Traditional electroplating of such components as bearings, pistons, andlanding gear parts often results in an uneven finish as well as wastageas the plating technician tries to achieve uniformity through grindingand polishing. HNKTech’s FEA software works by creating a densitymodel. The model is displayed after inputting your electroplatingset-up including the geometric profile, material properties, andboundary conditions. Using these variables, the software simulates theelectroplating process then displays the density model with predictedplating thickness and uniformity.

Engineers can review the density model and make changes to thepositioning of the jig, voltage, time, and temperature. The simulationis re-run until the engineer is satisfied with the thickness anduniformity predicted. The company says that the variation in thicknessand uniformity between what is predicted and what is achieved in thefactory is 95% accurate.

HNKTech’s software uses a customized user interface that is said to beeasy to use. No specialist training is necessary and even thosewith limited training can use the software effectively, according tothe company.

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With the study of zinc electroplating process by Electrochemical Noise (EN), it was found that the EN generated during the electroplating of large conglomerate zinc deposit has large potential oscillation amplitude and positive potential drift. However, small noise amplitude and little potential drift was seen in the case of compact zinc deposit. Any metal can be plated through zinc electroplating process, but the most common are steel and iron, on which the process offers sacrificial protection.

Steps of Commercial Zinc Electroplating Process
On the commercial scale, zinc electroplating is done by the following steps.
1. Surface of the metal is cleaned in alkaline detergent type solutions, and it is treated with acid, in order to remove any rust or surface scales. Cleanliness is essential for successful zinc electroplating, as the molecular layers of oil or rust can prevent adhesion of the coating.
2. Next, the zinc is deposited on the metal by immersing it in a chemical bath containing dissolved zinc. A DC current is applied, which results in zinc being deposited on the cathode. Alkaline zinc baths are used by the finished products, to produce a more consistent zinc thickness, especially in recesses.
3. Hence an increased protection from corrosion is provided, as the corrosion of the deposited zinc is reduced. The zinc coating can increase the time required for the formation of white rust, by ten times. Finished Products also apply sealers, which are now commonly being specified by the automotive industry, further increasing corrosion protection.

It is very difficult to obtain a uniform thickness of coating, with electroplating technique. The thickness of the coating is very much dependent on the geometry of the object being plated, and it is preferentially on the external corners and protrusions of the metal body, hence not much of it is deposited on internal corners and recesses. Zinc electroplating process is used to make a clean, smooth and corrosion resistant surface. It also makes an excellent undercoat for powder coating or paint and can leave recesses on complex shaped components without sufficient zinc coating, in order to provide corrosion protection.

The process of electroplating (also referred to as electrodeposition) is fairly simple. To start, a negative charge is placed on the object that will be coated. The object is then immersed in a salt solution of the metal that will be used to plate the object. From there, it’s simply a matter of attraction; the metallic ions of the salt are positively charged and are thus attracted to the negatively charged object. Once they connect, the positively charged ions revert back to their metallic form again and you have a newly electroplated object.

Controlling the thickness of the electroplated object is generally achieved by altering the time the object spends in the salt solution. The longer it remains inside the bath, the thicker the electroplated shell becomes. Of course there must also be an adequate amount of metallic ions in the bath to continue coating the object. The shape of the object will also have an effect on the thickness. Sharp corners will be plated thicker than recessed areas. This is due to the electric current in the bath and how it flows more densely around corners.

Before electroplating an object, it must be cleaned thoroughly and all blemishes and scratches should be polished. As mentioned, recessed areas will plate less than sharp corners, so a scratch will become more prominent, rather than being smoothed over by the plated material.

The process of electroplating began at the beginning of the 20th century and continues to evolve today. Many common objects such as tin cans are actually electroplated steel with a protective layer of tin. Medical science has experimented with electroplating to create synthetic joints with electroplated coatings, and new advances in electronics have been made with electroplated materials.

At the beginning of the line, the end of one coil is welded to the start of the next coil. Then there are two basic methods for continuously galvanizing sheet which differ in the way that the strip is cleaned before galvanizing-chemically or by thermal treatments. Coils of annealed cold reduced sheet may be fed directly to the galvanizing line, or alternatively, coiled sheet is continuously heat treated in the pretreatment line. After leaving the galvanizing bath, in which strip only stays for a few seconds, the surface is wiped to remove excess zinc and may be further treated to after the surface appearance, composition, smoothness or mechanical properties.

