EP2888104A1 - Glass substrate strip - Google Patents

Abstract

The invention relates to a glass substrate strip made of a multiplicity of thin-glass segments which are positioned and fixed on an adherent foil. The thin-glass segments are fixed on the adherent foil over the entire area thereof, by way of the entire edge region thereof or by way of parts of the edge regions thereof. The glass substrate strip can comprise lateral transport bands or else coding fields. For storage, it is plated in meandering fashion or is rolled up, and it serves not only for transport and storage but also as a carrier strip in processing steps for the thin-glass segments.

Description

 Glassubstratoana

The invention relates to a glass substrate tape consisting of a plurality of thin glass blanks on an adhesive film.

For a variety of applications such. In the field of consumer electronics, for example as cover glasses for semiconductor modules, for organic LED light sources or for thin or curved display devices or in areas of regenerative energy or energy technology, such as for solar cells, thin glass is increasingly used. Examples include touch panels, capacitors, thin-film batteries, flexible printed circuit boards, flexible OLEDs, flexible photovoltaic modules, e-papers or micro-electro-mechanical systems (MEMS) or micro-opto-electro-mechanical systems (MOEMS).

Thin glass is becoming more and more of a focus for many applications due to its excellent properties such as resistance to chemicals, thermal shocks, gas tightness, high electrical insulation, coefficient of expansion, flexibility, high optical quality and light transmission or high surface quality with very low roughness due to a fire polished finish Surface of the two thin glass sides. Thin glass is understood here to mean thin glass with thicknesses of less than approximately 1.2 mm, up to thicknesses of 15 μm and smaller.

Due to its flexibility, thin glass is increasingly rolled up as a thin glass after production and stored as a glass roll or transported for packaging or further processing. In a roll-to-roll process, the thin glass can also be rolled up after an intermediate treatment, for example a coating or finishing of the surface, and fed to a further use. The rolling of the glass involves the advantage over a storage and the transport of flat spreading material the advantage of a more cost-effective compact storage, transport and handling in further processing.

It is also to be avoided that particulate inclusions between the thin glass layers in a glass roller lead to damage. On the one hand, they can scratch the surface, which is assisted in particular by a displacement or a movement of the thin glass layers with one another or relative to one another, or they can lead to a crack or break by causing a punctiform pressure load. Also, dirt particles on the thin glass surface can affect a subsequent coating or packaging qualitatively or procedurally. Various solutions have become known to wind a continuous glass ribbon on a roll in order to coat it in a later treatment step in the roll-to-roll process or to assemble.

 Thus, WO 87/06626 proposes the use of a glass roll for a process for coating thin glass in a roll-to-roll process. Between a continuous thin glass band between the glass layers one or more layers of a glass non-abrasive material, such as a plastic film is provided. The plastic film may be a polymer such as polyester or polyethylene and may also contain an embossed pattern to protect the metal or metal oxide coating on the glass. To coat the glass ribbon, the glass ribbon and plastic film are separated. After coating, the glass ribbon is rewound with a new plastic film as an intermediate layer.

The cutting of the glass ribbon into the appropriate blank dimensions is then carried out in a later process step after the coating of the thin glass. The disadvantage here is a correspondingly high cutting waste on refined thin glass. Compared to the thin glass raw material, the refined thin glass has a significantly higher value. Also, the coated or finished thin glass cut waste may not be easily returned to the thin glass manufacturing process by meltdown.

US 3,089,801 discloses, in order to protect and support the handling of thin glass as a continuous glass ribbon in subsequent treatment steps, the use of wrapping paper or aluminum foil coated with a lightly adhering adhesive layer and removably adhered to the glass. As a result, the glass is to be given greater strength during bending and handling and thus also protected from breaking when rolled up. The disadvantage is that the adhesive layer can not always be solved residue-free and thus affects or prevents the subsequent use of the thin glass.

US 201 1/0171417 proposes to protect a thin-glass strip from splinters

or breaking lamination of the thin glass between two plastic layers prior to rolling into a glass roll. It is proposed a glued on one side of the thin glass carrier layer which projects beyond the edge of the thin glass. On the other side of the thin glass, a cover layer is adhesively glued over the entire surface or only in the region of the edges and over the edges, so that the edges are laminated between two plastic layers and the thin glass can then be rolled up. In the event of later release of the covering layer, an excessively high defor- To avoid mation of the carrier layer, the carrier layer should have an elongation of less than 10% under a tensile strength of 50 MPa. There are proposed various materials, polyethylene and soft vinyl chloride are excluded among others as unsuitable. In this proposed solution adhering residues of the adhesive or an influence of the glass surface by the adhesive are extremely disadvantageous. Also, this solution involves a material and cost-intensive packaging effort. Furthermore, there is a high risk of damage to the thin glass when loosening the adherent two plastic layers.

