How LCD is made!!!

Liquid crystal displays (LCDs) consist of liquid crystals that are activated by electric current. They are used most frequently to display one or more lines of alpha-numeric information in a variety of devices: fax machines, laptop computer screens, answering machine call counters, scientific instruments, portable compact disc players, clocks, and so forth. The most expensive and advanced type—active matrix displays—are even being used as screens for handheld color TVs. Eventually, they may be widely used for large screen, high-definition TVs.

The basis of LCD technology is the liquid crystal, a substance made of complicated molecules. Like water, liquid crystals are solid at low temperatures. Also like water, they melt as you heat them. But when ice melts, it changes into a clear, easily flowing liquid. Liquid crystals, however, change into a cloudy liquid very different from liquids like water, alcohol, or cooking oil. At slightly higher temperatures, the cloudiness disappears, and they look much like any other liquid.

When the liquid crystal is a solid, its molecules are lined up parallel to one another. In the intermediate cloudy phase (liquid), the molecules still retain this more or less parallel orientation. As in any liquid, the molecules are free to move around, but they tend to "line up" in one direction, reflecting light and causing a cloudy appearance. Higher temperatures tend to agitate the molecules and thus make the liquid clear.

In an LCD, an electric current is used to switch segments of liquid crystals from a transparent phase to a cloudy phase, each segment forming part of a number or letter. The segments can also be in the shape of tiny dots or pixels, and the can be arranged in rows and columns. They are turned on and off individually to either block or allow polarized light to pass through. When the light is blocked, a dark spot is created on the reflecting screen.

There are two general types of LCDs: passive matrix, and the newer active matrix (AMLCDs). Brighter and easier to read, active matrix displays use transistors behind each pixel to boost the image. The manufacturing process for AMLCDs, however, is much trickier than that for passive matrix LCDs. As many as 50 percent of those made must now be thrown out because of imperfections. One imperfection is enough to ruin an AMLCD. This makes them very expensive to manufacture.

Raw Materials

A working LCD consists of several components: display glass, drive electronics, control electronics, mechanical package, and power supply. The display glass —between which the liquid crystals lie—is coated with row and column electrodes and has contact pads to connect drive electronics (electric current) to each row and column electrode. The drive electronics are integrated circuits that supply current to "drive" the row and column electrodes. The control electronics are also integrated circuits. They decode and interpret the incoming signals—from a laptop computer, for example—and send them to the drive electronics. The mechanical package is the frame that mounts the printed circuit boards for the drive and control electronics to the display glass. This package

In all LCDs, the liquid crystal is sandwiched between 2 pieces of glass or transparent plastic called substrates. If glass is used, it is often coated with silicon dioxide to improve liquid crystal alignment. Transparent electrode patterns are then made by applying a layer of indium tin oxide to the glass and using a photolithography or silkscreening process to produce the pattern.

also strengthens and protects the display glass and anchors the entire display to the device using the LCD, whether it is a laptop computer, a fax machine, or another device. Finally, the power supply is an electronic circuit that supplies current to the LCD. Equipment makers who use LCDs often purchase the power supplies separately.

In all LCDs, the liquid crystal is sandwiched between two pieces of glass or transparent plastic called substrates. Just any glass will not do. If the glass has many sodium or other alkali ions, they can move to the glass surface, combine with any moisture that is there, and alter the electric field pattern and liquid crystal alignment. To eliminate that, LCD makers either use borosilicate glass, which has few ions, or they apply a layer of silicon dioxide to the glass. The silicon dioxide prevents the ions from touching any moisture. An even simpler solution is to use plastic instead of glass. Using plastic also makes the display lighter. However, inexpensive plastics scatter light more than glass, and they may react chemically with liquid crystal substances.

Most LCDs today also use a source of light coming from the rear of the display (backlight), such as a fluorescent light, to make the liquid crystal appear darker against the screen when in its cloudy phase. LCD makers also use sheets of polarizer material to enhance this effect.

The Manufacturing
Process

Making passive matrix LCDs is a multi-step process. The surface and rear glass of the display is first polished, washed, and coated with silicon dioxide (SiO ₂ ). Next, a layer of indium tin oxide is evaporated onto the glass and etched into the desired pattern. A layer of long chain polymer is then applied to allow the liquid crystals to align properly, followed by a sealing resin. The spacers next are put into place, and the glass sandwich is filled with the liquid crystal material.

