阅读说明：本技术 具有改善的翘曲的玻璃制品的陶瓷化方法 (Method for ceramming glass articles with improved warpage ) 是由 J·M·霍尔 M·G·J·休伯特 A·P·奇托森 J·R·小萨尔策 于 2019-07-03 设计创作，主要内容包括：提供了包含载具板、给定器板和玻璃片的玻璃堆叠构造,其用于对玻璃片进行热处理以形成玻璃陶瓷制品。对本文所述的玻璃堆叠构造和组件进行选择,从而改善陶瓷化过程期间的整个玻璃堆叠上的热均匀性,同时维持或者甚至降低所得到的玻璃陶瓷制品中的应力。因此,根据本文所述各种实施方式制造的玻璃陶瓷制品相比于根据常规工艺制造的玻璃陶瓷制品展现出改进的光学质量和较少的翘曲。描述了载具板、给定器板、脱模剂组合物和玻璃片堆叠方法的各种实施方式。(A glass stack configuration comprising a carrier plate, a setter plate, and a glass sheet is provided for heat treating the glass sheet to form a glass-ceramic article. The glass stack configurations and assemblies described herein are selected to improve thermal uniformity across the glass stack during the ceramming process while maintaining or even reducing stress in the resulting glass-ceramic article. Accordingly, glass-ceramic articles manufactured according to various embodiments described herein exhibit improved optical quality and less warpage than glass-ceramic articles manufactured according to conventional processes. Various embodiments of carrier plates, setter plates, mold release compositions, and methods of stacking glass sheets are described.)

1. A method of ceramming a plurality of glass sheets comprising:

placing a first portion of the plurality of glass sheets in a first stack between a first setter plate and a second portion of the plurality of glass sheets in a second stack between the second setter plate and a third setter plate, the second stack being on top of the first stack in a glass stack configuration; and

exposing the glass stack configuration to a ceramming cycle to ceram the plurality of glass sheets,

wherein a delta T of the first stack or the second stack is less than 10 ℃ when the glass sheets are heated to a nucleation temperature for a predetermined period of time during the ceramming cycle; or

Wherein the delta T of the first stack or the second stack is less than 10 ℃ when the glass sheets are heated to the crystallization temperature for a predetermined period of time during the ceramming cycle.

2. The method of claim 1, wherein the plurality of glass sheets have a maximum thickness variation of 21 μ ι η or less.

3. The method of claim 1 or 2, further comprising removing edge beads from each of the plurality of glass sheets.

4. The method of any one of the preceding claims, further comprising forming a release agent layer from an aqueous dispersion of boron nitride and a colloidal inorganic binder between one of the plurality of glass sheets and an adjacent one of the plurality of glass sheets.

5. The method of any one of the preceding claims, further comprising forming a release agent layer from an aqueous dispersion of boron nitride and a colloidal inorganic binder between one of the plurality of glass sheets and an adjacent one of the first setter plate, the second setter plate, or the third setter plate.

6. The method of any of the preceding claims, wherein a Δ T of a glass stack configuration between a bottom of the first stack proximate the first setter plate and a top of the second stack proximate the third setter plate is 2.2 ℃ or less during the predetermined period of time that glass sheets are maintained at the nucleation temperature.

7. The method of any one of the preceding claims, wherein the ceramming process comprises: controlled cooling at a rate of about 4 c/min from the maximum temperature during ceramming to a temperature of about 450 c, followed by a quenching step to a temperature close to room temperature.

8. The method of any one of the preceding claims, wherein the first, second, and third setter plates each comprise reaction bonded silicon carbide.

9. The method of any of the preceding claims, wherein the first, second, and third setter plates each have a maximum flatness of less than or equal to about 100 μ ι η.

10. The method of any of the preceding claims, wherein the first, second, and third setter plates each have a maximum flatness of less than or equal to about 25 μ ι η.

11. The method of any one of the preceding claims, wherein the first, second and third setter plates each have a thickness t of about 6.5mm to about 10 mm.

12. The method of any of the preceding claims, wherein the glass stack configuration is supported on a carrier plate, the carrier plate comprising open grid configuration steel.

13. A method of ceramming a plurality of glass sheets comprising:

reducing thickness variation in the plurality of glass sheets;

placing the plurality of glass sheets between a first setter plate and a second setter plate in a glass stacking configuration; and

exposing the glass stack configuration to a ceramming cycle to ceram the plurality of glass sheets.

14. The method of claim 13, wherein reducing the thickness variation in the plurality of glass sheets comprises reducing the thickness variation in the plurality of glass sheets to a maximum thickness variation of 21 μ ι η or less.

15. The method of claim 13 or 14, further comprising removing edge beads from each of the plurality of glass sheets.

16. The method of any one of claims 13-15, further comprising forming a release agent layer from an aqueous dispersion of boron nitride and a colloidal inorganic binder between one of the plurality of glass sheets and an adjacent one of the plurality of glass sheets.

17. The method of any of claims 13-16, wherein a Δ T of a glass stack configuration between a glass sheet proximate to the first setter plate and a glass sheet proximate to the second setter plate is 2.2 ℃ or less during the predetermined period of time that the glass sheet is maintained at the nucleation temperature.

18. The method of any one of claims 13-17, wherein the ceramming process comprises: controlled cooling at a rate of about 4 c/min from the maximum temperature during ceramming to a temperature of about 450 c, followed by a quenching step to a temperature close to room temperature.

19. The method of any of claims 13-18, wherein the first given plate and the second given plate each have a maximum flatness of less than or equal to about 25 μ ι η.

20. The method of any of claims 13-19, wherein the glass stack configuration is supported on a carrier plate, the carrier plate comprising open grid configuration steel.

Technical Field

The present description relates generally to methods and apparatus for ceramming glass sheets, and more particularly, to methods of ceramming glass sheets with improved warpage.

Background

Conventional ceramming processes employ ceramic and/or refractory materials as the setter (setters). However, such materials do not produce glass-ceramics with optical qualities suitable for optical displays. Without being bound by theory, it is believed that the heat transfer and heat capacity limitations of the ceramic and/or refractory material may cause the glass-ceramic to warp or create a skin effect (skin effect) on the glass-ceramic.

Warping may also be introduced during the manufacturing process due to stacking of the glass sheets. In particular, warping may result from sticking of the glass sheets in the stack to other glass sheets and/or a setter (setter), thickness variations of the glass sheets throughout the stack, and loads applied to the glass stack.

Accordingly, there is a need for alternative methods and apparatus suitable for producing glass-ceramic sheets with high optical quality and reduced warpage.

Disclosure of Invention

According to one embodiment, a method of ceramming a plurality of glass sheets comprises: placing a first portion of the plurality of glass sheets in a first stack between a first setter plate and a second setter plate, and placing a second portion of the plurality of glass sheets in a second stack between the second setter plate and a third setter plate, the second stack being on top of the first stack in a glass stack configuration, and exposing the glass stack configuration to a ceramming cycle to ceram the plurality of glass sheets. The first portion of the plurality of glass sheets and the second portion of the plurality of glass sheets each comprise from 5 glass sheets to 15 glass sheets.

According to another embodiment, a method of ceramming a plurality of glass sheets comprises: the method includes the steps of machining each of the plurality of glass sheets to reduce thickness variation in the plurality of glass sheets, placing the plurality of glass sheets between a first setter plate and a second setter plate in a glass stack configuration, and exposing the glass stack configuration to a ceramming cycle formation to ceram the plurality of glass sheets.

Additional features and advantages will be set forth in the detailed description which follows, and in part will be readily apparent to those skilled in the art from that description or recognized by practicing the embodiments as described herein, including the detailed description which follows, the claims, as well as the appended drawings.

It is to be understood that both the foregoing general description and the following detailed description describe various embodiments of printing compositions, printing methods on substrates, and printed substrates, and are intended to provide an overview or framework for understanding the nature and character of the claimed subject matter. The accompanying drawings are included to provide a further understanding of the various embodiments, and are incorporated in and constitute a part of this specification. The drawings illustrate various embodiments described herein and together with the description serve to explain the principles and operations of the claimed subject matter.