The US 201 1/0023548 also proposes a double-sided enclosure of the thin glass for protection and handling in subsequent processes. The two-sided or one-sided cover made of a heat-resistant film is in this case limited in particular to the edge region, but may also extend over the entire surface of the thin glass. The thin glass may be a continuous rolled up glass ribbon or a single glass sheet. As a heat-resistant film, a metal, a silicone or a polymide is proposed, which withstands temperatures up to 300 ° C. The border is molded directly onto the thin glass or glued on with an acrylic adhesive. The disadvantage is that this is a difficult to detach compound. When removing the protective skirt, there is a high risk of undesirable damage to the thin glass. In the protection and the enclosure of individual slices of thin glass, these can be stacked by means of the enclosure, the border at the edge serves as a spacer, so that an air gap arises between the thin glass layers. The disadvantage here is that the thin glass layers can vibrate or sag and are thus exposed to a risk of breakage. On the other hand, it comes on the surface of the glass on prolonged storage in areas in contact with a protective film to other signs of aging as in areas without contact with a protective film. This can have undesirable and visible effects in later coating or use of the glass.

The object of the invention is therefore to avoid the disadvantages described above and to provide protection for thin glass during transport and handling in subsequent processes available, which is inexpensive and easy to handle.

The invention solves this problem with the features of claim 1 and claims 18 and 19. Further advantageous embodiments of the invention are described in the dependent claims 2 to 17. According to the invention, a glass substrate tape is provided on which at least two, preferably a plurality of individual thin-glass panes, ie thin glass blanks, are fixed on a tape made of an adhesive film. The individual thin-glass panes can undergo subsequent processing steps in this fixation, whereby they are securely held and protected. The adhesive film serves as a carrier tape.

Processing steps are, for example, grinding, polishing, washing, printing, a photolithographic process, the application of one or more coatings such as an antireflective coating, easy-to-clean coating, an electrically conductive coating, a lamination process or else the assembly with, for example electronic component. Advantage of the glass substrate tape according to the invention is the free accessibility of the entire surface on one or the other side of the thin glass blank, a simple, cost-effective handling of a variety of individual blanks made of thin glass with an integrated secure packaging option in the form of a roll or a meander-shaped stacking. On the other hand, the thin glass is secured in the event of breakage or chipping, so that resulting fragments or fragments can not become a disruptive factor in a subsequent process step, but remain safely on the adhesive carrier tape.

Furthermore, the thin glass blanks can be easily and easily loosened again from the adhesive carrier film without residues remaining on the glass surface. Since in the packaged state as a roll or stack both surfaces of the thin glass blanks are contacted in the same way with the film, it can not lead to an undesirable different aging and change of the glass surface. When packaged, the adhesive film serves as protection for the transport and storage of the thin glass panes.

A further advantage of the invention is that the cutting of the individual thin glass panes into specified dimensions takes place from the not further refined glass strip. The blank waste thus still has a low value added and can also be easily recycled as a raw material in the melting and manufacturing process of the thin glass. Cost-intensive follow-up processes are only carried out on the occasional smaller thin-glass blanks. However, according to the invention, they can also be carried out in the cost-effective roll-to-roll process as in the continuous glass strip. In doing so, they are securely fixed and do not have to be relocated during processing, which always means a high risk of breakage and cracks in thin glass. The thin glass is produced in a known manner by the down-draw method or the overflow drawdown method (cf., for example, WO 02/051757 A2 for the down-draw method and WO 03/051783 A1 for the overflow down-draw method). The shaped and drawn endless belt is wound up on a glass roll and cut to length. The thin glass blanks are separated from the glass roll or immediately after drawing from the glass ribbon.

The thin glass can in this case consist of any suitable type of glass, in particular of a borosilicate glass, aluminoborosilicate glass, soda lime glass, aluminosilicate glass, or a lithium aluminum silicate glass. In order to reduce the risk of breakage and the formation of cracks during rolling up and to ensure good adhesion to the adhesive carrier foil, the surface is fire-polished and very smooth. It has been shown that, in particular in the thickness range of less than 100 μm, a particularly smooth surface is created by the thin drawing off of low-alkali glasses.

The thin glass blanks, which are positioned and fixed according to the invention on the glass substrate tape, usually have a thickness of less than or equal to 350 .mu.m, preferably less than or equal to 100 .mu.m, preferably less than or equal to 70 .mu.m, more preferably less than or equal to 50 .mu.m, particularly preferably less than or equal to 25 .mu.m at least 5 μηη, preferably of at least 10 μηη, more preferably of at least 15 μηη. Preferred thin glass thicknesses are 15, 20, 25, 30, 35, 50, 55, 70, 80, 100, 130, 145, 160, 190, 210, 280 μηι.

The thin glass blanks can have any shape in their areal spread, preferred are square, rectangular or round blanks.

The thin glass blanks preferably have a fire-polished surface on at least one surface of their two sides, preferably on the surface of both sides.

