Its miniature size gives it its flexibility
It has a small size, and its performance is enhanced with its technology. Most users prefer a device having a smaller size
As a result of its less weight, it is portable enough and convenient for users. Users can easily carry the around, because they are not as bulky as some other smartphones.
Due to its fabrication process, users consider this PCB as one with high quality
It makes use of highly skilled professionals, modern technology, and high-quality materials.
Easy installation, which makes it widely used, hence there is no need getting the service outsourced
Multilayer PCBs come with a protective layer, which prevents damage from coming to it, as well as an increase in its durability
It is the most preferred due to its higher density, when compared to its counterparts. Users love devices that have a higher mass per volume degree, which should boast enough storage space.
 
 
Multilayer PCB Quality Standards
 
Multilayer PCBs come with some quality standards. They include ISO 9001 makes sure that manufacturers meet the needs of customers within regulated and permitted requirements that concern a service or product.
 
ATF16949 is another quality standard requiring the manufacturers of electronics to assure the security and quality of automotive products. This helps in improving the reliability and performance of automotive components.
 
The UL listing service requires that manufacturers test their products thoroughly. This is to makes sure that specific requirements are met.
 
 
Should Multilayer PCBs be regarded as High-frequency PCBs?
 
 
Yes, multilayer PCBs are categorized under high-frequency PCBs. With multiple layers, the boards can have a great thermal coefficient and impedance control.
To be regarded among the high-frequency design applications, having a ground plane is very essential. Multilayer applications are utilized in high-frequency applications like smartphones and microwaves.
Conclusion
Multilayer PCBs come with lots of benefits and are relevant in several applications. However, before choosing multilayer PCBs, there are so many things you need to consider. Make sure that whatever decision you make suits your needs.
Due to the increase in the packaging density of integrated circuits, a high concentration of interconnection lines has resulted, which necessitates the use of multilayer PCB. Unforeseen design problems such as noise, stray capacitance, and crosstalk have appeared in the printed circuit layout. Therefore, the printed circuit board design must minimize the length of signal lines and avoid parallel routes. Obviously, in the PCB single-sided board, even the double-sided board, due to the limited number of crosses circuit that can be achieved, these requirements cannot be satisfied. In the case of a large number of interconnection and crossover requirements, the PCB circuit board must be expanded to more than two layers to achieve satisfactory performance. Thus a multilayer circuit board has appeared. Therefore, the original intention of manufacturing multilayer circuit boards is to provide more freedom in selecting appropriate wiring paths for complex and noise-sensitive electronic circuits.
 
Request Multilayer PCB Quote
Contact Us at sales@linked-elec.com
 
Multilayer PCB circuit boards have at least three conductive layers, two of which are on the outer surface, and the remaining layer is integrated into the insulating board. The electrical connection between them is usually achieved through plated through holes on the cross-section of the circuit board. Unless specified, multilayer printed circuit boards are the same as double-sided boards, generally plated through-hole boards
Advantages and disadvantages of multilayer PCB
Advantages:
1
High assembly density
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2
Small size
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3
Lightweight
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Multilayer PCB circuit boards have at least three conductive layers, two of which are on the outer surface, and the remaining layer is integrated into the insulating board. The electrical connection between them is usually achieved through plated through holes on the cross-section of the circuit board. Unless specified, multilayer printed circuit boards are the same as double-sided boards, generally plated through-hole boards
Disadvantages:
1
High cost
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2
Long manufacturing time
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3
Request high-reliability testing methods.
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Multilayer printed circuit is the product of electronic technology development in high speed, multi-function, large capacity, and small volume. With the continuous development of electronic technology, especially the extensive and in-depth application of large-scale and very large-scale integrated circuits, multilayer printed circuits are rapidly developing in the following directions: high density, high precision, and high layers, tiny lines and small holes, blind and buried holes, high plate thickness to aperture ratio and other technologies to meet market needs.
 
