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Protective display film with glass

A technology of display film and protective layer, applied in the field of protective display film with glass

Active Publication Date: 2021-12-07
3M INNOVATIVE PROPERTIES CO
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Problems solved by technology

However, many hard-coated films cannot withstand a fold event or impact event around a tight bend radius without exhibiting visible damage

Method used

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  • Protective display film with glass
  • Protective display film with glass
  • Protective display film with glass

Examples

Experimental program
Comparison scheme
Effect test

Embodiment 1-5

[0120] Samples of shape memory polyurethane were prepared in a roll-to-roll process, where the isocyanate was mixed with the polyol with catalyst using an inline dynamic mixer. Apply the solution to the moving web between two silicone release liners at an appropriate flow rate to achieve the desired final sample thickness. The polyurethane between the films was heated at 70°C and wound into rolls. The films were post baked at 70° for 24 hours before lamination to glass. The samples had a range of NCO equivalents reacted with 1.0 equivalent of -OH, as shown in Table 2, in order to obtain the desired glass transition temperature and crosslinking concentration. Table 2 shows the relative mass ratios of K-FLEX188 and Desmodur N3300 for samples 1-5. The coated material contained about 350 ppm dibutyltin dilaurate catalyst.

[0121] Table 2: Coating Compositions and Theoretical Crosslinking Concentrations

[0122]

[0123]

Embodiment 6-9

[0125] Similar to samples 1-5, but these polyurethane coatings were made with a mixture of isocyanates. For these examples, the polyurethane consisted of an aliphatic polyol (K-FLEX 188) reacted with a blend of multifunctional isocyanates (Desmodur N3300 and Desmodur N3400), prepared in the same manner as samples 1-5. The weight ratios of K-FLEX to Desmodur N3300 to Desmodur N3400 for samples 6-9 are shown in Table 3.

[0126] Table 3: Mixing ratios of polyurethanes used in Examples 6-9

[0127]

[0128] 1 Note that the N3400 isocyanate contains uretdione units which can react at elevated temperatures with excess OH in the polyol component to form allophanate groups. Therefore, the table contains two stoichiometric ratio columns. The first is to calculate the NCO / OH ratio based only on the existing NCO content in N3300 and N3400 at the beginning of the reaction. The NCO+UD / OH ratio is the ratio after reaction of the uretdione with the excess OH of the polyol.

Embodiment 10

[0130] Similar to samples 1-5, but this polyurethane coating was made with an alternative polyol, Fomrez 55-112, in order to achieve an even lower glass transition temperature. The polyurethane consisted of an aliphatic polyol (Fomrez 55-112) reacted with a polyfunctional isocyanate (Desmodur N3300), prepared in the same manner as samples 1-5. The weight ratio of Fomrez 55-112 to Desmodur N3300 for sample 10 is shown in Table 4. The oven was operated at 70°C and the samples were post-cured at 70°C for 24 hours.

[0131] Table 4: Coating Compositions and Theoretical Crosslinking Concentrations

[0132]

[0133] Polyurethane Layer Characterization

[0134] glass transition temperature

[0135] The glass transition temperature of polyurethane coatings was characterized using a Q800DMA from TA Instruments. The samples were cut into strips 6.35 mm wide and approximately 4 cm long. Measure the thickness of each membrane. The membranes were mounted in a Q800DMA tensile...

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Abstract

The present invention provides a display film comprising a transparent glass layer having a thickness of 250 microns or less, or in the range of 25 microns to 100 microns. A transparent energy dissipation layer is secured to the transparent glass layer. The transparent energy dissipating layer has a glass transition temperature of 27 degrees Celsius or less, a peak loss tangent of 0.5 or greater or in the range of 1 to 2, and greater than 0.9 MPa in the temperature range of -40 degrees Celsius to 70 degrees Celsius Young's modulus (E'). In a preferred embodiment, the transparent energy dissipating layer comprises a layer of cross-linked polyurethane or a layer of cross-linked polyurethane acrylate.

Description

Background technique [0001] Displays and electronic devices have evolved to bend, bend or fold and provide new user experiences. For example, these device architectures may include flexible organic light emitting diodes (OLEDs), plastic liquid crystal displays (LCDs), and others. [0002] Flexible and foldable display architectures represent a new paradigm for displays and offer a dramatic expansion of design freedom and new form factors that can deliver significant new value to consumers. One challenge is the outer protective layer on the display device, sometimes called cover glass, cover window film or cover window. More recent mobile displays have focused on using chemically strengthened glass sold under trade names such as Gorilla Glass and Dragon Glass. In use, these cover glasses tend to have a thickness in the range of at least 400um-500um total thickness and provide a glossy surface to the display with a low coefficient of friction and an appropriate coating of an a...

Claims

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Application Information

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Patent Type & Authority Patents(China)
IPC IPC(8): B32B17/06B32B27/40B32B27/28H01L51/52B32B7/12
CPCB32B7/12B32B17/06B32B27/40G06F1/1613G06F1/1652B32B2307/56B32B7/02B32B7/06B32B2250/04B32B27/308B32B27/34B32B27/325B32B2255/26B32B2307/748B32B2307/732B32B2307/412B32B2457/206B32B2457/202B32B2457/20Y02E10/549H10K50/844H10K2102/311B32B7/023B32B17/10B32B2315/08B32B2333/04B32B2375/00H10K59/12H10K77/111
Inventor 约瑟夫·W·V·伍迪戴维·S·汤普森凯瑟琳·A·莱瑟达尔瑞安·M·布劳恩迈克尔·A·约翰逊史蒂文·D·所罗门松约翰·J·斯特拉丁格柳德米拉·A·佩库洛夫斯基约瑟夫·D·鲁尔彼得·D·孔多
Owner 3M INNOVATIVE PROPERTIES CO