In order to ensure a secure fixation or adhesion of a thin glass blank on the Ädhäsionsfolie and to easily solve the adhesive film from the thin glass surface, the square RMS Rq on the surface of at least one of its two sides is preferably at most 1 nanometer, preferably at most 0.8 nanometers, more preferably at most 0.5 nanometers. The average roughness Ra is at the surface of at least one of its two sides at most 2 nanometers, preferably at most 1, 5 nanometers, more preferably at most 1 Nanometers, each on a gauge length of 670 μηι. In a preferred embodiment, these roughness values characterize the surface of both sides of the thin glass blanks. In particular, however, the surface of a thin glass blank which adheres to the adhesive film is characterized by these roughness values.

In a preferred embodiment, the adhesion effect of the film to the glass surface on one side of the film and / or the thin glass is higher than on the other side or the static friction of the adhesion film on the glass surface is higher than on one side of the adhesion film and / or the thin glass the other side. This has the advantage that, when the glass substrate tape is rolled up or collapsed, the opposite surface of the thin glass not contacted by the adhesive film, which comes into contact with the next layer of the adhesive film, assumes a weaker adhesion with this. This facilitates the reeling or loosening of the glass substrate tape from a stack. The compound adhesive film to the protected glass surface can thereby remain stable unimpaired when rewinding or loosening the glass substrate tape from a stack.

The side of the adhesive film, which has a higher adhesion effect in cooperation with a fire-polished thin glass surface and therefore in contact with a thin glass surface in the rolled-up state of the glass substrate tape, has an adhesion frictional force F _s in the range of greater than 20 N, preferably greater than 50 N. Under adhesion force is the force peak understood that must be overcome so that the adhesive film sets relative to the thin glass surface in motion.

The opposite side of the adhesive film, which has a comparatively lower adhesion in cooperation with a fire-polished thin glass surface and is in contact with a thin glass surface only in the rolled or collapsed state of the glass substrate belt, has an adhesion frictional force F _s in the range of 0.10 to 10N. preferably from 0.10 to 2 N. Furthermore, the opposite side of the adhesive film, which in cooperation with a fire-polished thin glass surface has a lower adhesion effect compared frictional force F _D in the range of 0.10 to 5 N, preferably from 0.10 to 1, 5 N. Frictional force is understood to be the averaged force via a test path after overcoming the stiction which is necessary for a relative movement between the intermediate material and the glass surface.

The values for the static friction F _s and the friction force F _D apply in each case in accordance with a measurement according to DIN EN ISO 8295 on an electromechanical universal testing machine the Schenk Trebel in the standard climate at 23 ° C and 50% relative humidity according to DIN 50 014 with a normal force of 1, 96 N.

The material for the adhesive film is any material which is suitable as an adhesive film on at least one surface. Preference is given to polyethylene (PE), such as a coextruded polyethylene adhesive film, or a polyvinyl chloride (PVC), such as a soft PVC adhesive film. It may also be a composite film, wherein a film of the composite is preferably a PE or PVC, for example, a composite film of a polyethylene terephthalate (PET) and soft polyvinyl chloride (plasticized PVC).

The thickness of an adhesive film is in the range of less than 6 mm, preferably in the range of less than or equal to 2 mm, more preferably less than or equal to 1 mm, most preferably less than or equal to 0.5 mm, especially in the range of 30 to 350 μm, preferably 60 to 200 μm.

Adhesive film is understood to be a soft plastic film with a very smooth underside, which adheres to a thin glass surface without adhesive. In contrast to an adhesive film, it can be removed from the substrate in a matter of seconds even after a relatively short time without aids and without leaving any residue. The effect of adhesion or attachment force is mainly due to the so-called van der Waals forces, i. weak attractive forces that exist between the molecules in the surface of the thin glass and the adhesive film and the stronger, the smoother the surfaces are.

In one embodiment, the adhesive film is an electrostatically charged adhesive film.

In one embodiment, the adhesive film has on its adhesive surface a microfine structure, for example in the form of very small suction cups, which assists adhesion to the thin glass surface.

In one embodiment, the adhesive sheet material may be an adhesive textile, such as a polyester fabric, provided with an adhesive coating on the contact surface with the thin glass. This coating can also be an adhesive which ensures a flat, even repeatable removability of the adhesive textile. It is advantageous here that, for example, during a treatment or processing of the thin glass steps in the roll-to-roll method, the glass substrate tape is kept under a certain tension can, without deforming the carrier film. This allows the thin glass blanks to be positioned precisely.

For applications in a subsequent processing step, which is carried out at higher temperatures, for example at 150 to 500 ° C, the adhesive film may be in one embodiment, a metal foil such as an aluminum foil, which is provided on the contact surface to the thin glass with an adhesive coating. This coating can also be an adhesive which ensures a flat, even repeatable detachability of the adhesive film.

Such an adhesive coating is especially a butyl rubber or silicone rubber, but may also be, for example, a silicone gel, urethane rubber, natural rubber, butadiene rubber, ethylene-propylene rubber, chloroprene rubber, nitrile rubber, nitrile isoprene rubber, acrylic rubber, fluororubber, chlorosulfonated polyethylene, chlorinated polyethylene or epichlorohydrin rubber.