Why are PCB multilayer boards all even-numbered layers?
It can be manufactured in a PCB factory. The four-layer board generally uses a core with one copper foil on each sideand a three-layer board with one copper foil on one side. They must be pressed together.
 
The process cost difference between the two is that the four-layer board has one more copper foil and bonding layer. The cost difference is not significant. When the PCB factory makes a quote, they are generally quoted on an even number basis. Also, 3-4 layers are commonly quoted as a grade. (For example:If you design a 5-layer board, the other party will quote at the price of a 6-layer board. That is to say, the price you design for 3 layers is the same as the price you design for 4 layers.)
 
In the PCB process technology, the four-layer PCB board is better controlled than the three-layer board, mainly in terms of symmetry. The warpage of the four-layer board can be controlled below 0.7% (IPC600 standard), but the size of the three-layer board is large. At that time, the warpage will exceed this standard, which will affect the reliability of the SMT assembly and the entire product. Therefore, the designer shouldnot design the odd-numbered layer board. Even if the odd-numbered layer is necessary, it will be designed as a fake even-numbered layer. That is to design 5 layers into 6 layersand 7 layers into 8 layers.
 
 
Calculation Method of Multilayer PCB Stack-Up:
 
Multilayer Printed Circuit Board PCB Prototypes Metal Core Stack-up
 
A: Thickness of inner layer
E: Thickness of inner copper foil
X: Finished board thickness
B: Thickness of PP sheet
F: Thickness of outer copper foil
Y: Finished PCB tolerance
1. Calculate the upper and lower limit of pressing:
Usually tin plate: upper limit -6MIL, lower limit-4MIL Gold plate: upper limit -5MIL, lower limit -3MIL For example, tin plate: upper limit=X+Y-6MIL lower limit=X-Y-4MIL Calculate the median = (upper limit + lower limit)/2 ≈A+the area of the second layer of copper foil%*E+the area of the third layer of copper foil%*E+B*2+F*2
 
 
 
The inner cutting material of the above conventional four-layer board is 0.4MM smaller than the finished board, using a single 2116 PP sheet to press. For special inner layer copper thickness and outer layer copper thickness that more than 1OZ, the copper thickness should be considered when choosing the inner layer material.
 
2. Calculate the Pressing Tolerance:
Upper limit = Finished board thickness + Finished on-line tolerance value-[Plating copper thickness, green oil character thickness
(Conventional 0.1MM)]-The theoretically calculated thickness after pressing
Lower limit = finished board thickness-finished product off-line tolerance value-[electroplating copper thickness, green oil character thickness
(Regular 0.1MM)]-The theoretically calculated thickness after pressing
 
3. Commonly types of PP sheets:
PP KB KB
1080 0.07MM 0.065MM
2116 0.11MM 0.105MM
2116 0.11MM 0.105MM
 
 
Generally, do not use two PP sheets with high resin content together. If the inner layer of copper is too small, please use PP sheets with high resin content. 1080 PP sheets have the highest density and low resin content. Do not press single sheets as much as possible. Only 2 sheets of 2116 and 7630 PP sheets can be pressed into thick copper plates above 2OZ. The layer cannot be pressed by a single sheet of PP. 7628 PP sheet can be pressed by a single sheet, 2 sheets, 3 sheets, or up to 4 sheets.
 
Explanation of theoretical thickness calculation of multilayer PCB board after lamination.
 
Multilayer Printed Circuit Board PCB Prototypes Metal Core Stack-up
 
Thickness after PP lamination = 100% residual copper lamination thickness-inner copper thickness*(1-Remaining copper rate%)
 
 
4. Typical Recommendation of Multilayer Stack-Up
 
Multilayer Printed Circuit Board PCB Prototypes Metal Core Stack-up
 
1): 4 Layer PCB Stack-Up
 
 
Multilayer Printed Circuit Board PCB Prototypes Metal Core Stack-up
 
Multilayer Printed Circuit Board PCB Prototypes Metal Core Stack-up
Multilayer Printed Circuit Board PCB Prototypes Metal Core Stack-up
Multilayer Printed Circuit Board PCB Prototypes Metal Core Stack-up
 