The steel sheet electroplating process utilizes the same basic principle as that for conventional decorative finish electroplating. However, the steel sheet process differs in that the electroplated coating is applied by passing the strip at high speeds through a series of plating cells, building the coating thickness by a small amount each time the strip passes through an individual cell. This continuous process for electroplating steel strip requires necessary equipment to transport the strip at high speeds (150 to 200 meters per minute and higher) through a series of individual plating cells, and is not as simple as it sounds.

An Electroplating Cell

The simplest electroplating cell is shown in the sketch where the plating solution bath is zinc sulfate.

The common schema of the electroplating cell.
This simple plating cell illustrates the actions during the plating process. At cathode (steel, for example), zinc ions dissolved in the zinc sulfate solution combine with two electrons and form elemental zinc, which deposits onto the cathode surface. At anode, water is converted to oxygen and hydrogen ions to maintain electrical balance. The oxygen forms a gas and nothing is deposited on the anode surface. The plating solution carries the current between the cathode and anode.

Plating of Steel Sheet in a Continuous Process

There are many types of anode arrangements. Some are horizontal, others are vertical, and one process utilizes a radial cell wherein the strip passes around large diameter rolls inside each plating cell, and the anodes have a radial design to match the diameter of the large rolls submerged into the plating solution. Each type of anode arrangement and design has advantages and disadvantages; thus, it is easy to see why different manufacturers use different methods. Each requires very close control of the anode-to-strip spacing to achieve efficient plating, avoiding arc spots and other defects in the coating.
Modern Continuous Electroplating Line.
Maintenance of the large volume of plating solution that is contained in all the cells is a science unto itself. Whether the plating solution for electrogalvanizing is based on zinc sulfate or zinc chloride chemistry, maintenance of the proper ranges of zinc ion concentration and solution pH are important control features. Besides plating zinc, some manufacturers have the ability to deposit alloy coatings. This requires, at a minimum, at least one more level of control of the plating solution. For example, producing a zinc/nickel alloy coating requires close control of the concentrations of both the dissolved zinc and nickel in the solution. Solution control has to be accomplished on a dynamic basis since these lines operate continuously.

Power Requirements

The electroplating process requires a large amount of electric power to deposit a metallic coating. The total power requirement is a direct function of the coating thickness that is needed to meet the customer’s specification. For example, the power required to deposit a zinc coating mass of 80 g/m2 is approximately twice that required to deposit a coating of 40 g/m2. A typical line that has the capability to process 70 to 120 tons/hour with a coating mass of 50 g/m2 will consume hundreds of thousands of amperes during this one hour of processing time. It is easy to see why power costs are major cost component for a facility that processes large quantities of electroplated sheet product.

Product Types

The most common electroplated coating for steel sheet products is zinc. Electrogalvanized zinc coatings are used by a number of automotive companies for exposed car-body panels, where the typical coating mass ranges from about 50 to 80 g/m2 per side. These coatings are considerably thicker than the electrogalvanized coatings typically used for non-automotive applications, so the lines built to make products for automotive applications usually have a large number of plating cells. Also, each automotive customer has their own specific coated-product specification.

Another attribute associated with the use of electrogalvanized coatings for automotive applications is excellent surface finish that is attainable with the electroplating process. Twenty-five years ago, when automotive companies began using large amounts of galvanized sheet for exposed body panels to improve corrosion protection, one of the few coated sheet products that could meet the demanding surface quality requirements was electrogalvanized. Hot-dip galvanized was, and still is, used for unexposed body parts. As the surface of hot-dip products improves, they continue to replace electrogalvanized sheet for exposed automotive body panels.

Other zinc electroplating lines have been built through the years to make thinner coatings. Typically, the sheet that is made on these lines has a coating mass of less than 25 g/m2. The applications for this product are often indoors; applications where the environment is not very corrosive. Many applications involve painted products. These coating lines often have the ability to apply paint pre-treatment so that the customer can paint directly without additional in-house treating.

A second type of electroplated coated-steel sheet being manufactured today has a coating composed of a zinc/nickel alloy. Typically, the nickel content is 10 to 16 percent with the balance being zinc. The unique feature of this process is that the zinc and nickel ions are co-deposited to make a true alloy coating. It is not composed of alternating layers.