The adhesive film can also be coated on one side with, for example, a cover film, cardboard, a non-adhesive plastic, a fabric or a metal film. Especially the coating with a fabric ensures a stable transport during subsequent process steps and prevents unwanted stretching, stretching or deformation of the adhesive carrier film in the transport during the process steps and also facilitates later detachment of the thin glass panes of the adhesive film. The coating can also be a compressible material such as a compressible cardboard or a

Foam sheet, e.g. from a polyolefin foam, in particular a crosslinked polyolefin foam, or else a foam film made of polyethylene or polyurethane. As a result, special advantages for the glass substrate web can be created as a roll material by the role is stable in itself against lateral displacement and the thin glass substrates are advantageously protected and stored in the role. The coating may each be a cover which is bonded to and peelable by the adhesive force of the film or a firmly applied non-peelable coating.

The thickness of such a coated adhesive film is in the range of less than 6 mm, preferably in the range of less than or equal to 2 mm, more preferably less than or equal to 1 mm, most preferably less than or equal to 0.5 mm. In a very preferred embodiment, the thickness of the adhesive film is adjusted so that the neutral phase lies between tensile and compressive stresses in the rolled state of a thin glass substrate and an adjacent film in the adhesive layer connecting both layers. As a result, both surfaces are free of forces and it is a permanent installation of the thin glass blanks during unrolling of the glass substrate tape prevented. For this purpose, the thickness of the adhesion foil (D _p ) is taking into account the thickness of the thin glass substrates (D _g ), the Poisson's number of adhesion foil (v _p ), the Poisson's number of thin glass substrates (v _g ), the modulus of adhesion of the adhesion foil (E _p ) and of the modulus of elasticity of thin glass substrates (E _g ) is determined as follows:

The adhesive film may cover the entire first or second surface of the thin glass blanks. This offers the advantage that the thin glass blanks can be treated in one process step on their entire first or on their entire second surface. In another embodiment, however, the adhesion film can also cover only the entire edge region or sections of the edge region of the first and / or second surface of the thin glass blanks, for example the edge region of two opposite edges of the thin glass blanks. This offers the advantage that the thin glass blanks can be treated simultaneously on their first and second surfaces in one process step.

In each embodiment, the adhesion film can project beyond the edge region of the first and second surfaces of the thin glass blanks perpendicular to the longitudinal direction of the glass substrate tape and form a projection. The supernatant can also serve as a transport strip to move the glass substrate belt with a drive device and / or to steer. For example, the glass substrate belt can be driven and moved with the aid of one or two interacting pressure rollers, which forcefully exert a drive or steering force on the projection. The projection can also have recesses, in particular punched out, in which form fit the teeth of a gear or toothed belt engage and exert a driving force by which the glass substrate belt is driven and moved.

The supernatant may also have a coding, via which the position and specification of the glass substrate strip or the individual thin glass blanks can be read. However, the coding can also be perpendicular to the running direction of the strip, ie transversely to the glass tube. stratband be mounted between fixed on the Adhäsungsfolie thin glass blanks. The coding can be applied directly to the adhesive film, or special coding fields can be applied to the adhesive film, to which the coding is applied, for example printed. The coding fields can be printed or affixed label fields which are easy to label or print. If necessary, they can also be printed or affixed with coding. For adhesion, the adhesion of the adhesive film can be used.

The glass substrate tape is layered meandering for storage or transport as a whole or rolled up into a compact roll. The meandering layering provides gentle storage for the thin glass blanks since the blanks do not provide bending forces, i. Be subjected to tensile forces. The role has the advantage that the subsequent treatment or processing of the thin glass blanks in a roll-to-roll process can be carried out in a comfortable manner and the glass substrate strip can be held under a certain tension for exact alignment of the thin glass blanks.

The invention further includes a method of making a glass substrate tape comprising the steps of making a thin glass tape in a down-draw or an overflow down-draw method, separating thin glass blanks from the thin glass tape, and positioning and contacting the thin glass blanks on the adhesive film.

The thin glass ribbon is produced endlessly by a down-draw or overflow down-draw method in a known manner. Before separating thin glass blanks from the thin glass band, this can still be prefabricated, for example by separating the lateral edge sections or a process for relaxing thermal stresses. It can also be wound up on a roll. The separation of the thin glass blanks from the thin glass ribbon can then take place directly from the endless strip after the drawing process or from a glass roll. The separation is done with known technologies such as a laser cutting process or by cutting tool by scribing and breaking. The separated thin glass blanks are then stored by means of a gripping and positioning device, such as a robot arm, positionally accurate on the prepared adhesive film. The adhesive film is wound from roll to a roll and forms with a slight bias a flat smooth surface for receiving the thin glass blanks. Optionally, the adhesive film can then be firmer with a pressure roller be connected to the surface of the thin glass blanks. The adhesive film coated with the thin glass blanks is then rolled up or folded together in meandering fashion.

