lcd panel printing factory

AGDisplays offers this screen print and glass service to give your display a finished and professional look. Add a hardened glass/touchscreen configuration with various ink options for logo customizations. Our custom branding allows for a unique finish to your product.Typically, screen print applications include display and touch panels;icons, lettering and logos;gauges and instrumentation and more. Screen printed images are printed by applying ink through a mesh screen to achieve a precise and crisp custom image or border.There are different cover glass thicknesses that range from ultra-thin for lightweight applications to thick and heavy for rugged applications. AGDisplays works with various types of glass and substrate options for which ever suites the display’s environment.

We offer a clean and efficient printing process with a high level of printing precision.Our screen printing is performed on a semi-automatic printer or an automated printer in a Class 1000 or 10,000 clean room, depending on project specification requirements. We offer customized color matching to meet your exact specification requirements.

For the screen printing process, we apply ink through a mesh screen to create the desired image. The ink is then cured to bond it to the substrate. This is a low-cost printing method which allows a durable and vibrant print. Screen printing allows more flexibility in terms of ink colors and thicknesses and is usually used to print on products like cover glass, display glass and EMI shielding.AGDisplays offers frit or epoxy/polyester inks for printing.

The frit ink is configured of three parts, giving the ink a high adhesion to the LCD’s glass substrate. Once applied, the glass is placed into a tempering oven to fuse the ceramic ink to the substrate. Overall, the three-part combination creates a permanent and rigorous print.

Optionally integrate a touchscreen so your display performance jumps immediately to intuitive usability and ease of access. AGDisplays offers a complete touchscreen solution for integration into your LCD. A durable PCAP touchscreen OCA bonded with a cover lens and a finished border.This touch sensor is embedded behind the glass and we carefully selected OCA bonding to increase LCD/component ruggedization when installed into your LCD stack up. The increased durability does not compromise on the integrity of the display itself. The ruggedized touch sensors and cover lens combo fit panels in the range of 3.5 to 32 inches. We add a touch sensor embedded behind a glass substrate for protection. Our designs increase durability without compromising integrity of the technology.

The injection of ITO glass — glass CLEANING and drying — PR COAT — PREBREAK — DEVELOP MAIN CURE — ETCHING — STRIP CLEAN — TOP COAT — UV CURE — curing — MANICURE) – cleaning (CLEAN) – applied orientation agent (PI) PRINT – CURING (MAIN CURE), cleaning (CLEAN), silk screen printing (SEAL/SHORT PRINTING) – baking (CUPPING FURNACE), SPRAY packing material (SPACER SPRAY) – para pressing (ASSEMBLY) – CURING (SEAL MAIN CURING)

In this process, two conductive glasses are stacked on top of each other, and sealed together, and cured to make a glass box with a specific thickness of clearance. The technology of box-making is one of the key technologies in LCD manufacturing. (Spacing of LIQUID crystal boxes must be strictly controlled)

SCRIBING — BREAK OFF — LC INJECTION — END seal — BREAK OFF — sharpen — VISUAL inspection — ELECTRICAL test — secondary cleaning special procedure (POLYGON) — BACK PRINTING — dry ink — POLARIZER ASSEMBLY — Thermal pressure — Inspection appearance test (FQC) — BIT PIN — FINAL test — PACKING — IN STOCK.

STONE provides a full range of 3.5 inches to 15.1 inches of small and medium-size standard quasi TFT LCD module, LCD display, TFT display module, display industry, industrial LCD screen, under the sunlight visually highlight TFT LCD display, industrial custom TFT screen, TFT LCD screen-wide temperature, industrial TFT LCD screen, touch screen industry. The TFT LCD module is very suitable for industrialcontrol equipment, medical instruments, POS system, electronic consumer products, vehicles, and other products.

Important technical improvements of LCD, such as LED backlighting and wide viewing Angle, are directly related to LCD. And account for an LCD display 80% of the cost of the LCD panel, enough to show that the LCD panel is the core part of the entire display, the quality of the LCD panel, can be said to directly determine the quality of an LCD display.

The production of civil LCD displays is just an assembly process. The LCD panel, the main control circuit, shell, and other parts of the main assembly, basically will not have too complex technical problems.

Does this mean that LCDS are low-tech products? In fact, it is not. The production and manufacturing process of the LCD panels is very complicated, requiring at least 300 process processes. The whole process needs to be carried out in a dust-free environment and with precise technology.