Drawings

FIG. 1 is a schematic view of a glass stack configuration according to one or more embodiments described herein;

FIG. 2 shows the average stress and the maximum stress (y-axis; MPa) in the glass-ceramic article for various quench initiation temperatures (x-axis);

fig. 3 is a schematic view of a carrier plate having an open grid configuration according to one or more embodiments described herein;

FIG. 4 is a schematic view of a carrier plate having a hollow slab construction according to one or more embodiments described herein;

FIG. 5 plots modeled Δ T (deg.C; y-axis) as a function of heating time (minutes; x-axis) for an open lattice steel carrier plate and a silicon carbide hollow carrier plate according to one or more embodiments described herein;

FIG. 6 is a plot of modeled Δ T (deg.C; y-axis) as a function of heating time (minutes; x-axis) for the setter plates of example A and comparative examples 1 and 2;

FIG. 7 plots the maximum stress (MPa; y-axis) for two different setter materials, with reaction bonded silicon carbide for the left and silicon refractory plate for the right;

figure 8 shows an EDX (energy dispersive X-ray) showing no Si on the surface of the reaction bonded silicon carbide setter plate after ceramization according to one or more embodiments described herein;

FIG. 9 shows XRD (X-ray diffraction) of various glass-ceramic articles according to one or more embodiments described herein;

FIG. 10 is a maximum warp plot (μm; y-axis) for various given plate flatness and weight gain according to one or more embodiments described herein;

FIG. 11 schematically shows a scan pattern for CMM (coordinate measuring machine) measurements given flatness of a tool plate according to one or more embodiments described herein;

FIG. 12 shows maximum warp (μm; left y-axis) over the thickness of the glass stack for various applied amounts of force (bar graph) according to one or more embodiments described herein; and the amount of application of the various forces, the maximum stress (MPa; right y-axis) (line graphs);

FIG. 13 shows maximum warp (μm; y-axis) over the thickness of a glass stack having various thickness variations according to one or more embodiments described herein;

FIG. 14 shows the maximum warp (μm; y-axis) over the thickness of a glass stack for various given plate flatness, according to one or more embodiments described herein;

FIG. 15A is a graphical representation of the warpage of a 265 mm glass strip with edge beads removed, according to one or more embodiments described herein;

FIG. 15B is a graphical representation of the warpage of a 265 mm glass strip with retention of edge beads according to one or more embodiments described herein;

fig. 16 graphically represents stress of the glass-ceramic article with the edge bead retained (top) and with the edge bead removed (bottom), according to one or more embodiments described herein;

FIG. 17 is a graph plotting critical Δ T (deg.C; y-axis) as a function of part length (mm; x-axis) for various lengths and widths of glass-ceramic parts according to one or more embodiments described herein;

FIG. 18 is% transmission (y-axis) for various glass stacks according to one or more embodiments described herein;

FIG. 19 is a% haze (y-axis) for various glass stacks according to one or more embodiments described herein;

FIG. 20 plots maximum warpage (μm; y-axis) versus stack position (from left to right, bottom of stack to top of stack; x-axis) for application of release agent with varying nozzle spacing according to one or more embodiments described herein;

FIG. 21 is a schematic view of a glass stack configuration including an interlayer setter plate according to one or more embodiments described herein;

FIG. 22 plots glass layer center temperature (deg.C; y-axis) as a function of time (x-axis) for a top glass sheet in the glass stack and a bottom glass sheet in the glass stack according to one or more embodiments described herein;

FIG. 23 plots glass layer temperature (deg.C; y-axis) as a function of time during the ceramming process (x-axis) for the top glass sheet in the glass stack and the bottom glass sheet in the glass stack according to one or more embodiments described herein; and

FIG. 24 shows maximum warp (μm; left y-axis) over the thickness of a glass stack for various applied forces (bar graph) according to one or more embodiments described herein; and maximum stress (MPa; right y-axis) (line graphs) for glass stacks without interlayer setter plates (left) and glass stacks containing interlayer setter plates (right).

Detailed Description

Reference will now be made in detail to various embodiments of methods and apparatus for forming glass-ceramic articles with improved optical quality and reduced warpage, examples of which are illustrated in the accompanying drawings. Wherever possible, the same reference numbers will be used throughout the drawings to refer to the same or like parts.

Generally, described herein are glass stack configurations comprising a carrier plate, a setter plate, and a glass sheet for heat treating the glass sheet to form a glass-ceramic article. The glass stack configurations and assemblies described herein are selected to improve thermal uniformity across the glass stack during the ceramming process while maintaining or even reducing stress in the resulting glass-ceramic article. Accordingly, glass-ceramic articles manufactured according to various embodiments described herein exhibit improved optical quality and less warpage than glass-ceramic articles manufactured according to conventional processes. Various embodiments of carrier plates, setter plates, mold release compositions and methods of stacking glass sheets will be described herein with particular reference to the accompanying drawings.

Unless otherwise indicated, directional terms used herein, such as upper, lower, left, right, front, rear, top, bottom, longitudinal, horizontal, are used solely with reference to the drawings, and are not intended to be absolute.

Unless specifically stated otherwise, any methods described herein should not be construed as requiring that their steps be performed in a particular order, or that any apparatus be specifically oriented. Accordingly, if a method claim does not actually recite an order to be followed by its steps, or any apparatus claim does not actually recite an order or orientation to individual components, or no further limitation to a specific order is explicitly stated in the claims or specification, or a specific order or orientation is recited to components of an apparatus, then no order or orientation should be inferred, in any respect. The same applies to any possible explicative basis not explicitly stated, including: logic for setting steps, operational flows, component orders, or component orientations; general meaning derived from grammatical structures or punctuation; and the number or type of embodiments described in the specification.

As used herein, the singular forms "a," "an," and "the" include plural referents unless the context clearly dictates otherwise. Thus, for example, reference to "a" or "an" element includes aspects having two or more such elements, unless the context clearly indicates otherwise.

In general, a process for forming a glass-ceramic includes: forming a glass article, and ceramming the glass article to convert the glass article into a glass-ceramic form. Referring to fig. 1, an exemplary stacked configuration 100 for ceramization is shown. The stack configuration 100 includes: a carrier plate 102 supporting two setter plates 104, and a glass stack 106 placed between the setter plates 104.

In some embodiments, insulation layers (not shown) may be located on the top surface of the upper given collector plate 104 and the bottom surface of the lower given collector plate 104. The insulating layer may be formed of any material having a low thermal conductivity and may reduce or even eliminate the axial temperature gradient of the glass sheets 108 on the top and bottom of the glass stack 106.

As shown in fig. 1, the glass stack 106 includes a plurality of glass sheets 108, each glass sheet 108 being separated from an adjacent glass sheet 108 by a release agent layer 110. As will be described in greater detail below, the release agent layer 110 reduces or even eliminates sticking of the glass sheets 108 in the glass stack 106 during the ceramming process. Although not shown in fig. 1, in some embodiments, the glass stack 106 may also include a release agent layer 110 between the glass sheet 108 and the given cliche plate 104. In other embodiments, such as the various embodiments described below, the given cliche 104 is made of a material that does not react with the glass sheet 108, and the release agent layer 110 is not required to prevent interaction between the glass sheet 108 and the given cliche 104.

Generally, to form a glass-ceramic, the glass stack 106 is heated above its annealing point for a time sufficient to establish crystal nucleation (also referred to as nucleation phase). The heat treatment may be carried out in, for example, a toughening furnace or a furnace. After heating above its annealing point, the glass is then heated further, typically at a higher temperature between the annealing point of the glass and the softening point of the glass, to establish a crystalline phase (also referred to as crystalline phase). In various embodiments, the thermal treatment or ceramming process comprises: the method includes heating the glass stack to a nucleation temperature, maintaining the nucleation temperature for a predetermined period of time, heating the glass stack to a crystallization temperature, and maintaining the crystallization temperature for a predetermined period of time. In some embodiments, the step of heating the glass stack to the nucleation temperature may comprise heating the glass stack to a nucleation temperature of about 700 ℃ at a rate of 1-10 ℃/minute. The glass stack may be maintained at the nucleation temperature for a period of time from about 1/4 hours to about 4 hours. The step of heating the glass stack to a crystallization temperature may include heating the glass stack to a crystallization temperature of about 800 ℃ at a rate of 1-10 ℃/minute. The glass stack may be maintained at the nucleation temperature for a period of time from about 1/4 hours to about 4 hours.

However, it is contemplated that other heat treatment protocols (including different times and/or temperatures) may be used depending on the particular embodiment. In particular, the temperature-time profile of the heat treatment step is selected to produce one or more of the following attributes: the ratio of the crystalline phases, the one or more primary crystalline phases and/or the one or more secondary crystalline phases to the residual glass of the glass-ceramic, the set of crystalline phases of the one or more primary crystalline phases and/or the one or more secondary crystalline phases to the residual glass, and the grain size or grain size distribution between the one or more primary crystalline phases and/or the one or more secondary crystalline phases, which in turn can affect the final integrity, quality, color, and/or opacity of the resulting glass-ceramic article.

After heating to the nucleation temperature and maintaining at that temperature for a predetermined time, the glass stack is allowed to cool back to room temperature. In various embodiments, the cooling rate is controlled down to a temperature of about 450 ℃, which may be followed by quenching the glass-ceramic article without affecting the stress, as shown in fig. 2. Thus, in various embodiments, the ceramming process comprises: controlled cooling at a rate of about 4 c/minute from a maximum temperature to a temperature of about 450 c, followed by a quenching step to bring the temperature to approximately room temperature.

Having generally described the stacked configuration 100, additional details regarding the components of the stacked configuration 100 will now be provided.