 
 
 
 
 
 
Previous
Next
 
2).6 Layer PCB Stack-Up
0.8mm 6 layer PCB stack up
 
Multilayer Printed Circuit Board PCB Prototypes Metal Core Stack-up
2.0mm 1.6mm 6Layer PCB Stack-up
 
Multilayer Printed Circuit Board PCB Prototypes Metal Core Stack-up
1.2mm 1.0mm 6 Layer PCB Stackup
 
Multilayer Printed Circuit Board PCB Prototypes Metal Core Stack-up
0.8mm 6 layer PCB stack up
 
Multilayer Printed Circuit Board PCB Prototypes Metal Core Stack-up
2.0mm 1.6mm 6Layer PCB Stack-up
 
3).Typical Stack-Up of 8 Layer PCB
 
Multilayer Printed Circuit Board PCB Prototypes Metal Core Stack-up
1.2mm 1.0mm 8 Layer PCB Stackup
 
Multilayer Printed Circuit Board PCB Prototypes Metal Core Stack-up
2.0mm 1.6mm 8 Layer PCB Stackup
 
Multilayer Printed Circuit Board PCB Prototypes Metal Core Stack-up
1.2mm 1.0mm 8 Layer PCB Stackup
 
Multilayer Printed Circuit Board PCB Prototypes Metal Core Stack-up
2.0mm 1.6mm 8 Layer PCB Stackup
 
 
 
 
Introduction to the Multilayer PCB Lamination Process
 
 
★ Lamination uses high temperature and high pressure to melt the prepreg by heat, make it flow, and turn it into a cured sheet. It is then processing one or more inner etched boards (Black Oxide Treatment) and copper foil into a multilayer board.
★ This process also includes layer stack-up before lamination, drill positioning holes, and profile routing after laminated multilayer boards.
1. Lamination Process Flow
 
Multilayer Printed Circuit Board PCB Prototypes Metal Core Stack-up
 
Multilayer PCB Manufacturing Process Steps
 
 
Remarks: For 6 layer PCB stack-up and over, two or more inner layers must be pre-positioned so that the holes and circuits of different layers have the correct alignment.
2.Position Methods
1) Positioning of rivet nails: press the layout of the inner layer board and prepreg with pre-drilled positioning holes
1. The sequence is set on the template with rivets and then punched with a nail punch
2. Rivets to position
2) Solder joint positioning: set the inner layer board and prepreg with pre-drilled positioning holes according to the layout
1. The sequence is set on the template equipped with positioning pins, and then through the heating several
2. A fixed point, using the prepreg to melt and solidify when heated
We are currently using solder joint positioning-RBM
Pre-punched positioning hole for the inner board, the current method we use is as follows: Punch 4 slot holes on the four sides of the board, two as a group, respectively locating in the X/Y direction, one of which is asymmetrical design. The purpose is to start to prevent a reaction.
A= 7.112±0.0254MM
B= 4.762 ±0.0254MM
 
Thickness <40mil 40mil<T<60mil >60mil
temperature 300℃ 300℃ 300℃
Time 0.3-0.5min 0.6-0.8min 0.8-1.0min
Quality control after RBM-potential problems
 
1) Interlayer offset: poor RBM positioning or poor heating point condensation, causing Shift between layers after pressing, after drilling due to Dislocation of the lines on each layer causes open or short.
Possible reason:
uInner layer punching deviation
uThe expansion and contraction of the inner plate is very different
uRBM staff deflection
uRBM parameters do not match-the coagulation effect is not acceptable
uRBM heating head wear-bad condensation effect
u Lay up personnel put the board improperly, causing the heating point to fall off
 