The general structure of the LCD panel is not very complex, now the structure of the LCD panel is divided into two parts: the LCD panel and the backlight system.

Due to the LCD does not shine, so you need to use another light source to illuminate, the function of the backlight system is to this, but currently used CCFL lamp or LED backlight, don’t have the characteristics of the surface light source, so you need to guide plate, spreadsheet components, such as linear or point sources of light evenly across the surface, in order to make the entire LCD panel on the differences of luminous intensity is the same, but it is very difficult, to achieve the ideal state can be to try to reduce brightness non-uniformity, the backlight system has a lot to the test of design and workmanship.

In addition, there is a driving IC and printed circuit board beside the LCD panel, which is mainly used to control the rotation of LCD molecules in the LCD panel and the transmission of display signals. The LCD plate is thin and translucent without electricity. It is roughly shaped like a sandwich, with an LCD sandwiched between a layer of TFT glass and a layer of colored filters.

LCD with light refraction properties of solid crystals, with fluid flow characteristics at the same time, under the drive of the electrode, can be arranged in a way that, in accordance with the master want to control the strength of the light through, and then on the color filter, through the red, green, blue three colors of each pixel toning, eventually get the full-screen image.

According to the functional division, the LCD panel can be divided into the LCD panel and the backlight system. However, to produce an LCD panel, it needs to go through three complicated processes, namely, the manufacturing process of the front segment Array,the manufacturing process of the middle segment Cell, and the assembly of the rear segment module. Today we will be here, for you in detail to introduce the production of the LCD panel manufacturing process.

The manufacturing process of the LCD panel Array is mainly composed of four parts: film, yellow light, etch and peel film. If we just look at it in this way, many netizens do not understand the specific meaning of these four steps and why they do so.

First of all, the motion and arrangement of LCD molecules need electrons to drive them. Therefore, on the TFT glass, the carrier of LCD, there must be conductive parts to control the motion of LCD. In this case, we use ITO (Indium Tin Oxide) to do this.ITO is transparent and also acts as a thin-film conductive crystal so that it doesn’t block the backlight.

The different arrangement of LCD molecules and the rapid motion change can ensure that each pixel displays the corresponding color accurately and the image changes accurately and quickly, which requires the precision of LCD molecule control.ITO film needs special treatment, just like printing the circuit on the PCB board, drawing the conductive circuit on the whole LCD board.

This completes the previous Array process. It is not difficult to see from the whole process that ITO film is deposited, photoresist coated, exposed, developed, and etched on TFT glass, and finally, ITO electrode pattern designed in the early stage is formed on TFT glass to control the movement of LCD molecules on the glass. The general steps of the whole production process are not complicated, but the technical details and precautions are very complicated, so we will not introduce them here. Interested friends can consult relevant materials by themselves.

The glass that the LCD board uses makes a craft also very exquisite. (The manufacturing process flow of the LCD display screen)At present, the world’s largest LCD panel glass, mainly by the United States Corning, Japan Asahi glass manufacturers, located in the upstream of the production of LCD panel, these manufacturers have mastered the glass production technology patents. A few months ago, the earthquake caused a corning glass furnace shutdown incident, which has caused a certain impact on the LCD panel industry, you can see its position in the industry.

As mentioned earlier, the LCD panel is structured like a sandwich, with an LCD sandwiched between the lower TFT glass and the upper color filter. The terminal Cell process in LCD panel manufacturing involves the TFT glass being glued to the top and bottom of a colored filter, but this is not a simple bonding process that requires a lot of technical detail.

As you can see from the figure above, the glass is divided into 6 pieces of the same size. In other words, the LCD made from this glass is finally cut into 6 pieces, and the size of each piece is the final size. When the glass is cast, the specifications and sizes of each glass have been designed in advance.

Directional friction:Flannelette material is used to rub the surface of the layer in a specific direction so that the LCD molecules can be arranged along the friction direction of the aligned layer in the future to ensure the consistency of the arrangement of LCD molecules. After the alignment friction, there will be some contaminants such as flannelette thread, which need to be washed away through a special cleaning process.

After the TFT glass substrate is cleaned, a sealant coating is applied to allow the TFT glass substrate to be bonded to the color filter and to prevent LCD outflow.

Finally, the conductive adhesive is applied to the frame in the bonding direction of the glass of the color filter to ensure that external electrons can flow into the LCD layer. Then, according to the bonding mark on the TFT glass substrate and the color filter, two pieces of glass are bonded together, and the bonding material is solidified at high temperatures to make the upper and lower glasses fit statically.