Carrier plate

In various embodiments, carrier plate 102 supports 2 or more given plates 104. The structure and materials of the carrier plate 102 can be selected to control the thermal uniformity of the glass sheets loaded into the stacked configuration 100 on top thereof. In some embodiments, the carrier plate 102 has an open carrier design (as shown in fig. 3), while in other embodiments, the carrier plate 102 has a closed carrier design (as shown in fig. 4). In the embodiment shown in fig. 3, the carrier plate 102 is approximately 17% solid metal (e.g., steel), while in the embodiment shown in fig. 4, the carrier plate 102 is a hollow plate, approximately 45% solid metal, fabricated from reaction bonded silicon carbide beams.

To evaluate the thermal influence of the carrier plate, a thermal model was run assuming production with specification capacities of 9 stacks of carrier plate and 8mm thick given plate made of reaction bonded silicon carbide, and 23 glass sheets in each stack. As shown in the model data of fig. 5, the glass stack on the hollow carrier plate exhibited reduced thermal uniformity compared to the glass stack on the open steel carrier plate due to heat transfer. In particular, except for the very early heating stage when the glass temperature is low, greater glass stack temperature variability is expected for carriers made of silicon carbide beams (fig. 4) compared to carriers made of the open steel grid design (fig. 3). Furthermore, the blocking of the carrier plate from direct radiation also increases the overall heating time, despite the fact that reaction bonded silicon carbide is a better thermal conductor than steel.

Thus, while various designs and materials may be employed for the carrier plate 102, the carrier plate is made of steel and has an open grid design as shown in fig. 3.

Setter plate

As shown in fig. 1, in various embodiments, carrier plate 102 supports at least two setter plates 104. For example, while the embodiment shown in fig. 1 includes a single glass stack 106 with a given setter plate 104 above the glass stack 106 and a given setter plate 104 between the glass stack 106 and the carrier plate 102, it is contemplated that additional given setter plates 104 may be included, such as: in a glass stack 106, and/or by placing a plurality of glass stacks 106 on carrier plate 102, each glass stack 106 having at least a given plate 104 above glass stack 106 and a given plate 104 between glass stack 106 and carrier plate 102.

While most conventional ceramming processes employ ceramics and refractory materials to form a given plate, the heat transfer and heat capacity limitations of such materials make them unsuitable for producing high optical qualities that are desirable or needed for certain applications. Furthermore, a given plate made of such materials can be subject to thermal expansion, oxidation, and creep, which in turn can lead to warpage in the glass-ceramic article.

In addition, a given device plate 104 adhered to a glass stack 106 provides a lateral heat transfer path, spreading out radiant heat from the heating element, which may reduce in-plane glass sheet temperature variations. Minimizing temperature variations may in turn lead to reduced warpage and in-plane stress in the glass-ceramic article. Thus, in various embodiments, a given plate 104 is selected to maximize the reduction in glass sheet temperature variation. Specifically, a given plate 104 is selected to have a particular specific heat capacity, density, and thermal diffusivity.

According to various embodiments, the specific heat capacity (c) of a given plate is measured at room temperature according to ASTM E1461_p) Is about 670J/kg K to about 850J/kg K. For example, the specific heat capacity (c) of a given plate is measured at room temperature according to ASTM E1461_p) May be about 670J/kg K to about 850J/kg K, about 670J/kg K to about 800J/kg K, about 670J/kg K to about 750J/kg K, or about 670J/kg K to about 700J/kg K, and all ranges and subranges therebetween. Without being bound by theory, it is believed that when the specific heat capacity falls outside this range, the material cannot give off and receive heat at an appropriate rate, which leads to stress and warpage in the glass in the stacked configuration.

In various embodiments, a given board may be selected to have greater than about 2500kg/m, measured in accordance with ASTM C20, in addition or alternatively³The bulk density of (2). For example, a given board may have a bulk density, as measured according to ASTM C20, of: about 2500kg/m³To about 4000kg/m³About 2750kg/m³To about 3750kg/m³Or about 3000kg/m³To about 3500kg/m³And all ranges and subranges therebetween. Without being bound by theory, it is believed that materials having a bulk density in this range have low porosity and do not add significant weight to the stack. Too low a packing density can lead to material degradation over time and reduced material life, while too high a packing density can lead to stresses in the stack due to increased forces on the glass.

Further, in various embodiments, the thermal diffusivity of a given plate is greater than about 2.50x10^-5m²And s. For example, a given plate may have a thermal diffusivity as follows: about 2.50x10^-5m²S to about 5.50x10^-4m²S, about 3.0x10^-5m²S to about 5.00x10^-4m²S, about 4.0x10^-5m²S to about 4.50x10^-4m²S, about 4.50x10^-5m²S to about 4.00x10^-4m²S, about 5.00x10^-5m²S to about 3.50x10^-4m²S, about 5.50x10^-5m²S to about 3.00x10^-4m²S, about 6.00x10^-5m²S to about 2.50x10^-4m²S, about 6.50x10^-5m²S to about 2.0x10^-4m²S, about 7.00x10^-5m²S to about 2.00x10^-4m²S, or about 7.50x10^-5m²S to about 1.50x10^-4m²S, and all ranges and subranges therebetween. Without being bound by theory, if the thermal diffusivity is too low, heating and cooling of the material can take too long, causing thermal gradients in the stack, which can lead to stress and warpage. However, if the thermal diffusivity is too high, stress may also result due to thermal gradients imparted in the stack. The rate at which a glass sheet in contact with a given plate is affected by heat transfer may be different than the glass sheet in the center of the stack. The thermal diffusivity, α, can be defined according to the following equation:

wherein K is a thermal conductivity coefficient (W/m × K), and ρ is a density (kg/m)³) And c, and c_pIs the specific heat capacity (J/kg. multidot.K).

Thus, in various embodiments, a given device plate has a thermal conductivity (k) as measured according to ASTM E1461 at room temperature as follows: greater than about 100W/m-K, greater than about 125W/m-K, greater than about 150W/m-K, greater than about 175W/m-K, or even greater than about 180W/m-K. For example, at room temperature, a given board may have a thermal conductivity (k) as follows, measured according to ASTM E1461: about 100W/m-K to about 350W/m-K, about 125W/m-K to about 325W/m-K, about 150W/m-K to about 300W/m-K, about 175W/m-K to about 275W/m-K, or about 180W/m-K to about 250W/m-K, and all ranges and subranges therebetween. Without being bound by theory, a thermal conductivity that is too high or too low may induce thermal gradients in the stack, resulting in stress and warpage.

Has the required specific heat capacity and specific heat densityVarious materials of degree and thermal diffusivity may be suitable for use in forming a given plate described herein. One exemplary material that is particularly suitable is reaction bonded silicon carbide (SiSiC). In an embodiment, a given plate 104 may comprise about 85 wt.% to about 90 wt.% reaction bonded silicon carbide. A given plate 104 may also comprise about 10 wt.% to about 15 wt.% silicon metal (Si) and a binder. Commercially available reaction bonded silicon carbide products that may be suitable for forming a given plate 104 may include, for example, CRYSTAR RB available from Saint Goban ceramic materials^TMBut is not limited thereto.

To verify the effect of the thermal properties of the material used to form a given plate, three different materials were used to form a given plate having a thickness of 8 mm. Specifically, example a was formed from reaction bonded silicon carbide, comparative example 1 was formed using nitride bonded silicon carbide, and comparative example 2 was formed using a silicon refractory plate. Table 1 provides the thermal properties of each of these materials.

Table 1:

the Δ T of the glass stack during the heating ramp was measured. The results are shown in FIG. 6. Specifically, as shown in fig. 6, the reaction bonded silicon carbide exhibits reduced heating time and reduced Δ Τ during the process. Comparative example 2, which employed a given plate formed of a silicon refractory plate, exhibited a significantly greater temperature change, most likely because it was a poor heat conductor. However, the greater thermal diffusivity of example a and comparative example 1 (nitride bonded silicon carbide) show more uniform temperatures.

In addition to reducing temperature variations in the glass stack, a given plate 104 of various embodiments is made of a material that imparts lower stress than conventional materials. For example, the thermal diffusivity of reaction-bonded silicon carbide imparts lower stress to the glass-ceramic article after the ceramming heat treatment as compared to conventional given sheet materials. As shown in fig. 7, the reaction bonded silicon carbide produces a lower maximum stress on the stack (left hand side in the figure) than the stack in contact with the silicon refractory plate setter plate (right hand side in the figure). Without being bound by theory, it is believed that the decrease in temperature Δ, which is derived from the thermal diffusivity of the reaction bonded silicon carbide, reduces the stress in the glass-ceramic article as crystals grow and phase transition occurs in the article. The stress drop directly affects the warpage in the glass-ceramic article. In particular, the increased stress induces higher warpage in the article, which may make it unusable for certain applications (e.g., handheld electronic displays). However, the use of reaction bonded silicon carbide reduces stress in the glass-ceramic article, thereby providing low warpage in the final product.

In various embodiments, the material used to form a given plate 104 is also selected based on whether it lacks reactivity with both the carrier plate 102 and the glass-ceramic article. Exemplary materials are demonstrated in which reaction bonded silicon carbide has low reactivity or even no reactivity with the materials typically used to form carrier plate 102. Specifically, a given device plate made of reaction bonded silicon carbide in contact with stainless steel alloy and Ni-based superalloy metal carrier plates was tested in air, up to 800 ℃, for 24 hours and 100 hours. As shown in fig. 8, SEM (scanning electron microscope) and EDX examination showed no reaction of the metal with the reaction bonded silicon carbide. Specifically, no Si was found on the surface of the carrier plate, indicating no reaction with free Si in the reaction bonded silicon carbide microstructure.