2) The inner core is reversed: the order of the inner core is incorrectly placed during RBM, which affects the quality of the customer’s assembled board.
Introduction to Layer Stack-Up Process: The layout process arranges the inner core, prepreg, and copper foil with aluminum plates according to the structural requirements and reaches the required height for pressing. CEDAL layer stack-up can be divided into four main layouts according to the below picture
 
Multilayer Printed Circuit Board PCB Prototypes Metal Core Stack-up
 
3).Introduction to Prepreg
A prepreg refers to glass fibers or other fibers impregnated with resin. After partial polymerization, the resin molecules are slightly cross-linked, which can be softened by heat. However, it cannot be completely melted.
Prepreg specifications
 
Multilayer Printed Circuit Board PCB Prototypes Metal Core Stack-up
 
Prepreg specifications
Main Performance characteristics of prepreg
Resin content (R/C)
Resin fluidity (R/F)
Gel time (G/T)
Volatile content (V/C)
Test - Resin Content
Resin content (RC)
 
1). Resin content definition: the percentage of the weight of resin in the semi-cured to the weight of the prepreg;
 
2). Calculation formula: RC=(TW-DW)÷TW ×100%;
RC: Resin content; TW: weight of prepreg; DW: weight of glass cloth after burning.
 
3) TW can be used as a control indicator when the base weight of the glass cloth is constant
2. Instrument: Electronic balance, accuracy: 0.001 g
3. Sample: 4 “X 4” X 4 pieces
 
 
Description of Resin Content
Resin content of prepreg (RC)
lRC is mainly related to the thickness of the laminate.
lThe RC is low,and the thickness of the board is thin;
lIf the deviation of the left, middle,and right of the RC is large, the thickness uniformity of the board will be poor.
After controlling the RC of the prepreg, the required thickness can be obtained after pressing, and the Cpk value of the thickness can be increased.
Comparison table of resin content and PP thickness
 
Multilayer Printed Circuit Board PCB Prototypes Metal Core Stack-up
 
Thickness calculation after resin filling:
Thickness after PP pressing
1. Thickness = theoretical thickness of single PP-filling loss
2. Filling loss = (1-A side copper residual copper rate) x copper foil thickness + (1-B side copper residual copper rate) x copper foil thickness + 0.4*(D2)2*H(inner layer thickness)*N(hole Number)/the whole board area
 
Multilayer Printed Circuit Board PCB Prototypes Metal Core Stack-up
 
The relationship between PP film characteristic parameters and resin fluidity:
lThe gel time (PG) is large,and the resin has strong fluidity;
lThe fluidity (RF) is large, and the resin has strong fluidity;
lThe minimum viscosity (MV) is small,and the resin has strong fluidity;
lLarge flow window (FW), strong resin fluidity;
The influence of resin fluidity on board quality
 
When PG is long, RF is high, MV is low, or FW is long, the following situations may occur after pressing:
1. There is a lot of resin flow and poor board thickness uniformity (easy to be thick in the middle and thin on the edge).
2. White edges appear on the edges of the board due to low resin content.
3. Skateboarding easily occurs.
4. Easy to show texture.
5. The resin content of the board is reduced, which affects the dielectric properties and insulation properties. Also,anti-CAF performance is poor.
6. The internal stress of the plate is increased, and it is easy to twist and deform after pressing.
 
 
When PG is short, RF is low, MV is high, or FW is short, the following situations may occur after suppression:
1. Dry board, trunk line, dry point.
2. Air bubbles.
3. The cohesive force between core material layers is weakened, and the board is prone to bursting.
4. The peel strength between resin and copper foil is weakened.
PP storage conditions:
lStorage temperature: 21±2℃ or below 5℃
lStorage humidity: below 60%
lStorage time: 90 days and six month
 
 
Key Points of Layer Stack-Up Control
-Placing the Board Along the Laser Beam
Our current lay up is two types. Controlling the consistency of lay up can ensure uniform force during pressing and avoid white edges due to loss of pressure. This requires the position of the laser beam to be adjusted and fixed when preparing for lay up. Laying the board along with the laser beam in the lay up production.
 