The application for this product has been limited primarily to a few automotive companies. These companies have developed in-house product design and manufacturing processes to take advantage of the unique characteristics of the zinc/nickel coating. For these automotive applications, the metallic coating is often coated with a special corrosion-resistant thin organic coating on top of the zinc/nickel. The zinc/nickel alloy coating is covered by ASTM Specification A 918.

A third type of electroplated coating is zinc/iron alloy coating. The attributes of this specialized coating are somewhat like those of hot-dip galvannealed product. Like zinc/nickel alloy, zinc/iron coating is co-deposited as an alloy coating. Iron is uniformly deposited throughout the coating thickness. Also, like zinc/nickel coating, zinc/iron coating is used predominantly by the automotive industry. The attributes of electroplated zinc/iron is that it is relatively easy to weld and paint if the proper electro-priming equipment is available to the automotive manufacturer. Also, the coating is very hard, making it is less susceptible to scratching during stamping and handling. This is the important feature since the zinc/iron alloy coated-sheet product is being used almost exclusively for exposed car-body panels.

Corrosion Resistance of Electroplated Coatings

Concerning the corrosion behavior of electrogalvanized versus hot-dip galvanized coating, it is important to note that it is essentially equivalent for identical coating masses. A coating mass of 100 g/m2 will provide essentially the same amount of corrosion protection whether it is a hot-dip galvanized or electrogalvanized coating.

The reason that the automotive companies can successfully use a coating mass in the 50 to 80 g/m2 range is because they apply additional treatments on top of the metallic coating, including a zinc phosphate coating, an electro-deposited organic-based coating, a primer, and multiple-layer finishing paint coatings. Clearly, the corrosion resistance needed to protect a car body panel for over 10 years is more than that afforded by the metallic coating alone. Application of the above coatings over the electroplated metallic layer results in a synergistic system, whose corrosion resistance is more than the sum of its individual components.

Application of FPC
FPCs are employed in a wide variety of applications due to the nature of their characteristics. Examples of applications for FPCs include cell-phone liquid crystal display enclosure, hinge parts, keypad, battery enclosure and interface components. FPCs are also used in optical pickup and device interfaces inside hard disk drives, digital still cameras and digital camcorders. Desired performance characteristics are: 1) wiring within small spaces; 2) wiring connection accompanied by mechanical functions within working part/device and motherboard; and 3) high density interconnect resulting from denser and narrower features.

FPCs fall into three broad categories: single-sided flexible printed wiring boards, double-sided flexible printed wiring boards and multilayer flexible printed boards. Single sided and double sided FPCs are widely employed for personal computers, optical pickup (OPU), HDD and cell phones. When calculated based on substrate area, half of these are single sided and the remainder are double sided. Multilayer FPCs are mainly used in cell phones, OPU, portable music players and DSC/DVC. However, multilayer FPCs only represent approximately 3 to 4% of the total FPC production by finished board area base. This is because there are relatively few large volume applications for multilayer FPCs.

FPC Materials
Polyimide is a crucial material which provides key features to FPCs and is used in almost all FPCs. In general, FPC is manufactured with a flexible copper clad laminate (FCCL) or one of many combinations. FCCL may be broadly grouped into the following four types: 1) material made from single polyimide and copper clad sheets connected with epoxy adhesive; 2) material laminated using polyimide adhesive (laminate); 3) material made using polyimide film and a sputtering/plating method; and 4) material made by coating polyimide varnish on copper foil (casting) followed by a curing step.

Today, the dominant films for FPC applications are 12.5 to 25 microns thick, with the industry trend being toward ever thinner materials. Two major types of copper foil are used for FCCL–electrolytic copper foil and rolled copper foil. Electrolytic copper foil is typically 18 or 12 microns in thickness, and rolled copper foil 18 microns thick. Both types of copper foils are moving to thinner dimensions. Generally, rolled copper foils demonstrate flexural properties superior to those of electrolytic copper foil. HDD applications, in particular, require high flexibility and reliability, so rolled copper foils dominate this segment. In recent years, flexural properties of electrolytic copper foil have been much improved and these foils are being increasingly used for optical pickup applications.

FPC Manufacturing Process
As mentioned previously, FPCs fall into three broad categories; single sided, double sided and multilayer. Each type of FPC has a series of required manufacturing process steps, examples of which are provided below. In particular, multilayer FPCs have a wide variety manufacturing processes based on the specifics of desired structures and performance characteristics.