Furthermore, Li-based glass ceramics in contact with the reaction bonded silicon carbide material during the thermal ceramming process do not exhibit any skin effect, as characterized by XRD phase set. For example, as shown in FIG. 9, the phase of the glass (A) in contact with the reaction bonded silicon carbide setter plates is similar to the bulk glass (B).

In addition to having improved thermal properties compared to other materials, reaction bonded silicon carbide has low porosity (< 1%), which may increase the lifetime of a given plate during thermal cycling due to increased resistance to oxidation, cracking, and reactivity with other elements and materials through diffusion.

In various embodiments, a given plate 104 is also dimensionally adjusted to reduce warpage in the glass-ceramic article. Specifically, the thickness of a given plate 104 and the flatness of the given plate 104 are controlled to reduce both warpage and stress in the glass-ceramic.

During the ceramming process, the glass sheet 108 forms a glass stack 106 in contact with the given plate 104 that moves and conforms to the flatness of the given plate 104. In various embodiments, a given plate 104 may be machined after formation to have a particular flatness. As used herein, the term "flatness" refers to the tolerance zone defined by the two parallel planes in which the surfaces lie. For example, a flatness of 100 μm means that the surface must lie entirely between two parallel planes separated by up to 100 μm. The effect of the flatness of a given plate 104 on the flatness of the glass-ceramic article is shown in fig. 10. Specifically, as shown in FIG. 10, the maximum warpage of the glass-ceramic article for a given plate having a flatness of 100 μm is reduced as compared to a given plate having a flatness of 700 μm.

Fig. 10 also demonstrates that the use of extra weight (e.g., double the weight used in sample set 1) does not significantly reduce warpage. For example, for sample set 1, sample set 2, and sample set 3, respectively, the first five samples in each set employed a setter having a flatness of 100 μm, while the last five samples in each set employed a setter having a flatness of 700 μm. Independent of weight, the flatter setter was approximately the same amount of reduction in warpage, as shown by comparing sample set 1 (with double weight) with sample sets 2 and 3 (with equal weight, respectively).

In various embodiments, a given plate 104 has a maximum flatness as follows: less than or equal to about 100 μm, less than or equal to about 75 μm, less than or equal to about 50 μm, less than or equal to about 45 μm, less than or equal to about 40 μm, less than or equal to about 35 μm, less than or equal to about 30 μm, or even less than or equal to about 25 μm.

Flatness may be measured using a CMM and a touch and/or non-touch probe. In various embodiments, the measurement density is 1 point/mm across the scan track, and the measurement area is about 10mm inward from the side of a given plate. The origin of the alignment is located at the center of the shorter side as shown in fig. 11. To locate the origin, the CMM looks for a corner of the given plate 104 and calculates the distance between the two corners. The origin is the distance divided by 2. To determine the examination region, the probe is moved horizontally 10mm inward from the edge of the setter plate at the origin. The probe then moves up about 325mm to the start point. From which point the scan starts. The spacing between each line is about 15mm and a given plate is scanned in a serpentine pattern as shown in fig. 11. Flatness was evaluated by CMM using the minimum area method.

The thickness t (shown in FIG. 1) of the given plate 104 is selected to at least partially balance the effect of the thermal effect of the given plate 104 on inducing warpage of the glass stack 106. In particular, the thickness should be as small as possible for heat transfer and uniformity, and as large as possible for strength and resistance to warping. Thus, in various embodiments, a given plate 104 has a thickness t as follows: from about 6.5mm to about 10mm, alternatively from about 7mm to about 9.5mm, alternatively from about 7.5mm to about 9mm, alternatively from about 7.9mm to about 8.2mm, and all ranges and subranges therebetween.

The density of the material used to form a given plate 104 and the thickness of a given plate 104 may also be selected based on the force exerted on the glass stack 106. Fig. 12 shows how additional force on the glass stack contributes to increased stress in the glass-ceramic article. Specifically, as shown in FIG. 12, the increase in weight not only does not improve warpage (e.g., reduce maximum warpage), but further increases the maximum stress at various points in the glass stack. Without being bound by theory, it is believed that the addition of additional force has a limiting effect on the glass sheet as it shrinks during the ceramming process. Thus, it is believed that the ability of the material to move freely during the ceramming process reduces warpage in the glass-ceramic article. In various embodiments, a given plate 104 fabricated from reaction bonded silicon carbide may provide good heat transfer while maintaining low applied forces, resulting in low warpage and stress in the glass-ceramic article.

Glass sheet

The glass sheet 108 can be made of any glass composition suitable for forming a glass-ceramic article, but it is understood that the glass composition of the glass sheet 108 can affect the mechanical and optical properties of the glass-ceramic article. In various embodiments, the glass composition is selected such that the resulting glass-ceramic article has a petalite crystalline phase and a lithium silicate crystalline phase, and wherein the petalite crystalline phase and the lithium silicate crystalline phase are present in a higher weight percentage than other crystalline phases present in the glass-ceramic article.

For example, in various embodiments, glass sheet 108 may be formed from a glass composition comprising: about 55 wt% to about 80 wt% SiO₂About 2 to about 20 weight percent Al₂O₃From about 5% to about 20% by weight Li₂O, about 0 wt.% to about 10 wt.% B₂O₃From about 0 wt% to about 5 wt% Na₂O, about 0 wt.% to about 10 wt.% ZnO, about 0.5 wt.% to about 6 wt.% P₂O₅And about 0.2 to about 15 weight percent ZrO₂But is not limited thereto.

SiO₂It relates to glass-forming oxides which act to stabilise the network structure of glass and glass ceramics. In various glass compositions, SiO₂Should be sufficiently high to form a petalite crystalline phase when the glass sheet is heat treated for conversion to a glass ceramic. Can be applied to SiO₂Is limited to control the melting temperature of the glass because of pure SiO₂Or high SiO₂The melting temperature of the glass is undesirably high. In some embodiments, the glass or glass-ceramic composition comprises about 55 wt.% to about 80 wt.% SiO₂. In some embodiments, the glass or glass-ceramic composition comprises about 69 wt.% to about 80 wt.% SiO₂. In some embodiments, the glass or glass-ceramic composition may comprise SiO₂: about 55 to about 80 wt.%, about 55 to about 77 wt.%, about 55 to about 75 wt.%, about 55 to about 73 wt.%, about 60 to about 80 wt.%, about 60 to about 7 wt.%, based on the total weight of the composition7 wt%, about 60 wt% to about 75 wt%, about 60 wt% to about 73 wt%, about 69 wt% to about 80 wt%, about 69 wt% to about 77 wt%, about 69 wt% to about 75 wt%, about 69 wt% to about 73 wt%, about 70 wt% to about 80 wt%, about 70 wt% to about 77 wt%, about 70 wt% to about 75 wt%, about 70 wt% to about 73 wt%, about 73 wt% to about 80 wt%, about 73 wt% to about 77 wt%, about 73 wt% to about 75 wt%, about 75 wt% to about 80 wt%, about 75 wt% to about 77 wt%, or about 77 wt% to about 80 wt%.

Al₂O₃Network stabilization may also be provided, and improved mechanical properties and chemical durability may also be provided. However, if Al is present₂O₃Too high, the proportion of lithium silicate crystals may decrease, possibly to the extent that an interlocking structure cannot be formed. Can adjust Al₂O₃In order to control the viscosity. In addition, if Al is present₂O₃Too high, the viscosity of the melt generally increases. In some embodiments, the glass or glass-ceramic composition may comprise about 2 wt.% to about 20 wt.% Al₂O₃. In some embodiments, the glass or glass-ceramic composition may comprise about 6 wt.% to about 9 wt.% Al₂O₃. In some embodiments, the glass or glass-ceramic composition may comprise Al as follows₂O₃: about 2 wt% to about 20 wt%, about 2 wt% to about 18 wt%, about 2 wt% to about 15 wt%, about 2 wt% to about 12 wt%, about 2 wt% to about 10 wt%, about 2 wt% to about 9 wt%, about 2 wt% to about 8 wt%, about 2 wt% to about 5 wt%, about 5 wt% to about 20 wt%, about 5 wt% to about 18 wt%, about 5 wt% to about 15 wt%, about 5 wt% to about 12 wt%, about 5 wt% to about 10 wt%, about 5 wt% to about 9 wt%, about 5 wt% to about 8 wt%, 6 wt% to about 20 wt%, about 6 wt% to about 18 wt%, about 6 wt% to about 15 wt%, about 6 wt% to about 12 wt%, about 6 wt% to about 10 wt%, about 6 wt% to about 6 wt%, about 6 wt% to about 10 wt%, about 6 wt% to about 6 wt%, about 10 wt%, about 6 wt%, and about 6 wt% to about 10 wt%From about 8% to about 20%, from about 8% to about 18%, from about 8% to about 15%, from about 8% to about 12%, from about 8% to about 10%, from 10% to about 20%, from about 10% to about 18%, from about 10% to about 15%, from about 10% to about 12%, from about 12% to about 20%, from about 12% to about 18%, or from about 12% to about 15%.