Multilayer Printed Circuit Board PCB Prototypes Metal Core Stack-up
 
- Height Control
Controlling the height during lay up can ensure the smooth progress of pressing and achieve maximum productivity.
Machine Minimum height Highest height
48# 160mm 170mm
73# 220mm 260mm
- Panel Lay Up Requirements
l Boards of different sizes cannot lay up together.
lBoards with a difference of more than 15mil in thickness cannot lay up together.
lThe boards of different thicknesses are lay up together, the thermocouple must be placed in the middle of the thin board, and the ADARA staff shall be notified to increase the curing time by 10 minutes.
lSmall plates (less than 10 pieces) of different copper foil thickness can be lay up together by cutting the copper foil, and PE release film must be placedbetween the board and the conductive copper foil during production.
- Separate Lay Up Requirements
Lay up the board in the middle of the whole cycle.
Add dummy lay up on the top and bottom of the production board and reach the lowest height.
- Separate Lay Up Requirements
The Black Oxide Treatmentboard is stored in the environment for a long time, and it is easy to absorb water, causing delamination after pressing
Process Storage time
B/F 72hours
B/O 24hours
Lay Stack up design guidelines
1. Inner board design requirement
The edge of the inner board is filled with dummy pads.The pad diameter is required to be 4.0mm, and the spacing is required to be 1.5mm.
The two layers of dummy pads corresponding to the inner layer board mustbe staggered by half the pad distance to balance the pressure during pressing.
The dummy pads of adjacent rows should be staggered to improve flow resin.
 
Multilayer Printed Circuit Board PCB Prototypes Metal Core Stack-up
 
In the PCB design, if the removed area by the rout is large, a dummy pad is required to be added to the rout area to increase the residual copper rate and reduce the filling. The pad diameter is required to be 4.0mm, and the spacing is required to be 1.5mm.
When designing in array, if the area removed by rout is relatively large, add a dummy pad in the routarea to increase the residual copper rate and reduce the filling. The pad diameter is required to be 1.5mm, and the spacing is 1.0mm.
 
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Multilayer Printed Circuit Board PCB Prototypes Metal Core Stack-up
 
 
For designswith broken edges, dummy pads must be filled with a pad diameter of 1.5mm and a spacing of 1.0mm.
lThe two layers of dummy pads corresponding to the inner layer board are required to be staggered by half the pad distance to balance the pressure during pressing
2. PP Design Requirements
1. The centrally symmetric structure can avoid the bending phenomenon caused by structural stress.
 
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2. High R/C, thin fabric on the outer layer
lThe same glass cloth combinationand high resin content are placed on the outer layer.
lDifferent kinds of glass cloth combinations, based on the principle of symmetry, thin fabrics are placed on the outer layer.
3. Warp to warp, weft to weft
The glass cloth yarn contains different yarn counts in warp and weft directions, resulting in different glue content and differences in thermal expansion in the two directions.
4. Each layer of prepreg has a reasonable thickness
lThe thickness andglue content is high. The thickness is not suitable for control
lSmall thickness, low glue content,and low adhesion
5. Minimum number of layers
Many layers, high cost, andnot suitable for process control
 
Pressing Method – Hydraulic Press
The structure of the hydraulic pressing machine is vacuum type and standard pressure type. The plate between the openings of each layer is clamped between the upper and lower hot plates. The pressure is from bottom to top, and the heat is transferred from both upper and lower hot plates to the plate.
Advantages: simple equipment, low cost, large output.
Disadvantages: large amount of glue flow, poor thickness uniformity.
 
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Pressing method - ADARA SYSTEM Cedal
DARA SYSTEM Cedal
The Cedal is a revolutionary laminating machine. Its operating principle uses continuous coiled copper foil that laminates in a closed vacuum chamber. Current is then applied at both ends. Due to its resistance, the copper foil generates high temperature and heats prepreg, and the pressure is applied by the upper air bag to achieve the compression effect.
Advantages:
Using the upper and lower interlayer copper foils for electric heating, energy-saving,and low operating cost.
Small temperature difference between the inner and outer layers, uniform heating, good product quality.
Cycle time is short, about 60minutes.
Fast heating rate (35/min).
Disadvantages:
The equipment has a complex structure and high cost.
Single machine output is small.
The pressure is a pneumatic working method, which cannot provide high pressure.
 