Before contacting the thin glass blanks with the adhesive film, these are dirt, dust and grease-free, which is especially true after pulling the thin glass. Before sticking, the adhesive film is spread flat and clean in order to apply the thin glass blanks over the entire surface and without wrinkling. Wrinkles in the film would result in undesired pressure areas, e.g. later in the rolled up condition. If a carrier paper is connected to the adhesive film, this is drawn off in the area of the overlay of the respective thin glass blanks to be placed on top and, for example, taken up by a roll.

The contacting of the thin glass blanks with the adhesive film is preferably dry. However, if the thin glass blanks on the adhesive film aligned, corrected and can be raised several times if necessary, the contacting is also wet. In this case, the surfaces to be contacted of the thin glass blanks and of the adhesion film are moistened uniformly with a special assembly liquid or with a solution of water and a rinsing agent. After contacting the thin glass blanks, the adhesive film is pressed piece by piece, usually by means of one or more pressure rollers and wrinkles, the air and optionally the liquid streaked under the film. In order to ensure the best possible adhesion of the adhesive film and to avoid the formation of bubbles, in particular when using a pressure-sensitive adhesive, the contacting temperature is between 5 and 45 ° C, preferably at 10 ° C and 25 ° C.

Especially with a glass substrate tape, which is rolled up into a roll, the neutral phase between tensile and compressive stress in the rolled-up state is placed in the adhesive layer. As a result, a permanent bending of the thin glass blanks during unrolling of the glass substrate tape is prevented. In order to position the neutral phase in the interface between thin glass substrates and adhesive film, the modulus of elasticity, the Poisson's number and the thickness of the adhesion film and the thin glass blanks are matched to one another. The following mathematical relationship applies to the determination of the thickness of the adhesion foil: D _{p is} the thickness of the adhesive film, D _{g is} the thickness of the thin glass substrates, v _{p is} the Poisson number of the adhesive film, v _{g is} the Poisson number of the thin glass substrates, E _{p is} the modulus of adhesion of the adhesive film and E _{g is} the modulus of elasticity of the thin glass substrates.

The invention further includes the use of a glass substrate tape for packaging or treating the first and / or second surface of the thin glass blanks in a continuous process. The advantage here is that not the entire glass ribbon must be treated or refined accordingly and the glass waste is expensive in the subsequent cutting and possibly also no longer melted. Also, the costly cutting process on a glass band up to 1000 m long or longer at this stage of the process chain is eliminated and the customer can be supplied directly with ready-cut thin-glass masses. Such preparation or treatment of one or both surfaces of the thin glass blanks are for example grinding, lapping, polishing, washing,

Printing, a photolithographic process, the application of one or more coatings such as an antireflection coating, easy-to-clean coating, anti-fingerprint coating, Antiglare coating, an electrically conductive coating, a lamination process or the assembly with, for example an electronic component.

The following detailed embodiments and examples are intended to describe the invention in more detail.

1 shows the execution of round (FIG. 1 a) and square (FIG. 1 b) thin-glass blanks on an adhesive film with full-area contact of a first or second thin-glass surface.

 2 shows the execution of round (FIG. 2a) and rectangular (FIG. 2b) thin-glass blanks on an adhesive film with contact of the respective entire edge region of a first or second thin-glass surface.

 3 shows the execution of round (FIG. 3a) and rectangular (FIG. 3b) thin-glass blanks on an adhesive film with contact between two opposite edge regions of a first and second thin-glass surface. FIGS. 3c and 3d respectively show cross sections of the arrangements according to FIGS. 3a and 3b.

4 shows thicknesses of the adhesive film as a function of the thickness of the thin-glass blanks for different E-moduli of the adhesive film, the neutral phase lying between tensile and compressive stress in the adhesive layer between adhesion film and thin-glass blanks. 1 a shows by way of example the embodiment of a glass substrate belt 1 a with positioned and fixed round thin-glass blanks 12 for production of wafers. The thin glass blanks 12 are fixed on an adhesive film 14 with full-surface contact of a first thin glass surface 12 b. The second thin glass surface 12a lies freely upwards and only comes into contact with the adhesive film 14, ie with the surface 14b of the adhesive film, when the glass substrate tape 1a is rolled up. The thin glass blanks have a thickness of 0.06 mm. The adhesive film 14 is a coextruded polyethylene adhesion film, as it is offered for example by the company. Molco Germany GmbH, Schwerte under the name PE-CLING Protect. The thickness of the adhesive film was 1 10 μm, so that the neutral phase between tensile and compressive stresses in the rolled-up state was positioned in the adhesive layer between the surface 14a of the adhesive film and the surface 12b of the thin glass blanks. The adhesive film 14 has an adhesion side 14a with a static friction force greater than 20 N, which comes into contact with the first surface 12b of the thin glass blanks 12 and an opposite side 14b with a static frictional force of 0.5 to 0.7 N, which during winding or meandering Ming collapsing the glass substrate tape 1 a with the second surface 12 a of the thin glass blanks 12 comes into contact.