In the glasses and glass-ceramics herein, Li₂O contributes to the formation of two crystalline phases petalite and lithium silicate. In fact, to obtain petalite and lithium silicate as the main crystalline phases, it is desirable to have at least about 7% by weight Li in the composition₂And O. Furthermore, it has been found that once Li is present₂O becomes too high (greater than about 15 wt%) and the composition becomes very fluid. Thus, in some embodiments, the glass or glass-ceramic composition may comprise from about 5 wt.% to about 20 wt.% Li₂And O. In other embodiments, the glass or glass-ceramic composition may comprise from about 10 wt.% to about 14 wt.% Li₂And O. In some embodiments, the glass or glass-ceramic composition may comprise Li as follows₂O: about 5% to about 20%, about 5% to about 18%, about 5% to about 16%, about 5% to about 14%, about 5% to about 12%, about 5% to about 10%, about 5% to about 8%, about 7% to about 20%, about 7% to about 18%, about 7% to about 16%, about 7% to about 14%, about 7% to about 12%, about 7% to about 10%, about 10% to about 20%, about 10% to about 18%, about 10% to about 16%, about 10% to about 14%, about 10% to about 12%, about 12% to about 20%, about 12% to about 18%, about 10% to about 12%, about 12% to about 12% by weight, about 14 wt% to about 20 wt%, about 14 wt% to about 18 wt%, about 14 wt% to about 16 wt%, about 16 wt% to about 20 wt%, about 16 wt% to about 18 wt%%, or from about 18% to about 20% by weight.

As described above, Li₂O is commonly used to form various glass-ceramics, but other alkali oxides tend to reduce the formation of glass-ceramics and the formation of aluminosilicate residual glass in glass-ceramics. More than about 5 wt% Na has been found₂O or K₂O (or combinations thereof) results in an undesirable amount of residual glass, which can lead to distortion during crystallization and undesirable microstructure from a mechanical property standpoint. The composition of the residual glass can be adjusted so that: controlling the viscosity during crystallization minimizes deformation or undesirable thermal expansion, or controls microstructural properties. Thus, in general, glass sheets can be formed from glass compositions having low amounts of non-lithium basic oxides. In some embodiments, the glass or glass-ceramic composition may comprise from about 0 wt.% to about 5 wt.% R₂O, wherein R is one or more of alkaline cations Na and K. In some embodiments, the glass or glass-ceramic composition may comprise about 1 wt.% to about 3 wt.% R₂O, wherein R is one or more of alkaline cations Na and K. In some embodiments, the glass or glass-ceramic composition may comprise Na as follows₂O、K₂O or a combination thereof: 0 wt% to about 5 wt%, 0 wt% to about 4 wt%, 0 wt% to about 3 wt%, 0 wt% to about 2 wt%, 0 wt% to about 1 wt%,>from 0% by weight to about 5% by weight,>from 0% by weight to about 4% by weight,>from 0% by weight to about 3% by weight,>from 0% by weight to about 2% by weight,>0% to about 1%, about 1% to about 5%, about 1% to about 4%, about 1% to about 3%, about 1% to about 2%, about 2% to about 5%, about 2% to about 4%, about 2% to about 3%, about 3% to about 5%, about 3% to about 4%, or about 4% to about 5%.

The glass and glass ceramic composition may comprise P₂O₅。P₂O₅Can function as a nucleating agent to produce a bodyAnd (4) nucleating. If P is₂O₅Too low, the precursor glass crystallizes, but (due to the lower viscosity) only at higher temperatures and a weak and usually deformed body is obtained from the surface inwards. However, if P₂O₅Too high, it may be difficult to control devitrification after cooling during forming of the glass sheet. Embodiments may include>0 wt.% to about 6 wt.% P₂O₅. Other embodiments may comprise from about 2 wt% to about 4 wt% P₂O₅. Other embodiments may comprise from about 1.5 wt% to about 2.5 wt% P₂O₅. In some embodiments, the glass or glass-ceramic composition may comprise P as follows₂O₅: 0 wt% to about 6 wt%, 0 wt% to about 5.5 wt%, 0 wt% to 5 wt%, 0 wt% to about 4.5 wt%, 0 wt% to about 4 wt%, 0 wt% to about 3.5 wt%, 0 wt% to about 3 wt%, 0 wt% to about 2.5 wt%, 0 wt% to about 2 wt%, 0 wt% to about 1.5 wt%, 0 wt% to about 1 wt%,>from 0% to about 6% by weight,>0% to about 5.5% by weight,>from 0% by weight to 5% by weight,>0 wt% to about 4.5 wt%,>from 0% by weight to about 4% by weight,>0% to about 3.5% by weight,>from 0% by weight to about 3% by weight,>0 wt.% to about>2.5 wt%, 0 wt% to about 2 wt%,>0% to about 1.5% by weight,>0% to about 1% by weight, about 0.5% to about 6% by weight, about 0.5% to about 5.5% by weight, about 0.5% to about 5% by weight, about 0.5% to about 4.5% by weight, about 0.5% to about 4% by weight, about 0.5% to about 3.5% by weight, about 0.5% to about 3% by weight, about 0.5% to about 2.5% by weight, about 0.5% to about 2% by weight, about 0.5% to about 1.5% by weight, about 0.5% to about 1% by weight, about 1% to about 6% by weight, about 1% to about 5.5% by weight, about 1% to about 5% by weight, about 1% to about 4.5% by weight, about 1% to about 4% by weight, about 1% to about 1% by weight, about 1.5% to about 1% by weight, about 3% to about 1.5% by weight, about 1% to about 1% by weight, about 1% to about 2% by weight, about 1% by weight, and about 1% by weightFrom about 1% to about 2%, from about 1% to about 1.5%, from about 1.5% to about 6%, from about 1.5% to about 5.5%, from about 1.5% to about 5%, from about 1.5% to about 4.5%, from about 1.5% to about 4%, from about 1.5% to about 3.5%, from about 1.5% to about 3%, from about 1.5% to about 2.5%, from about 1.5% to about 2%, from about 2% to about 6%, from about 2% to about 5.5%, from about 2% to about 5%, from about 2% to about 4.5%, from about 2% to about 4%, from about 2% to about 2%, from about 3.5%, from about 2% to about 5%, from about 2.5%, about 2.5% to about 4.5%, about 2.5% to about 4%, about 2.5% to about 3.5%, about 2.5% to about 3%, about 3% to about 6%, about 3% to about 5.5%, about 3% to about 5%, about 3% to about 4.5%, about 3% to about 4%, about 3% to about 3.5%, about 3.5% to about 6%, about 3.5% to about 5.5%, about 3.5% to about 5%, about 3.5% to about 4.5%, about 3.5% to about 4%, about 4% to about 6%, about 4% to about 5.5%, about 4% to about 5%, about 4% to about 4.5%, about 4% to about 5%, about 4.5%, about 5% to about 5%, about, about 5 wt% to about 6 wt%, about 5 wt% to about 5.5 wt%, or about 5.5 wt% to about 6 wt%.

ZrO is commonly found in various glass and glass ceramic compositions₂Li can be improved by significantly reducing glass devitrification during forming and lowering liquidus temperature₂O-Al₂O₃-SiO₂-P₂O₅Stability of the glass. At a concentration above 8% by weight ZrSiO₄The main liquidus phase will be formed at high temperatures, which significantly reduces the liquidus viscosity. When the glass contains more than 2 wt% ZrO₂When the temperature of the water is higher than the set temperature,a transparent glass will be formed. With addition of ZrO₂It may also help to reduce the grain size of petalite, which helps to form a transparent glass-ceramic. In some embodiments, the glass or glass-ceramic composition may comprise from about 0.2 wt.% to about 15 wt.% ZrO₂. In some embodiments, the glass or glass-ceramic composition may comprise from about 2 wt.% to about 4 wt.% ZrO₂. In some embodiments, the glass or glass-ceramic composition may comprise ZrO as follows₂: about 0.2% to about 15%, about 0.2% to about 12%, about 0.2% to about 10%, about 0.2% to about 8%, about 0.2% to about 6%, about 0.2% to about 4%, about 0.5% to about 15%, about 0.5% to about 12%, about 0.5% to about 10%, about 0.5% to about 8%, about 0.5% to about 6%, about 0.5% to about 4%, about 1% to about 15%, about 1% to about 12%, about 1% to about 10%, about 1% to about 8%, about 1% to about 6%, about 0.5% to about 4%, about 1% to about 6%, about 1% to about 4%, about 2% to about 2%, about 2% to about 10%, about 1% to about 8%, about 1% to about 6%, about 1% to about 4%, about 2% to about 2%, about 2% to about 10%, about 2 wt% to about 6 wt%, about 2 wt% to about 4 wt%, about 3 wt% to about 15 wt%, about 3 wt% to about 12 wt%, about 3 wt% to about 10 wt%, about 3 wt% to about 8 wt%, about 3 wt% to about 6 wt%, about 3 wt% to about 4 wt%, about 4 wt% to about 15 wt%, about 4 wt% to about 12 wt%, about 4 wt% to about 10 wt%, about 4 wt% to about 8 wt%, about 4 wt% to about 6 wt%, about 8 wt% to about 15 wt%, about 8 wt% to about 12 wt%, about 8 wt% to about 10 wt%, about 10 wt% to about 15 wt%, about 10 wt% to about 12 wt%, or about 12 wt% to about 15 wt%.