Pressure curve
 
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Parameter Control and Function of Pressing
Vacuum:
It can help to remove gases, air, and small monomer residues generated by solvent volatilization.
Temperature:
The curing agent DICY is very stable at room temperature and can be cured quickly after the temperature rises. Experiments show that 170°C is the ideal curing temperature. Therefore, it is necessary to control the temperature above 170°C during the pressing process to complete the curing reaction.
Heating Rate:
Maintaining a specific heating rate can appropriately increase the resin’s fluidity, thus improving the resin’s wettability and preventing problems caused by thermal stress.
Pressure:
Offset the vapor pressure generated by volatiles. Improve resin fluidity. Increase interlayer adhesion. Prevent deformation due to thermal stress during cooling
 
 
Thickness Control
Thickness test
Use a thickness gauge to measure the thickness of the four corners and a midpoint of each plate
The test point is 50 mm from the edge of the board
Thickness tolerance: general thickness requirements ± 10%
Current thickness control after pressing
Use a thickness gauge to measure the thickness of the four corners and a midpoint of each plate
The test point is 50 mm from the edge of the board
Thickness tolerance: general thickness requirements ± 10%
 
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Multilayer PCB is manufactured by stacking two or more circuits on top of each other, and they have reliable pre-set interconnections. Since drilling and plating have been completed before all layers are pressed together, this technique violates the traditional manufacturing process from the beginning. The two innermost layers are composed of traditional double panels, while the outer layers are different. They are composed of single independent panels. Before pressing, the inner substrate will be drilled, through-hole plated, pattern transferred, developed, and etched. The outer layer to be drilled is the signal layer, which is plated through so that a balanced copper ring is formed on the inner edge of the through-hole. The layers are then rolled together to form a multilayer PCB, which can be connected to each other (between components) using wave soldering.
Pressing may be done in a hydraulic press or an overpressure chamber (autoclave). In the hydraulic press, the prepared material (for pressure stacking) is placed under the cold or preheated pressure (high glass transition temperature material is placed at a temperature of 170-180°C). The glass transition temperature is the temperature at which an amorphous polymer (resin) or part of the amorphous region of a crystalline polymer changes from a hard and brittle state to a viscous, rubbery state.
 
 
 
 
Multilayer Circuit Board
 
1. Autoclave Pressure Cooker
It is a container filled with high-temperature saturated water vapor, and high-pressure can be applied. The laminated substrate (laminates) sample can be placed in it for a period of time to force moisture into the board, and then take out the sample again. Place it on the surface of high-temperature molten tin and measure its “delamination resistance” characteristics. This word is also synonymous with the pressure cooker, which is commonly used by the industry. In addition, in the multilayer board pressing process, there is a “cabin press method” with high temperature and high-pressure carbon dioxide, which is also similar to this type of Autoclave Press.
 
2. Cap Lamination Method
It refers to the traditional lamination method of early multilayer PCB boards. At that time, the “outer layer” of MLB was mostly laminated and laminated with a single-sided copper thin substrate. It was not used until the end of 1984 when the output of MLB significantly increased. The current method is the copper-skin type large or mass pressing method (Mss Lam). This early MLB pressing method using a single-sided copper thin substrate is called cap lamination.
 
3. Crease Wrinkles
The multilayer board pressing often refers to the wrinkles that occur when the copper skin is improperly handled. Such shortcomings are more likely to occur when thin copper skins are below 0.5 oz and laminated in multiple layers.
 