 The Poisson's number of the adhesive film was 0.45, the Poisson's number of the thin glass blanks was 0.23, the modulus of adhesion of the adhesive film was 0.2 GPa, and the modulus of elasticity of the thin glass substrates was 73 GPa. The thickness of the adhesive film, taking into account the following thicknesses of the thin glass blanks, was determined in accordance with the above-described relationships in further variants of the example of FIG. 1a as follows, wherein the neutral phase between tensile and compressive stresses in the rolled-up state is in each case in the adhesive layer between the surface 14a of the adhesive film and the surface 12b of the thin glass blanks.

 Thickness of thin glass blanks [mm] Thickness of adhesive film [mm]

 0.01 0.17

 0.02 0.35

 0.03 0.53

 0.04 0.70

 0.05 0.88

 0.06 1, 10

 0.07 1, 23

 0.08 1, 40

 0.09 1, 58

 0.1 1, 75

 0.11 1, 93

0.12 2.10 0.13 2.28

 0.14 2.45

 0.15 2.63

 0.16 2.80

 0.17 2.98

 0.18 3.15

 0.19 3.33

 0.2 3.51

 0.21 3.68

A dependence of different thicknesses of the adhesive film on the thickness of the thin glass substrates with different moduli of elasticity of different materials for the adhesive film is shown in FIG. 4. In all these variants, the Poisson's number of the adhesion film was 0.45, the Poisson's number of the thin glass blanks was 0.23 and the E Modulus of the thin glass substrates was 73 GPa. Curve 41 shows the thickness dependence for an adhesion foil with an E modulus of 0.2 GPa, corresponding to the examples given above. Curve 42 shows, by way of example, the thickness dependence for an adhesion foil having an E modulus of 0.3 GPa, curve 43 shows, by way of example, the thickness dependence for an adhesion foil with an E modulus of 0.5 GPa, curve 44 shows, by way of example, the thickness dependence for an adhesive film with an E-modulus of 0.7 GPa and the curve 45 shows an example of the thickness dependence for an adhesion film with an E-modulus of 2.5 GPa.

Fig. 1 b shows a corresponding glass substrate tape 1 b with positioned and fixed square thin glass blanks 13 for a production of display disks. The thin glass blanks 13 with a thickness of 0.1 mm are fixed on an adhesive paper 15 with contact over the entire surface of a first thin glass surface 13b. The second thin glass surface 13a is exposed upwards and comes into contact with the adhesive film 15 only when the glass substrate belt 1b is rolled up. with the surface 15b of the adhesive film. The adhesive film 15 is an adhesive paper which consists of a paper coated with a polyethylene adhesive layer, as offered for example by the company. Molco Germany GmbH, Schwerte under the name PE-CLING paper. The adhesive paper 15 contacts the first surface 13b of the thin glass blanks 13 with its coated side 15a. The opposite non-adherent side 15b comes into contact with the second surface 13a of the thin glass blanks 13 during rolling up or meandering folding of the glass substrate tape 1b.

Fig. 2a shows, as in Fig. 1a by way of example the execution of a glass substrate tape 2a with positioned and fixed round thin glass blanks 22 for a production of wafers. The thin glass blanks 22 with a thickness of 0.7 mm are fixed here on an adhesive film 24 with contact of the respective entire edge region of a first thin glass surface 22b. The second thin glass surface 22a lies freely upwards and comes into contact with the adhesive film 24 only when the glass substrate tape 2a is rolled up. The adhesive film 24 is a composite adhesive film Polyethylene adhesive film of polyethylene terephthalate (PET) and plasticized polyvinyl chloride (plasticized PVC) with a thickness of 290 μηη, as offered for example by the company. Moico Germany GmbH, Schwerte under the name Penstick® Flex. The adhesive film 24 has an adhesive side 24a which comes into contact with the first surface 22b of the thin glass blanks 22 and an opposite side 24b which comes into contact with the second surface 22a of the thin glass blanks 22 when the glass substrate tape 2a is rolled up or meandered together.

 At the two of the thin glass blanks 22 projecting side edges of the adhesive film each have a transport strip 26 is provided, which may optionally be reinforced with a carrier film. The transport strip 26 serves to guide the glass substrate belt 2a. The transport strip may be provided to support the guide, depending on the drive and steering mechanism also, as shown, with recesses such as cutouts 27 for engagement with a gear or toothed belt. Coding fields 28 are provided between the thin-glass blanks 22, on which an encoding is applied, for determining the position and / or marking of the individual thin-glass blanks 22 in the production process. The coding can be printed directly on or inscribable or printable fields, e.g. be attached in the form of labels on the adhesive tape therefor.