Preparing the glass substrates

• 1 First, the two glass substrates must be cut to the proper size, polished, and washed. Cutting can be done with a diamond saw or scribe, while polishing involves a process called lapping, in which the glass is held against a rotating wheel that has abrasive particles embedded in it. After being washed and dried, the substrates are coated with a layer of silicon dioxide.

Making the electrode pattern

• 2 Next, the transparent electrode pattern must be made on the substrates. This is done by completely coating both front and rear glass surfaces with a very thin layer of indium tin oxide. Manufacturers then make a mask of the desired pattern, using either a silk-screening or photolithography process. They apply the finished mask to the fully coated glass, and areas of indium tin oxide that are not needed are etched away chemically.
• 3 Alternatively, finer definition can be achieved by using glass that has a layer of etching-resistant, light-sensitive material (called photoresist) above the indium tin oxide film. A mask with the desired pattern is placed over the glass, and the glass is bombarded with ultraviolet light. This light causes the resistive layer it shines on to lose its resistance to etching, allowing the chemicals to eat away both the exposed photoresist and the indium tin oxide below it, thus forming the pattern. The unnecessary photoresist that remains can then be removed with other chemicals. A second variety of resistive film resists etching only after it is exposed to ultraviolet light; in this case, a negative mask of the pattern must be used. Regardless of which method is used, the patterns on the two substrates are designed to overlap only in specific places, a design that ensures that the thin strips of indium tin oxide conveying voltage to each element have no electrode positioned directly opposite that might show up while the cell is working.

Applying the polymer

• 4 After the electrode pattern is in place, the substrates must be coated with a polymer. The polymer allows the liquid crystals to align properly with the glass surface. Polyvinyl alcohol, polyamides, and some silanes can be used. Polyamides are the most popular agents, because polyvinyl alcohol is subject to moisture problems, and silanes produce a thin, unreliable coating.
• 5 After coating the glass, manufacturers then stroke the polymer coat in a single direction with soft material. This can result in small parallel grooves being etched into the polymer, or it may simply stretch the polymer coat. In any case, this process forces the liquid crystals to lie parallel to the direction of the stroke. The crystals may be aligned another way, by evaporating silicon oxide onto the glass surface at an oblique angle. This procedure is used to make most digital watch displays but is not convenient for making large-scale displays. It also does not yield the low-tilt angle possible with the previous method.
• 6 If LCD makers want to align liquid crystals perpendicular to the glass surface, another technique is used: coating the glass with an amphophilic material. This is material whose molecules display affinity for water at one end of the molecule and repulsion from water at the other end. One end—the affinity end—adheres to the glass surface while the other end—the repulsing end—points into the liquid crystal area, repelling the liquid crystals and forming them into an alignment that is perpendicular to the glass surface.

Applying the sealant and injecting
the liquid crystal

• 7 A sealing resin is next applied to the substrates, followed by plastic spacers that will give the liquid crystal cell the proper thickness. Next, the liquid crystal material is injected into the appropriate area between the two glass substrates. The thickness of the LCD cell is usually restricted to 5-25 micrometers. Because proper thickness is crucial for cell operation and because spacers don't always achieve uniform thickness, LCD makers sometimes put appropriately sized glass fibers or beads in the liquid crystal material. The beads or fibers cannot be seen by the naked eye. They help hold the cell at the proper thickness while the sealant material is setting.
• 8 To make LCDs more visible, polarizers are added. These are usually made from stretched polyvinyl alcohol films that have iodine in them and that are sandwiched between cellulose acetate layers. Colored polarizers, made using dye instead of iodine, are also available. Manufacturers glue the polarizer to the glass using an acrylic adhesive and cover it with a plastic protective film. They can make reflective polarizers, which also are used in LCDs, by incorporating a simple metal foil reflector.

In a typical LCD watch assembly, the shaded areas are etched away chemically to form the electrode pattern. The segments are turned on and off individually to either block or allow polarized light to pass through. When electric current is applied to a segment, the light is blocked and a dark spot is created on the reflecting screen.

Final assembly

• 9 After the polarizer film is attached, the unit is allowed to age. Finally, the finished glass display assembly is mounted to the circuit boards containing the control and drive electronics. Then, the entire package is ready to be mounted to the device using the LCD—laptop computer, fax machine, clock, etc.

