EP4208421A1

EP4208421A1 - Method of increasing the strength and/or hardness of a glass article

Info

Publication number: EP4208421A1
Application number: EP21770233.1A
Authority: EP
Inventors: Thomas VOLAND; Sabine HÖNIG; Martin Gross; Heiko Hessenkemper
Original assignee: 2mh Glass GmbH
Current assignee: 2mh Glas GmbH
Priority date: 2020-09-03
Filing date: 2021-09-02
Publication date: 2023-07-12
Also published as: CN116234780A; WO2022049203A1; JP2023539777A; CA3193626A1; TW202220944A; MX2023002582A; AU2021335528A1; LU102043B1; KR20230061419A; US20230312388A1

Abstract

The invention relates to methods of increasing the strength, especially the flexural strength, of a glass article produced from a glass material. The method includes the step of heating the glass article to a first temperature above the transformation temperature of the glass material, the step of shock cooling the glass article to a second temperature below the transformation temperature of the glass material, and the step of performing an ion exchange process at the second temperature.

Description

Method of increasing the strength and/or hardness of a glass article

The invention relates to a method for increasing the strength, in particular the transverse rupture strength, of a glass object made from a glass material, namely alkali-earth-alkaline silicate glass or borosilicate glass.

The invention also relates to a glass article made by the method according to the invention.

Various hardening and strengthening processes are known in order to ideally adapt glass as a versatile high-tech material to the respective application. Most hardening and strengthening processes are either very difficult to use and/or require the use of mostly expensive special glass.

For example, it is known to increase the breaking strength of glass by so-called thermal tempering (colloquially also referred to as thermal hardening or tempering). Here, the glass workpiece to be strengthened is heated to approx. 600 °C in a furnace and then quickly quenched to room temperature. This quenching solidifies the surface and the external dimensions of the component change only slightly. Compressive stresses arise on the surface of the glass workpiece, which ultimately lead to greater breaking strength. Thermal toughening is used in particular in the manufacture of toughened safety glass (ESG). The stress profile of toughened safety glass shows high internal tensile stresses across the glass thickness, which lead to a characteristic crumbly fracture pattern if the pane fails.

It is also known to strengthen glass objects by chemical toughening. In chemical toughening, a distinction is made between processes with so-called high-temperature ion exchange and processes with so-called low-temperature ion exchange. Only processes with low-temperature ion exchange, in which an alkali ion is replaced by a larger alkali ion, have so far found industrial use. In these processes, a zone of compressive stress is created at the surface of the glass by ion exchange, which usually takes place in a bath of molten salt between the glass surface and the salt bath takes place. For example, sodium ions are exchanged for potassium ions, which creates a compressive stress zone on the glass surface because the potassium ions are larger than the sodium ions. For commercially available glasses (alkaline-earth-alkaline-silicate glasses), the treatment time in the molten salt is disadvantageously very long. It is usually between 8 and 36 hours. The problem of long process times can be reduced by using expensive special glasses with the simultaneous use of complicated, in particular multi-stage, treatment processes.

DD 1579 66 discloses a method and a device for strengthening glass products by ion exchange. The glass products are strengthened by alkali ion exchange between the glass surface and alkali salt melts. For solidification, hollow glass products with the opening facing downwards or hollow glass products that are rotated or pivoted about a horizontal axis are sprinkled with molten salt. Here, the salt is constantly circulated and passed through perforated plates in order to create a rain cascade for the glass products arranged in several layers. Disadvantageously, this method can only be used in an economically viable manner when using comparatively expensive special glass.

DE 195 10 202 C2 discloses a method for producing hollow glass bodies using the blow-blow and press-blow shaping method with increased mechanical strength. The method is characterized in that mist-like aqueous alkali metal salt solutions are added to the compressed air in the preliminary and/or finished mold of the blow-blow molding process or in the finished mold of the press-blow molding process.

DE 11 2014 003 344 T5 discloses chemically hardened glass for flat screens of digital cameras, mobile phones, digital organizers, etc. The chemically strengthened glass has a compressive stress layer formed by an ion exchange method, the glass has a surface roughness of 0.20 nm or higher and the hydrogen concentration Y ranges to a depth X from an outermost surface of the glass satisfies the equation Y = aX + b at X = from 0.1 to 0.4 ( m). The glass is preheated to a temperature of 100 °Celsius and then immersed in melted salt.

It is the object of the present invention to specify a method which, while being able to be carried out comparatively quickly, also allows glass objects to be strengthened which are not produced from expensive and specially adapted special glass.

The task is solved by a method which is characterized by the following steps: a. heating the glass article to a first temperature above the glass transition temperature, b. shock cooling the glass article to a second temperature which is below the transformation temperature of the glass material, the shock cooling being effected by contacting the glass article with a cooling medium which has the second temperature, c. performing an ion exchange process at the second temperature for a time ranging from 15 minutes to 45 minutes.

The method according to the invention is based on a skillful combination of thermal and chemical hardening and can be carried out in an advantageous and surprising manner in a comparatively simple, quick and uncomplicated manner. Nevertheless, the method of the present invention offers both significant advantages over thermal toughening and significant advantages over chemical toughening.

In particular, the method according to the invention can be used to achieve very high strength values, in particular with regard to transverse rupture strength, microhardness and scratch resistance, which exceed the strength values of untreated glass many times over, but the required process times are very short compared to the process times that are usual Process of chemical toughening include. It has been shown that the ion exchange time in the method according to the invention generally needs to be less than 30 minutes in order to be able to achieve strength values that are similar to those achieved by conventional chemical strengthening methods with very long process times and that better ones Strength values are achieved than with pure thermal hardening. The method according to the invention is therefore particularly advantageous for industrial mass production of hardened glass objects.