Fig. 2b shows a corresponding glass substrate tape 2b with positioned and fixed square thin glass blanks 23 for a production of display disks. The thin glass blanks 23 are fixed on an adhesive film 25 with contact of the respective entire edge region of a first thin glass surface 23b. The second thin glass surface 23a lies freely upwards and only comes into contact with the adhesive film 25 when the glass substrate tape 2b is rolled up. The adhesive film 25 is a soft PVC adhesion film with a thickness of 150 μm, as described, for example, by the company Moico Deutschland GmbH , Schwerte under the name Penstick® Protect is offered. The adhesive film 25 has a static frictional force greater than 50 N. Its side 25a is in contact with the first surface 23b of the thin glass blanks 23, and its opposite side 25b comes into contact with the second surface 23a of the thin glass blanks 23 during winding or meandering of the glass substrate tape 2b. At the two of the thin glass blanks 22 projecting side edges of the adhesive film each coding fields 29 are provided on soft coding is applied, for determining the position and / or labeling of the individual thin glass blanks 23 in the production process. The coding can be printed directly or it can be inscribable or printable fields, for example in the form of labels for it to be attached to the adhesive film.

3a shows, by way of example, the embodiment of a glass substrate belt 3a with positioned and fixed round thin-glass blanks 32 for the production of wafers. The thin glass blanks 32 are fixed here on an adhesion film 34 with contact in each case between two mutually opposite edge regions of a first thin glass surface 32b. The second thin glass surface 32a is exposed upward and the edge portion does not come into contact with the adhesive film 34 until the glass substrate tape 3a is rolled up, that is, when the glass substrate tape 3a is rolled up. with the cover sheet 36, which forms the lower part of the adhesive film 34. The adhesive film 34 is a soft polyvinyl chloride (plasticized PVC) adhesive film having a static friction force greater than 50 N and a thickness of 150 μηη, as offered for example by the company. Molco Germany GmbH, Schwerte under the name Penstick® Protect. On the lower surface of the adhesive soft PVC material, a non-adherent cover sheet 36 is attached with which the adhesive film 34 comes into contact with the second surface 32a of the thin glass blanks when winding up or meandering the glass substrate tape 3a. Fig. 3c shows a cross section of the arrangement according to Fig. 3a.

Fig. 3b shows by way of example as Fig. 2b by way of example the execution of a glass substrate tape 3b with positioned and fixed square thin glass blanks 33 for a production of display disks. The thin glass blanks 33 are here fixed on an adhesion film 35 with contact in each case between two mutually opposite edge regions of a first thin glass surface 33b and a second thin glass surface 33a. In this case, either a second adhesive film (not shown) is placed on the first adhesive film, so that the edge regions of the thin glass blanks to be fixed come to rest between the two adhesive films or, as shown here, the adhesion film 35 is folded upwards from the edge and onto the edge region of the thin glass surface 33a folded inwards so that it fixes with its surface 35a, the first surface 33b and the second surface 33a of the thin glass blanks. The adhesive film 35 is a soft polyvinyl chloride (plasticized PVC) adhesive film with a thickness of 150 μm, as described, for example, by the company Molco Deutschland GmbH, Schwerte under the name Penstick® Protect. is offered. Adhesive film 35 has the same adhesive properties on both surfaces and has a static friction force greater than 50 N. FIG. 3d shows a cross-section of the arrangement according to FIG. 3b.

It is understood that the invention is not limited to a combination of the features described above, but that the skilled person will arbitrarily combine all features of the invention, as far as appropriate, or use it alone, without departing from the scope of the invention.

LIST OF REFERENCE NUMBERS

 1 a, 1 b, 2 a, 2 b, 3 a, 3 b glass substrate tape

 12, 13, 22, 23, 32, 33 thin glass blanks

 12a, 13a, 22a, 23a, 32a, 33a first surface of the thin glass blanks

12b, 13b, 22b, 23b, 32b, 33b second surface of the thin glass blanks

14, 15, 24, 25, 34, 35 adhesive film

 14a, 15a, 24a, 25a, 34a, 35a first surface of the adhesive film

 14b, 15b, 24b, 25b, 34b, 35b second surface of the adhesive film

 26 transport strips

 27 punched out

 28, 29 coding field

 36 cover sheet

 41, 42, 43, 44, 45 thicknesses of the adhesive film as a function of the thickness of the thin glass blanks at different E-moduli of the adhesive film, wherein the neutral phase is between tensile and compressive stress in the adhesive layer between the adhesive film and thin glass blanks.

Claims

claims

1 . Glass substrate tape (1a, 1b, 2a, 2b, 3a, 3b) comprising a thin glass substrate having first and second surfaces and a polymer tape which is in contact with the first (12a, 13a, 22a, 23a, 32a, 33a) and / or second (12b, 13b, 22b, 23b, 32b, 33b) surface of the thin glass substrate is characterized in that the thin glass substrate consists of an array of at least two thin glass blanks (12, 13, 22, 23, 32, 33) and the polymer tape an adhesion film (14, 15, 24, 25, 34, 35), wherein the thin glass blanks (12, 13, 22, 23, 32, 33) have a thickness of less than or equal to 350 μm and have a square at the first and / or second surface Rough average (RMS) Rq equal to or less than 1 nanometer, and the glass substrate tape (1a, 1b, 2a, 2b, 3a, 3b) is meandered or rolled up.