Color filters are very important components of LCD panels. Manufacturers of color filters, like glass substrate manufacturers, are upstream of LCD panel manufacturers. Their oversupply or undersupply can directly affect the production schedule of LCD panels and indirectly affect the end market.

As can be seen from the above figure, each LCD panel is left with two edges after cutting. What is it used for? You can find the answer in the later module process

Finally, a polarizer is placed on both sides of each LCD substrate, with the horizontal polarizer facing outwards and the vertical polarizer facing inwards.

When making LCD panel, must up and down each use one, and presents the alternating direction, when has the electric field and does not have the electric field, causes the light to produce the phase difference and to present the light and dark state, uses in the display subtitle or the pattern.

The rear Module manufacturing process is mainly the integration of the drive IC pressing of the LCD substrate and the printed circuit board. This part can transmit the display signal received from the main control circuit to the drive IC to drive the LCD molecules to rotate and display the image. In addition, the backlight part will be integrated with the LCD substrate at this stage, and the complete LCD panel is completed.

Firstly, the heteroconductive adhesive is pressed on the two edges, which allows external electrons to enter the LCD substrate layer and acts as a bridge for electronic transmission

Next is the drive IC press. The main function of the drive IC is to output the required voltage to each pixel and control the degree of torsion of the LCD molecules. The drive IC is divided into two types. The source drive IC located in the X-axis is responsible for the input of data. It is characterized by high frequency and has an image function. The gate drive IC located in the Y-axis is responsible for the degree and speed of torsion of LCD molecules, which directly affects the response time of the LCD display. However, there are already many LCD panels that only have driving IC in the X-axis direction, perhaps because the Y-axis drive IC function has been integrated and simplified.

The press of the flexible circuit board can transmit data signals and act as the bridge between the external printed circuit and LCD. It can be bent and thus becomes a flexible or flexible circuit board

The manufacturing process of the LCD substrate still has a lot of details and matters needing attention, for example, rinse with clean, dry, dry, dry, ultrasonic cleaning, exposure, development and so on and so on, all have very strict technical details and requirements, so as to produce qualified eyes panel, interested friends can consult relevant technical information by a search engine.

LCD (LC) is a kind of LCD, which has the properties of light transmission and refraction of solid Crystal, as well as the flow property of Liquid. It is because of this property that it will be applied to the display field.

However, LCD does not emit light autonomously, so the display equipment using LCD as the display medium needs to be equipped with another backlight system.

First, a backplate is needed as the carrier of the light source. The common light source for LCD display equipment is CCFL cold cathode backlight, but it has started to switch to an LED backlight, but either one needs a backplate as the carrier.

CCFL backlight has been with LCD for a long time. Compared with LED backlight, CCFL backlight has many defects. However, it has gradually evolved to save 50% of the lamp and enhance the transmittance of the LCD panel, so as to achieve the purpose of energy-saving.

With the rapid development of LED in the field of lighting, the cost has been greatly reduced.LCD panels have also started to use LED as the backlight on a large scale. Currently, in order to control costs, an LED backlight is placed on the side rather than on the backplate, which can reduce the number of LED grains.

On the transparent diffuser plate, point-like printing can block part of the light. The LED backlight on the side drives the light from the side of the diffuser plate, and the light reflects and refracts back and forth in the diffuser plate, distributing the light evenly to the whole surface. Point-like printing blocks part of the light, screening the light evenly like a sieve.

At the top of the diffusion plate, there will be 3~4 diffuser pieces, constantly uniform light to the whole surface, improve the uniformity of light, which is directly related to the LCD panel display effect. Professional LCD in order to better control the brightness uniformity of the screen, panel procurement, the later backlight control circuit, will make great efforts to ensure the quality of the panel.

Since the LCD substrate and the backlight system are not fixed by bonding, a metal or rubber frame is needed to be added to the outer layer to fix the LCD substrate and the backlight system.

After the period of the Module, the process is completed in LCM (LCDModule) factory, the core of this part of the basic does not involve the use of LCD manufacturing technology, mainly is some assembly work, so some machine panel factories such as chi mei, Korea department such as Samsung panel factory, all set with LCM factories in mainland China, Duan Mo group after the LCD panel assembly, so that we can convenient mainland area each big monitor procurement contract with LCD TV manufacturers, can reduce the human in the whole manufacturing and transportation costs.

However, neither Taiwan nor Korea has any intention to set up factories in mainland China for the LCD panel front and middle manufacturing process involving core technologies. Therefore, there is still a long way to go for China to have its own LCD panel industry.