B₂O₃It is advantageous to provide a glass sheet having a low melting temperature. In addition, B is added to the glass sheet₂O₃(further adding B to the glass-ceramic article₂O₃) Helps achieve an interlocking crystalline microstructure and may also improve the damage resistance of the glass-ceramic article. When the boron in the residual glass is not charge balanced by the alkaline oxide or divalent cation oxide, it will be in a deltoid coordination state (or, tridentate boron), which opens the structure of the glass. The network around these three-coordinate boron is not as rigid as tetrahedrally-coordinated (or four-coordinated) boron. Without being bound by theory, it is believed that glass sheets and glass-ceramics comprising tridentate boron can tolerate some degree of deformation prior to crack formation. The vickers indentation crack initiation value is increased due to the tolerance of some deformation. The fracture toughness of glass sheets and glass-ceramics containing tridentate boron may also be increased. Without being bound by theory, it is believed that the presence of boron in the residual glass (and glass flakes) of the glass-ceramic reduces the viscosity of the residual glass (or glass flakes), which facilitates the growth of lithium silicate crystals, particularly large crystals with high aspect ratios. It is believed that a greater amount of tridentate boron (relative to tetradentate boron) results in the glass-ceramic exhibiting a greater vickers indentation crack initiation load. In some embodiments, the amount of tridentate boron (as all B)₂O₃By percentage) may be about 40% or greater, 50% or greater, 75% or greater, 85% or greater, or even 95% or greater. In general, the amount of boron should be controlled to maintain the chemical durability and mechanical strength of the cerammed bulk glass-ceramic.

In one or more embodiments, the glass or glass-ceramic composition comprises 0 wt.% to about 10 wt.% or 0 wt.% to about 2 wt.% B₂O₃. In some embodiments, the glass or glass-ceramic composition may comprise B as follows₂O₃: 0 wt% to about 10 wt%, 0 wt% to about 9 wt%, 0 wt% to about 8 wt%, 0 wt% to about 7 wt%, 0 wt% to about 6 wt%, 0 wt% to about 5 wt%, 0 wt% to about 4 wt%, 0 wt% to about 3 wt%, 0 wt% to about 2 wt%, 0 wt% to about 1 wt%,>from 0% to about 10% by weight,>from 0% to about 9% by weight,>from 0% to about 8% by weight,>from 0% to about 7% by weight,>from 0% to about 6% by weight,>from 0% by weight to about 5% by weight,>from 0% by weight to about 4% by weight,>from 0% by weight to about 3% by weight,>from 0% by weight to about 2% by weight,>0% to about 1%, about 1% to about 10%, about 1% to about 8%, about 1% to about 6%, about 1% to about 5%, about 1% to about 4%, about 1% to about 2%, about 2% to about 10%, about 2% to about 8%, about 2% to about 6%, about 2% to about 4%, about 3% to about 10%, about 3% to about 8%, about 3% to about 6%, about 3% to about 4%, about 4% to about 5%, about 5% to about 8%, about 5% to about 7.5%, about 5% to about 6%, or about 5% to about 5.5%.

MgO can enter petalite crystals in partial solid solution. In one or more embodiments, the glass or glass ceramic composition may comprise 0 wt.% to about 8 wt.% MgO. In some embodiments, the glass or glass-ceramic composition may comprise MgO as follows: 0 wt% to about 8 wt%, 0 wt% to about 7 wt%, 0 wt% to about 6 wt%, 0 wt% to about 5 wt%, 0 wt% to about 4 wt%, 0 wt% to about 3 wt%, 0 wt% to about 2 wt%, 0 wt% to about 1 wt%, about 1 wt% to about 8 wt%, about 1 wt% to about 7 wt%, about 1 wt% to about 6 wt%, about 1 wt% to about 5 wt%, about 1 wt% to about 4 wt%, about 1 wt% to about 3 wt%, about 1 wt% to about 2 wt%, about 2 wt% to about 8 wt%, about 2 wt% to about 7 wt%, about 2 wt% to about 6 wt%, about 2 wt% to about 5 wt%, about 2 wt% to about 4 wt%, about 2 wt% to about 3 wt%, about 3 wt% to about 8 wt%, about 3 wt% to about 3 wt%, about 3 wt% to about 7 wt%, about 3 wt% to about 3 wt%, about 3 wt% to about 6 wt%, about 3 wt% to about 5 wt%, about 3 wt% to about 4 wt%, about 4 wt% to about 8 wt%, about 4 wt% to about 7 wt%, about 4 wt% to about 6 wt%, about 4 wt% to about 5 wt%, about 5 wt% to about 8 wt%, about 5 wt% to about 7 wt%, about 5 wt% to about 6 wt%, about 6 wt% to about 8 wt%, about 6 wt% to about 7 wt%, or about 7 wt% to about 8 wt%.

ZnO can enter petalite crystals in partial solid solution. In one or more embodiments, the glass or glass ceramic composition may comprise 0 wt.% to about 10 wt.% ZnO. In some embodiments, the glass or glass ceramic composition may comprise ZnO as follows: 0 wt% to about 10 wt%, 0 wt% to about 9 wt%, 0 wt% to about 8 wt%, 0 wt% to about 7 wt%, 0 wt% to about 6 wt%, 0 wt% to about 5 wt%, 0 wt% to about 4 wt%, 0 wt% to about 3 wt%, 0 wt% to about 2 wt%, 0 wt% to about 1 wt%, about 1 wt% to about 10 wt%, about 1 wt% to about 9 wt%, about 1 wt% to about 8 wt%, about 1 wt% to about 7 wt%, about 1 wt% to about 6 wt%, about 1 wt% to about 5 wt%, about 1 wt% to about 4 wt%, about 1 wt% to about 3 wt%, about 1 wt% to about 2 wt%, about 2 wt% to about 10 wt%, about 2 wt% to about 9 wt%, about 2 wt% to about 8 wt%, about 2 wt% to about 7 wt%, about 2% to about 6%, about 2% to about 5%, about 2% to about 4%, about 2% to about 3%, about 3% to about 10%, about 3% to about 9%, about 3% to about 8%, about 3% to about 7%, about 3% to about 6%, about 3% to about 5%, about 3% to about 4%, about 4% to about 10%, about 4% to about 9%, about 4% to about 8%, about 4% to about 7%, about 4% to about 6%, about 4% to about 5%, about 5% to about 10%, about 5% to about 9%, about 5% to about 8%, about 5% to about 5%, about 5% to about 7%, about 5% to about 6%, from about 6 wt% to about 10 wt%, from about 6 wt% to about 9 wt%, from about 6 wt% to about 8 wt%, from about 6 wt% to about 7 wt%, from about 7 wt% to about 10 wt%, from about 7 wt% to about 9 wt%, from about 7 wt% to about 8 wt%, from about 8 wt% to about 10 wt%, from about 8 wt% to about 9 wt%, or from about 9 wt% to about 10 wt%.

In various embodiments, the glass or glass-ceramic composition may further comprise one or more components, such as, but not limited to, TiO₂、CeO₂And SnO₂. Additionally or alternatively, an antimicrobial component may be added to the glass or glass-ceramic composition. Antimicrobial components that may be added to the glass or glass-ceramic may include, but are not limited to: ag. AgO, Cu, CuO and Cu₂O, and the like. In some embodiments, the glass or glass-ceramic composition may further comprise a chemical fining agent. Such fining agents include, but are not limited to, SnO₂、As₂O₃、Sb₂O₃F, Cl and Br. Additional details of Glass and/or Glass ceramic compositions suitable for use in various embodiments can be found, for example, in U.S. patent application publication No. 2016/0102010, entitled "High Strength Glass-Ceramics Having Glass ceramic and Lithium Silicate Structures," filed 10/8/2015, which is incorporated herein by reference in its entirety.

In various embodiments, the glass composition may be fabricated into a sheet by processes including, but not limited to: slot draw, float, roll, and other sheet forming processes known to those skilled in the art.