4. Dent Depression
It refers to the gentle and uniform sag on the copper surface, which may be caused by the partial protrusion of the steel plate used in pressing. If it shows a neat drop of the faulty edge, it is called “dish down.” If these shortcomings are left on the line after copper corrosion, the impedance of the high-speed transmission signal will be unstable, and noise will appear. Therefore, such a defect should be avoided as much as possible on the substrate’s copper surface.
 
5. Caul Plate Partition
When the multilayer board is pressed, in each opening of the press, there are often many “books” of bulk materials (such as 8-10 sets) of the board to be pressed. Each set of “bulk materials” (Opening) Book) must be separated by a flat, smooth, and hardened stainless steel plate. The mirror stainless steel plate used for this separation is called “caul plate” or “separate plate.” At present, AISI 430 or AISI 630 are commonly used.
 
6. Foil Lamination Method
Refers to the mass-produced multilayer board, the outer layer of copper foil and film are directly pressed with the inner skin, which becomes the mass lam of the multilayer board. This replaces the early traditional single-sided thin substrate Press legal.
 
7. Kraft Paper
When multilayer boards or substrate boards are laminated, kraft paper is often used as a heat transfer buffer. It is placed between the hot plate (Platern) of the laminator and the steel plate to ease the temperature rise curve closest to the bulk material. Between multiple substrates or multilayer boards to be pressed. Try to minimize the temperature difference of each layer of the sheet; the commonly used specifications are 90 to 150 pounds. Because the fiber in the paper has been crushed after high temperature and high pressure, it is no longer tough and difficult to function, so it must be replaced with a new one. This kind of kraft paper is co-cooked with a mixture of pinewood and various strong alkalis. After the volatiles escape and the acid is removed, it is washed and precipitated. After it becomes pulp, it can be pressed again to become rough and cheap paper material.
 
8. Kiss Pressure, Low Pressure
When the multilayer board is pressed and the plates are placed and positioned, they will start to heat and be lifted by the hottest layer from the bottom. Afterward, lift with a powerful hydraulic jack (ram) to press each opening (bulk materials in the opening) and are bonded together. At this time, the combined film (prepreg) begins to gradually soften or even flow, so the pressure used for the top extrusion cannot be too large. This is to avoid slippage of the sheet or excessive flow of the glue. This lower pressure (15-50 PSI) initially used is called “kiss pressure.” However, when the resin in the bulk materials of each film is heated to soften and gel and is about to harden. It is necessary to increase to the full pressure (300-500 PSI) so that the bulk materials are tightly combined to form a strong multilayer board.
 
9. Lay Up stacking
Before pressing multilayer circuit boards or substrates, various bulk materials such as inner layer boards, films and copper sheets, steel plates, kraft paper pads, etc., need to be aligned, aligned, or registered up and down to prepare. Then it can be carefully fed into the pressing machine for hot pressing. This kind of preparatory work is called Lay Up. To improve the quality of multilayer boards, not only this kind of “stacking” work must be carried out in a clean room with temperature and humidity control, but also for the speed and quality of mass production. Generally, the large-scale press method (Mass Lam) in construction, even “automated” overlapping methods are needed to reduce human error. To save workshops and shared equipment, most factories combine “stacking” and “folding boards” into a comprehensive processing unit, so automation engineering is quite complicated.
 
10. Mass Lamination (Lamination)
Before pressing multilayer circuit boards or substrates, various bulk materials such as inner layer boards, films and copper sheets, steel plates, kraft paper pads, etc., need to be aligned, aligned, or registered up and down to prepare. Then it can be carefully fed into the pressing machine for hot pressing. This kind of preparatory work is called Lay Up. To improve the quality of multilayer boards, not only this kind of “stacking” work must be carried out in a clean room with temperature and humidity control, but also for the speed and quality of mass production. Generally, the large-scale press method (Mass Lam) in construction, even “automated” overlapping methods are needed to reduce human error. To save workshops and shared equipment, most factories combine “stacking” and “folding boards” into a comprehensive processing unit, so automation engineering is quite complicated.
 
 
 
 

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