Fine Cause"s pad printing machine imported to industrial I.O.T., combine smart factory App, assist you to implement production management goals through synchronous monitoring.

1 piece per minute (input/output not included; L corner and up-side-down U shape cavity printed separately; 4 times printing each of 45° and 90°); pringting density at the up-side-down U shape cavity is +/-0.2 mm

A wide variety of lcd with silk print options are available to you, You can also choose from original manufacturer, odm lcd with silk print,As well as from tft, tn, and va.

LCD vs DLP technology: What are the differences between these resin 3D printing technologies? The liquid resin is contained within a vat, or tank, cured against a build platform, which slowly rises out of the tank as the part is formed, layer by layer. These two 3D printing technologies are quite similar, but here is the main difference: the light source.

LCD printing: A UV light coming from an array of LEDs shining through an LCD flashes complete layers at the resin tank. A screen is used to mask the entire image, only revealing the current layer for curing. LCD 3D printing is a cost-effective resin manufacturing technique to get big and detailed functional parts. This 3D printing technology focuses on mass manufacture and large component 3D printing for resin materials thanks to 3D printers with larger build tray developed by Photocentric for example.

DLP printing: The digital light projector is the light source of DLP 3D printers. The DMD (Digital Micromirror Device) is a component made of thousands of micromirrors that are contained within a semiconductor chip matrix. These micromirrors are used for navigating the light beam projected by the digital light projector.

High precision screen printing machine used in South Korean sole proprietorship factory in Shandong province, which specialized in screen printing on DVD pan...

High precision screen printing machine used in South Korean sole proprietorship factory in Shandong province, which specialized in screen printing on DVD pan...

Advancements in 3D printing, along with product complexity and different types of available processes have made it challenging to select the right 3D printer for high-volume manufacturing. Digital Light Processing (DLP) and LCD are two commonly implemented resin-based 3D printing technologies. The following compares DLP vs. LCD 3D printers, their unique features, and the subtle differences.

Resin-based 3D printing technologies (also known as vat-polymerization) such as stereolithography or SLA, DLP, and LCD involve curing a photosensitive resin using a light source that helps solidify the resin and create the printed product layer-by-layer. The post-processing steps include cleaning the excess uncured resin and exposure to UV light for final curing. However, the major difference lies in using different light sources for curing the resin.

Next-generation DLP and LCD 3D printing platforms built on LuxCreo’s LEAP™platform are delivering new capabilities that simplify manufacturing and enable high-volume production. LuxCreo’s LEAP™platform outperforms current DLP, LCD, and SLA printers by developing and tuning software, hardware, and resin to deliver new capabilities: high throughput, maximum batch size, and DigitalPolishing™.

DigitalPolishing™ eliminates 90% of the post-processing polishing labor allowing manufacturers to print clear, transparent parts with no polishing required, eliminating the Achilles heel of SLA, DLP, and LCD vat-polymerization systems.

Applications:With DLP printers, the number of pixels does not change and remains the same regardless of the size of the image. Therefore the precision of printing is impacted depending on the size of the model. The narrower the size of the model, the higher the precision. That is why DLP 3D printers work best for accurate and precise printing of small-sized models with details as fine as .05 mm and are widely used for 3D printing of dental implants, jewelry, footwear, and others.

Speed:The higher intensity of light facilitates faster printing. By utilizing a wavelength of 405 nm with light intensity as high as 20-30 mW/cm2, DLP 3D printers can cure an entire layer at once and require less time to print more parts in a batch. Lower DLP wavelengths, including 385nm, are used to improve clear part accuracy and open up other traditional SLA resins for use on DLP. However, there are advantages and disadvantages to selecting 405nm or 385nm depending on if speed, precision, and/or longevity are the priority.

Pricing:DLP 3D printers traditionally are higher-priced printers vs. LCD printers. For this higher price, industrial Smart Factory DLP 3D printers are designed for volume manufacturing with consistent batch-to-batch and machine-to-machine production. Smart Factory DLP 3D printers provide higher speed, larger build volumes, longer life, and higher precision across large build areas versus LCD printers.

How it works:Unlike a DLP printer which is used as a projector, an LCD printer does not use a projector and deploys an array of UV LEDs as the light source and an LCD to mask (block) UV light allowing only select areas to be cured in the layer. Inexpensive LCD printers utilize cheap light sources that have low uniformity and produce light that is not columnated (aligned with the print area). This results in pixel distortion. LCDs also have a much shorter life versus DLP light engines requiring owners to frequently replace LCD screens, increasing consumable cost versus DLP printers.