According to various embodiments herein, the thickness uniformity of the glass sheet 108 is controlled to reduce the warpage of the glass-ceramic article. In fig. 13, the maximum warp of a glass stack of 10 glass sheets and 24 glass sheets for both the freshly rolled glass and the polished (lapped) glass is shown. As shown in fig. 13, the maximum warpage is significantly increased for a glass stack comprising a freshly rolled glass sheet with a maximum thickness variation of 64 μm compared to a glass stack comprising a polished glass sheet with a maximum thickness variation of 21 μm. Thus, as evidenced by the data of fig. 14, the impact of flatness (as described above) of a given plate 104 is limited by variability in the thickness of the glass sheet. Specifically, fig. 14 shows that for a 10-glass sheet stack configuration of just-rolled glass, a 78 μm reduction in flatness for a given plate has a limited effect on the warpage of the glass-ceramic article. Thus, in various embodiments, after sheet forming, the glass sheet may be machined or otherwise processed to reduce thickness variability of the glass sheet.

In various embodiments, edge beads can be removed from the glass sheet to reduce the amount of warping observed in the glass-ceramic article. It is believed that the edge beads have higher thickness non-uniformity and therefore contribute to warpage during the ceramming process. In particular, in embodiments where a single glass sheet is subjected to a ceramming process (e.g., not integrated into a glass stack), removing edge beads may reduce warpage in the glass sheet. As shown in fig. 15A, removal of the edge beads (about 10mm per side of the glass sheet) resulted in a 56 μm reduction in maximum flatness compared to the glass sheet without edge beads removed (fig. 15B). Furthermore, as shown in fig. 16, the stress in the glass-ceramic article when the beads are removed is reduced (bottom) compared to when the glass-ceramic article containing the beads is cerammed (top). However, unexpectedly, in embodiments where the release agent layer is also not incorporated in the glass stack, removal of the edge beads from the glass sheet incorporated into the glass stack results in increased warpage during the ceramming process. Without being bound by theory, it is believed that the increased surface area contact due to the removal of the edge beads of adjacent glass sheets provides additional area for adhesion to occur. Thus, in embodiments where the edge beads are removed and the glass sheets are to be bonded into a glass stack, a release agent is incorporated.

In various embodiments, warpage and stress in the glass-ceramic article are controlled in consideration of component dimensions. As shown in fig. 17, the critical Δ T decreases with feature size. In particular, the critical Δ T is the Δ T at which stress and warpage may be induced for various feature lengths and widths. Thus, for larger components, a larger Δ T may be acceptable without inducing warpage or bending in the final glass-ceramic article.

Thus, in various embodiments, the thickness variation of the glass sheets can be controlled individually or throughout the glass stack, for example, by edge bead removal and polishing to reduce warpage and stress imparted into the glass-ceramic article.

Release agent layer

As described above, in various embodiments, a release agent layer 110 is deposited between adjacent glass sheets 108 in the glass stack 106. In some embodiments, a release agent layer 110 may also be deposited between a given plate 104 and the glass stack 106. For example, the release agent layer 110 may be coated onto a given plate 104, or may be deposited onto the surface of the glass sheet 108 at the top and/or bottom of the glass stack 106.

In various embodiments, the mold release layer 110 is formed from a mold release composition comprising an aqueous dispersion comprising boron nitride and a colloidal inorganic binder. In embodiments, the mold release composition is substantially free of volatile organic solvents. Thus, processes employing the mold release composition may generate less hazardous waste than conventional processes employing alcohol-based products.

According to various embodiments, the mold release composition comprises boron nitride as a lubricant. The use of boron nitride allows the mold release composition to be used in high temperature (e.g., >500 ℃) applications, which may not be feasible with alternative lubricants. Furthermore, boron nitride may be particularly well suited for use as a lubricant in various embodiments because it maintains its lubricating properties throughout the ceramming process. In various embodiments of the mold release composition, the boron nitride is present as agglomerated particles having an average particle size of about 2 μm to about 4 μm. Although the particle size may vary depending on the particular embodiment employed, the particle size should generally not exceed about 4 μm to reduce surface roughness and achieve ultra-thin (e.g., 2gsm dry weight) coating layer formation.

As noted above, the mold release composition also includes a colloidal inorganic binder. The colloidal inorganic binder may include, for example, aluminum oxide (AlOx), but is not limited thereto. Other colloidal inorganic binders may be used provided they do not completely decompose during the heat treatment (e.g., ceramming) process.

In some embodiments, the mold release composition may optionally include one or more dispersants or other additives. For example, antimicrobial additives may be employed. Suitable dispersants include nitric acid and other dispersants known and used in the art. However, in other embodiments, the mold release composition may be substantially free of additional components to reduce the likelihood of reactions occurring between the mold release layer 110 and the glass sheet 108 and/or a given cliche 104.

The mold release composition has a specific gravity of about 1.0 to about 1.2 as measured by drawing a predetermined volume of the mold release composition with a syringe and weighing the volume. Specifically, to measure specific gravity, 10mL of the mold release composition was drawn into a syringe using a 20mL syringe and pushed back to expel air bubbles. The syringe was then wiped clean, placed on a balance, and the balance zeroed. Then, exactly 20mL of the mold release composition was drawn into a syringe, the syringe was wiped clean, and placed on a balance to obtain the weight in the syringe (in grams). The weight was then divided by 20 to obtain the specific gravity.

Additionally or alternatively, in various embodiments, the viscosity of the mold release composition is from about 120 centipoise (cP) to about 160cP, and all ranges and subranges therebetween, as measured by a brookfield DV2TLV viscometer (4 spindle). While the viscosity may vary depending on the particular embodiment, viscosities greater than 160cP or less than 120cP may adversely affect the application of the composition to the glass sheet and may result in an uneven release agent layer.

In various embodiments, the pH of the mold release composition is from about 3 to about 5, and all ranges and subranges therebetween. Specifically, when the mold release composition has a pH in this range, the composition is compatible with the application of the surface of the glass sheet without concern for causing pitting or etching of the surface. Suitable commercially available mold release agents include those available from Zyp coatings corporation (tennessee, usa).

As described above, the release agent composition may be applied to one or more surfaces of the glass sheet 108 and/or to the given cliche plate 104 to form the release agent layer 110. In various embodiments, the mold release composition is applied via a spray dispersion technique (e.g., rotary atomization and/or air-assisted spray dispersion). Without being bound by theory, it is believed that other application techniques (including but not limited to roll coating, dip coating, and ultrasonic powder application) do not achieve the desired layer thicknesses and desired uniformity of various embodiments. Thus, in various embodiments, the mold release composition dries to form a mold release layer 110 having a dry coat weight of from about 2gsm to about 6gsm, and all ranges and subranges therebetween. While the thickness of the release agent layer 110 may vary depending on the particular embodiment, it is generally contemplated that dry coat weights of less than about 2gsm may have an increased risk of sticking. Further, in various embodiments, the release agent layer 110 has a substantially uniform distribution across the surface of the glass sheet 108 and/or a given applicator plate 104.

In the embodiments described herein, coating uniformity is characterized by percent Haze and percent transmission according to ASTM D1003 (for transmission) and ASTM D1044 (for Haze) using a BYK Haze-Gard + instrument available from Paul N gardner Company, Inc. Haze-Gard + enables direct determination of total transmission, Haze and clarity. The instrument used an Illuminant C light source representing average daylight and the calibrated color temperature was 6774K. In various embodiments, the cerammed glass sheet 100 having the release agent layer 110 on one surface thereof has a percent transmission (measured according to ASTM D1003) of about 76% to about 83% and a percent haze (measured according to ASTM D1044) of about 25% to about 38%.

FIG. 18 is a graph of percent transmission (y-axis) versus sample acceptability (x-axis). Specifically, the percent transmission of a Li-based glass-ceramic article comprising a release agent layer is shown. As shown in fig. 18, a coating that is too thick (e.g., greater than about 6gsm) exhibits a percent transmission of less than 70%, while a coating that is too thin (e.g., less than about 2gsm) exhibits a percent transmission of about 85%, but the glass sticks to the adjacent glass sheet. However, any other acceptable sample exhibits a percent transmission of about 76% to about 83% measured according to ASTM D1003.

FIG. 19 is a plot of percent haze (y-axis) versus sample acceptability (x-axis). For samples with coatings that are too thick (e.g., greater than about 6gsm), the percent haze is greater than about 40%, while samples with coatings that are too thin (e.g., less than about 2gsm) have a percent haze of less than about 25% and the samples exhibit stickiness. However, any other acceptable sample exhibits a percent haze of about 25% to about 38% measured according to ASTM D1044.

In various embodiments, the glass-ceramic article comprising the release agent layer 110 exhibits less warpage than a glass-ceramic article formed without the release agent layer 110. In other words, in addition to reducing adhesion between the glass sheet 108 and an adjacent glass sheet 108 and/or a given cliche 104, the release agent layer 110 may also reduce warpage in the final glass-ceramic article. Without being bound by theory, it is believed that applying the release agent layer 110 as described herein may prevent localized sticking that contributes to warpage in the glass-ceramic article. Specifically, during the ceramming process, the glass undergoes shrinkage during phase change and crystal growth, and the presence of the release agent layer 110 allows the glass to move freely rather than being confined in the glass stack 106.