2. glass substrate tape according to claim 1, wherein the thin glass blanks have a thickness of less than or equal to 100 μηη, preferably less than or equal to 70 μηη, preferably less than or equal to 50 μηη, more preferably less than or equal to 25 μηη.

3. glass substrate tape according to any one of the preceding claims, wherein the thin glass blanks have a thickness of at least 5 μηη, preferably of at least 10 μηη, more preferably of at least 15 μηη.

4. Glass substrate tape according to one of the preceding claims, wherein the thin glass blanks on the first and / or second surface have a fire-polished surface.

5. Glass substrate tape according to one of the preceding claims, wherein the thin glass blanks on the first and / or second surface have a root mean square roughness (RMS) Rq of less than or equal to 0.8 nanometers, preferably less than or equal to 0.5 nanometers.

6. Glass substrate tape according to one of the preceding claims, wherein the thin glass blanks on the first and / or second surface have an average roughness Ra of at most 2 nanometers, preferably of at most 1, 5 nanometers, more preferably of at most 1 nanometer.

7. glass substrate tape according to any one of the preceding claims, wherein the adhesive film of polyethylene or polyvinyl chloride, preferably soft polyvinyl chloride, consists.

8. Glass substrate tape according to one of the preceding claims, wherein the adhesive film consists of an adhesive textile or a metal foil, wherein at least one surface is coated with an adhesive coating.

9. Glass substrate tape according to one of the preceding claims, wherein the thickness of an adhesive film in the range of less than 6 mm, preferably in the range of less than or equal to 2 mm, more preferably less than or equal to 1 mm, most preferably less than or equal to 0.5 mm, in particular in the range 30 bis 350 μηη, preferably 60 to 200 μηη is located.

10. glass substrate tape according to one of the preceding claims, wherein the neutral phase between tensile and compressive stress in the rolled state of a thin glass substrate and an adjacent adhesive film in the two layers bonding adhesive layer, wherein the thickness of the adhesive film (Dp) taking into account the thickness of the thin glass substrates ( Dg), the Poisson's number of the adhesion foil (vp), the Poisson's number of the thin glass substrates (vg), the modulus of adhesion of the adhesion foil (Ep) and the modulus of elasticity of the thin glass substrates (Eg) are determined as follows:

1 1. Glass substrate tape according to one of the preceding claims, wherein the adhesive film covers the entire first or second surface of the thin glass blanks.

12. glass substrate tape according to one of the preceding claims, wherein the adhesive film covers portions of the edge region of the first and / or second surface of the thin glass blanks.

13. glass substrate tape according to one of the preceding claims, wherein the adhesive film in each case covers the entire edge region of the first and / or second surface of the thin glass blanks.

14. glass substrate tape according to any one of the preceding claims, wherein the adhesive film each protrudes beyond the edge region of the first and second surfaces of the thin glass blanks perpendicular to the longitudinal direction of the glass substrate tape and forms a projection (26).

15. glass substrate tape according to claim 1 1, wherein the supernatant recesses, in particular punched-out (27).

16. glass substrate tape according to claim 1 1 or 12, wherein the supernatant contains coding fields (29).

17. glass substrate tape according to claim 1 1 or 12, wherein the glass substrate tape between individual thin glass blanks coding fields (28).

18. glass substrate tape according to one of the preceding claims, wherein the adhesive film on the first or second surface of the thin glass surface facing having stronger adhesion properties than on the surface facing away from the surface of the thin glass surface.

19. glass substrate tape according to any one of the preceding claims, wherein the glass substrate tape is meander-shaped layered or rolled up.

20. A method for producing a glass substrate tape (1 a, 1 b, 2 a, 2 b, 3 a, 3 b) according to one of the preceding claims with the following steps:

 Producing a thin glass ribbon in the down-draw or overflow down-draw process,

 Separating thin glass blanks (12, 13, 22, 23, 32, 33) from the thin glass ribbon,

 Positioning and contacting the thin glass blanks on the adhesive film (14, 15, 24, 25, 34, 35),

- Rolling of the glass substrate tape (1 a, 1 b, 2 a, 2 b, 3 a, 3 b) into a roll, wherein the neutral phase between tensile and compressive stress in the rolled state of the glass substrate tape in the adhesive layer, the interface between the thin glass substrate and adhesive film is placed and for this purpose the thickness of the adhesive film Dp, the thickness of the thin glass substrates Dg, the Poisson's number of the adhesion film vp, the Poisson's number of the thin glass substrates vg, the modulus of elasticity of the adhesion film Ep and the modulus of elasticity of the thin glass substrates Eg are adjusted as follows: Use of a glass substrate tape according to one of the preceding claims for packaging or treating the first and / or second surface of the thin glass blanks in a continuous process.