Print Quality:Higher quality LCD can produce high-quality prints; however, as LCDs become larger, they have limits on uniformity, and batch to batch, machine to machine variability becomes an issue. Less expensive LCD 3D printers have challenges controlling distortion caused by a lack of LED array uniformity and alignment. If these technical challenges are not addressed, the print quality can be and be worse than in DLP printers.

Applications:Compared to FDM 3D printers, LCD printers offer better printing quality for the same price and are therefore popular for chairside dental or desktop applications. The lower cost barrier makes these printers popular for adopting 3D printing across dental, jewelry, engineering, hobbyists, and other industries.

Speed:Compared to DLP 3D printers, LCD printers are slower and are low in intensity in the range of 3-5 mW/cm2. Conventional LCD 3D printers can not print with high viscosity.

Pricing: LCD printers are created as an affordable alternative to their advanced 3D printing counterparts. With an easily replaceable LCD panel, these printers are customized for small spaces and are desktop-sized for ease of use.

When deciding between DLP vs. LCD 3D printers, a popular perception is that the DLP printers are better than the LCD. However, on a budget, next-generation LCD 3D printers can be the right first step into resin 3D printing, depending on the application-specific applications.

Next-generation DLP and LCD 3D printing platforms built on LuxCreo’s LEAP™platform are delivering new capabilities that simplify manufacturing and provide on-demand access to Smart Factory volume production. LuxCreo’s LEAP™platform outperforms current DLP, LCD, and SLA printers by developing and tuning software, hardware, and resin to deliver new capabilities: high throughput, maximum batch size, and DigitalPolishing™.

LuxCreo’s Smart Factory DLP and LCD 3D printer solve the above problems with traditional DLP and LCD 3D printers supporting repeatable high throughput production of high-performance and high-viscosity materials. LuxCreo’s Smart Factory DLP and LCD 3D printers open up a new category of 3D printers that deliver the fastest, most economical path to volume production.

To improve the performance of DLP or LCD 3D printers, it is necessary to get control over design, software, printer, and resins. LuxCreo’s integrated Smart Factory 3D printing solutions facilitate clear, transparent, faster, and accurate printing with both DLP and LCD printers while also providing the fastest, most economical path to volume production. Our advanced range of Smart Factory DLP 3D printers enables in-house production and provides contract 3D printing services through cloud-connected smart factories.

Luxcreo’s integrated suite of high-performance 3D printing materials, 3D printers, and software help manufacturers simplify high-viscosity 3D printing with Smart Factory DLP and LCD 3D printers. Our intuitive software tuned to our materials and our DLP and LCD 3D printers ensure uniformity, consistency, and accuracy in high-throughput and high-yield manufacturing batch to batch and machine to machine to achieve the highest, most economical production throughput.

Or remove the resin tank, clean the LCD panel and the bottom of the resin tank film; wipe them with alcohol and then with a dry paper towel. (Note: touch ONLY the glass part of the screen, the area covered with black tape should not be touched).

Replace the Resin Tank if there is any damage. Remove the Resin Tank and clean the surface of the LCD and the underside of the Resin Tank, wipe first with alcohol, then with a dry paper towel (note that you can only touch the glass portion of the screen and avoid pressing against the black tape).Increase cooling time appropriately

Digital light processing (DLP) and liquid crystal display (LCD) 3D printing have similarities to stereolithography (SLA) 3D printing; each of these technologies uses a light source to cure the resin. A projector is used to cure photopolymer resins in DLP printing and UV LEDs are projected through and LCD screen for LCD 3D printing.

The process of printing using these technologies can be “top-down” or “bottom-up”. In “top-down” printing, the object being printed is lowered into the resin and returns to one layer lower than previous after each layer is cured. In “bottom-up” printing, the object being printed is pulled out of the resin and returns to one layer higher than the previous after each layer is cured. The process is repeated layer by layer until the shape is built.

There are two ways how to perform a factory reset. The procedure depends on your firmware version. First, find out your firmware version number by navigating to LCD menu - support - Firmware. Once you know the version number, use the corresponding instructions below. We recommend keeping your printer"s firmware up to date.

Immediately press and hold the Control knob until "Factory reset" is displayed on the LCD display (after 2-3 seconds). Depending on your settings, you will also get a sustained beep.