FIG. 20 is a graph of maximum warp (in μm; y-axis) as a function of glass stack position (x-axis). The coatings were applied at a 1.5 "nozzle spacing (solid line) and a 3.0" nozzle spacing (dashed line). Fig. 20 shows that the maximum warpage increases from the bottom (left) of the glass stack to the top (right) of the glass stack. Furthermore, in embodiments where the thickness and uniformity of the coating layer of the applied coating have slight variations (3.0 "jet spacing), the maximum warpage increases with the overall thickness of the glass stack, compared to uniform application of a coating layer of about 2gsm dry coating weight at 1.5" jet spacing. Thus, as evidenced by the data of fig. 20, sticking results in lower yield (yield) and physical degradation of the glass-ceramic article, and localized stiction limits the glass, which increases warpage in the final product.

In addition to reducing warpage of the glass-ceramic article, the release agent layer 110 of the various embodiments described herein has been found to leave the phase set of the glass-ceramic article unchanged. Fig. 9 is an XRD of the glass-ceramic article comprising the release agent layer 110 in the case of just ceramming (C) and in the case of after polishing (D). The surface layer effect was measured to be less than about 1 μm.

Thus, in various embodiments, the release agent layer 110 may reduce CTE mismatch between the glass sheet 108 and a given plate 104, reduce scratching, and extend the life of a given plate 104 by reducing wear. For example, it is believed that a CTE mismatch between the glass sheet 108 and a given plate 104 can result in scratching if the glass sheet 108 becomes adhered to the given plate 104. However, various embodiments of the mold release composition (specifically, the colloidal binder) do not completely decompose during thermal processing. Thus, the release agent composition may be used to coat a given applicator plate 104 such that the given applicator plate 104 needs to be utilized multiple times (e.g., greater than about 25 cycles) before being recoated. Thus, in various embodiments, when the release agent layer 110 is applied in an ultra-thin and uniform layer, it prevents sticking in the high temperature glass-glass stack configuration, which in turn can reduce warpage of the final glass-ceramic article.

Glass stacking structure

In various embodiments described herein, a plurality of glass sheets 108 are arranged into a glass stack 106 for use in a ceramming process. In addition to the variables described above that affect the warpage and stress of the final glass-ceramic article, it has been found that various elements of the glass-stack configuration have an effect on the warpage and stress of the glass-ceramic article.

Thus, in various embodiments, an intermediate layer setter plate 112 may be placed in the glass stack 106, as shown in fig. 21. The inclusion of the interlayer setter plate 112 may increase heat transfer from the top of the glass stack to the bottom of the glass stack and decrease the temperature delay from the top of the glass stack to the bottom of the glass stack. As shown in fig. 22, when the temperature of each glass sheet in a stack comprising a three layer interlayer setter plate was measured during the nucleation stage of the ceramming process, there was a 2.2 ℃ change between the top layer of the top stack and the bottom layer of the bottom stack. Furthermore, as shown in fig. 23, the inclusion of an interlayer setter plate in the glass stack achieves temperature uniformity throughout the glass stack during the top temperature period, although there is still a temperature differential during the warm-up period of the ceramming process.

Furthermore, the inclusion of an interlayer gives the plate 112 reduced warpage and does not significantly affect the stress in the glass-ceramic article, as shown in FIG. 24. Specifically, fig. 24 shows that the inclusion of an interlayer setter plate 112 (right side in the figure) can reset the additional warp at each interlayer setter plate as compared to the increase in warp for a glass stack (left side in the figure) without an interlayer setter plate. In fig. 24, the maximum stress is shown as a line graph, which does not increase with the addition of an intermediate layer to the setter plate.

In addition to including an interlayer setter plate 112 in the glass stack 106, warpage and stress in the glass-ceramic article can be controlled or reduced by limiting the number of glass sheets incorporated into the glass stack. For example, in some embodiments, from a given plate 104 to a given plate 104, a glass stack can be formed from 6 to 24 glass sheets or 10 to 20 glass sheets. In embodiments where interlayer setter plates are arranged in a glass stack, the number of glass sheets between each interlayer setter plate may be 5 glass sheets to 15 glass sheets, or 6 glass sheets to 10 glass sheets.

Thus, various embodiments described herein may be used to produce glass-ceramic articles having superior optical quality and reduced warpage without negatively affecting or even improving the stress in the glass-ceramic article as compared to glass articles cerammed according to conventional techniques. Such glass-ceramic articles may be particularly well suited for use in portable electronic devices due to their strength properties and high transmission values.

It will be apparent to those skilled in the art that various modifications and variations can be made to the embodiments described herein without departing from the spirit and scope of the claimed subject matter. Thus, it is intended that the present description cover the modifications and variations of the various embodiments described herein provided they come within the scope of the appended claims and their equivalents. For example, the features may be combined according to the following non-exhaustive embodiments.

Embodiment 1: a method of ceramming a plurality of glass sheets comprising:

placing a first portion of the plurality of glass sheets in a first stack between a first setter plate and a second portion of the plurality of glass sheets in a second stack between the second setter plate and a third setter plate, the second stack being on top of the first stack in a glass stack configuration; and

exposing the glass stack configuration to a ceramming cycle to ceram the plurality of glass sheets,

wherein a delta T of the first stack or the second stack is less than 10 ℃ when the glass sheets are heated to a nucleation temperature for a predetermined period of time during the ceramming cycle; or

Wherein the delta T of the first stack or the second stack is less than 10 ℃ when the glass sheets are heated to the crystallization temperature for a predetermined period of time during the ceramming cycle.

Embodiment 2: the method of claim 1, wherein the plurality of glass sheets have a maximum thickness variation of 21 μ ι η or less.

Embodiment 3: the method of claim 1 or 2, further comprising removing edge beads from each of the plurality of glass sheets.

Embodiment 4: the method of any one of the preceding claims, further comprising forming a release agent layer from an aqueous dispersion of boron nitride and a colloidal inorganic binder between one of the plurality of glass sheets and an adjacent one of the plurality of glass sheets.

Embodiment 5: the method of any one of the preceding claims, further comprising forming a release agent layer from an aqueous dispersion of boron nitride and a colloidal inorganic binder between one of the plurality of glass sheets and an adjacent one of the first setter plate, the second setter plate, or the third setter plate.

Embodiment 6: the method of any of the preceding claims, wherein a Δ T of a glass stack configuration between a bottom of the first stack proximate the first setter plate and a top of the second stack proximate the third setter plate is 2.2 ℃ or less during the predetermined period of time that glass sheets are maintained at the nucleation temperature.

Embodiment 7: the method of any one of the preceding claims, wherein the ceramming process comprises: controlled cooling at a rate of about 4 c/min from the maximum temperature during ceramming to a temperature of about 450 c, followed by a quenching step to a temperature close to room temperature.

Embodiment 8: the method of any one of the preceding claims, wherein the first, second, and third setter plates each comprise reaction bonded silicon carbide.

Embodiment 9: the method of any of the preceding claims, wherein the first, second, and third setter plates each have a maximum flatness of less than or equal to about 100 μ ι η.

Embodiment 10: the method of any of the preceding claims, wherein the first, second, and third setter plates each have a maximum flatness of less than or equal to about 25 μ ι η.

Embodiment 11: the method of any one of the preceding claims, wherein the first, second and third setter plates each have a thickness t of about 6.5mm to about 10 mm.

Embodiment 12: the method of any of the preceding claims, wherein the glass stack configuration is supported on a carrier plate, the carrier plate comprising open grid configuration steel.

Embodiment 13: a method of ceramming a plurality of glass sheets comprising:

reducing thickness variation in the plurality of glass sheets;

placing the plurality of glass sheets between a first setter plate and a second setter plate in a glass stacking configuration; and

exposing the glass stack configuration to a ceramming cycle to ceram the plurality of glass sheets.

Embodiment 14: the method of claim 13, wherein reducing the thickness variation in the plurality of glass sheets comprises reducing the thickness variation in the plurality of glass sheets to a maximum thickness variation of 21 μ ι η or less.

Embodiment 15: the method of claim 13 or 14, further comprising removing edge beads from each of the plurality of glass sheets.

Embodiment 16: the method of any one of claims 13-15, further comprising forming a release agent layer from an aqueous dispersion of boron nitride and a colloidal inorganic binder between one of the plurality of glass sheets and an adjacent one of the plurality of glass sheets.

Embodiment 17: the method of any of claims 13-16, wherein a Δ T of a glass stack configuration between a glass sheet proximate to the first setter plate and a glass sheet proximate to the second setter plate is 2.2 ℃ or less during the predetermined period of time that the glass sheet is maintained at the nucleation temperature.

Embodiment 18: the method of any one of claims 13-17, wherein the ceramming process comprises: controlled cooling at a rate of about 4 c/min from the maximum temperature during ceramming to a temperature of about 450 c, followed by a quenching step to a temperature close to room temperature.

Embodiment 19: the method of any of claims 13-18, wherein the first given plate and the second given plate each have a maximum flatness of less than or equal to about 25 μ ι η.

Embodiment 20: the method of any of claims 13-19, wherein the glass stack configuration is supported on a carrier plate, the carrier plate comprising open grid configuration steel.