SHIVAM GAUTAM-

How RAM is made!!

We all use memory modules for storage and for system purposes,one of the most important memory we use is RAM memory it makes our PC's to work frequently,But did u know how r thy made in this module we talk about their making.Just check it out!

Programming the SMT Computer

 

The first stage of producing a memory module is programming the SMT computer, along with collecting the appropriate chips to be installed on the PCB.

 

It takes around 20 - 30 minutes to setup the machines for their first test run. In that time, the factory engineers program the computer with all the different settings, calibrate the SMT line and feed the SMT line with all the chips required to produce the module.

Once the machine is setup, the next step is to do a test run. This is to ensure that the SMT computer was programmed correctly and if the SMT line if properly placing the chips on the PCB. Why go ahead and produce an entire batch of modules which may be faulty, if the machine was setup incorrectly?

 

Once the first quick test run is complete (just a single PCB is tested, consisting of six modules), one of the engineers will remove the PCB from the SMT line and reference it with a document. The document is used as a map to determine whether or not the computer was programmed correctly and if full production can go ahead or not.

 

Once the engineer is satisfied with the first test run PCB, a full production run can begin.

Applying unleaded solder paste and the initial chips

 

The very first stage of RAM production is applying solder paste to the blank PCB. In recent times, there has been a call for computer companies to start using totally lead-free products and TEAM is one of the many companies to stand up and listen.

 

Here is a close up of what a PCB looks like without anything installed onto it.

 

 

The machine below is responsible for applying the solder paste to the PCB.

 

 

The PCB is then sent on through to the next part of the SMT line.

 

 

At this point, the SMT will begin to place all of the tiny components onto the PCB.

 

 

 

 

As we mentioned in the introduction, TEAM make use of “high-speed” SMT lines. That means they are twice as fast as regular SMT lines. Many years ago we visited other memory factories and it’s amazing to see how much Japanese robotics have improved over the years, in terms of the raw speed these machines can place chips on the PCB.

 

With just three high-speed SMT lines, which in theory are equal to six, TEAM Group is able to produce almost one million memory modules per month.

 

Now that the components are installed on the PCB, the RAM chips are ready to be installed

Installing the RAM chips

 

The third stage in the production phase is installing the all important RAM chips onto the PCB.

 

In the photo below you can see the SMT line putting the PCB into place, ready to have the RAM chips installed on it.

 

 

Next up the robotic “arms” pick up the RAM chips from the tray and prepares to place them onto the PCB.

 

 

Here we can see the RAM chips being placed onto the PCB which believe me happens at an amazingly rapid pace. I would say some cameras would have a hard time taking photos of this part of production without at least some type of blurriness. Three RAM chips are installed at one time and then the robotic arm will go back to the tray and pick up another three RAM chips - and so the cycle goes.

 

With the SMT machines placing the chips so quickly and delicately onto the PCB, it was interesting to find out what precautions TEAM have in place in case of earthquakes, since Taiwan is prone to many earthquakes every year. The SMT lines can continue production through a 2 – 4 scale earthquake without any interruption and usually with no faulty modules as a result - anything higher and the machines have to be stopped and the modules on the line destroyed. TEAM uses a special type of flooring in their factory which is “rubbery” in construction. It is designed to absorb earthquake shocks. Also, the SMT machines have special feet which are designed to absorb the shock as well. Although, nothing can fully combat the power of Mother Nature and sometimes there is nothing any computer company can do to avoid wasting product. I asked if the SMT machines were able to detect an earthquake and then shut off instantly but that type of technology is yet to be developed.

 

 

The SMT line is intelligent enough to determine if a RAM chip is faulty or not. That is, if the pins on the back of the RAM chip are broken or is unable to make proper electrical connection with the PCB. Quite amazingly, these chips are automatically dropped into the pink tray you can see below. These chips will then be sent back to one of TEAM Group’s many chip suppliers to be replaced.

 

 

 

How long will it be before humans become totally redundant in a factory?

Putting the PCB into the Oven

 

Now that the module components and RAM chips have been installed onto the PCB, now it is time for the PCB to be put into an oven – literally!

 

The oven operates at anywhere from 200c to almost 300c and effectively solders all of the parts to the PCB.

 

 

 

Now the modules are ready to be examined.

After testing them several times these memory modules are ready to be packed and to be send to market.

SHIVAM GAUTAM-