A further advantage of the method according to the invention is that it offers a very high level of flexibility with regard to the possible wall thicknesses and the possible shapes of the glass objects to be treated. The method according to the invention is suitable both for increasing the strength of flat glass, for example for windows or displays, and for increasing the strength of differently shaped glass objects, in particular vessels and/or crockery objects.

In particular, the invention has the very special advantage that in particular comparatively inexpensive glass material, such as simple utility glass, in particular container glass, can be used as the starting material in order to obtain particularly break-resistant glass objects as a result.

The invention also has the very special advantage that a smaller wall thickness of the glass object is required, in particular for objects of daily use, due to the increased breaking strength. The consequence of this is that glass can be saved in the production of the glass objects compared to glass objects conventionally produced from the same glass material. In particular, the glass objects treated according to the invention can therefore have a lower intrinsic weight than glass objects conventionally produced from the same glass material.

Particularly good results are achieved when the first temperature is in a range from 100 Kelvin to 300 Kelvin above the transformation temperature. In particular, it can advantageously be provided that the first temperature lies in a range of 50 Kelvin below and 30 Kelvin above the Littleton point of the glass material.

The transformation temperature is the temperature at which the glass changes from the plastic state to the rigid state during cooling; in particular the temperature at which the viscosity r| 10 ¹² - ³ Pa s (ten to the power of twelve point three Pascal times second) is.

The Littleton point is the temperature at which the viscosity r| 10 is ⁶ - ⁶ Pa s (Pascal times second).

In particular, it can advantageously be provided that the glass object is heated in such a way that the initial heating rate is 100 Kelvin per minute, in particular over 250 Kelvin per minute.

The glass object can advantageously be heated to a first temperature by transferring the glass object (in particular together with other glass objects of a batch) into an oven. The oven can advantageously have an oven temperature which corresponds to the Littleton point of the glass material or which is at most 50 Kelvin below and at most 30 Kelvin above the Littleton point of the glass material of the glass object. In particular, the oven can advantageously have an oven temperature which is in a range from 10 Kelvin to 40 Kelvin above the first temperature. In particular when using alkali-alkaline earth silicate glass as the glass material, the furnace temperature can advantageously be in the range from 650° Celsius to 770° Celsius, in particular in the range from 740° Celsius to 760° Celsius or in the range from 680° Celsius to 730° Celsius, lie or be 750 °Celsius.

It is important to ensure that the glass article remains in the kiln long enough to reach (at least its outermost layer) the first temperature. However, the glass object must not remain in the oven for too long in order to avoid unwanted deformation of the glass object. It has been shown that particularly good results are achieved with glass objects that are designed as hollow bodies with a wall that has a wall thickness if the glass object is heated up for a time in the range from 35 seconds to 90 seconds, in particular from 45 seconds to 70 Seconds per millimeter of wall thickness, in particular for a heating time of 55 seconds per millimeter of wall thickness, remains in the furnace. In the case of a glass object whose walls have different thicknesses at different points, the wall thickness at the thinnest point is preferably decisive for the heating-up time. For a glass object that is flat and has a thickness, particularly good results are achieved if the glass object is heated for a heating time in the range from 35 seconds to 90 seconds, in particular from 45 seconds to 70 seconds, per millimeter of thickness, in particular for a heating time of 55 seconds per millimeter of thickness, left in the oven. In the case of a glass object which has different thicknesses at different points, the thickness at the thinnest point is preferably decisive for the heating-up time.

In particular in the case of glass objects which have a wall thickness or a thickness of more than 2 millimeters, in particular more than 3 millimeters, and/or glass objects which have very different wall thicknesses or thicknesses in different areas, heating can be carried out in a particularly advantageous manner take place in a multi-stage, in particular two-stage, process. In particular, it can advantageously be provided that the glass object is first heated slowly to an intermediate temperature and then quickly heated to the first temperature. In particular, it can advantageously be provided that the glass object is first heated to an intermediate temperature at a first heating rate and is then heated to the first temperature at a second heating rate, which is higher than the first heating rate.

This procedure has the particular advantage that unwanted deformations of the glass object are effectively avoided, since all areas of the glass object reach the first temperature at the same time or at least within a predetermined or specifiable time window. In this way, it is avoided that the areas of the glass object that can be heated up more quickly are already deformed (unintentionally) while it is still necessary to wait until other areas that can be heated up less quickly reach the first temperature.

In addition, this procedure has the particular advantage that interactions between the glass object and the holder, which occur in particular at high temperatures and which hold and/or transport the glass object during the execution of the method, are avoided or at least reduced.

The intermediate temperature is preferably in a range from 50 degrees Kelvin below to 100 Kelvin above the transformation temperature of the glass material, in particular in a range from 0 Kelvin to 50 Kelvin above the transformation temperature of the glass material.

In order to achieve this, the oven temperature can be increased after the first heating-up phase, for example. Alternatively, it is also possible to use two ovens with different oven temperatures, with the glass object being transferred after the first heating-up phase from the first oven to the second oven, which has a higher oven temperature, for the second heating-up phase. In a particularly advantageous embodiment, a furnace is used which has furnace areas at different temperatures, so that after the first heating-up phase in a first furnace area, the glass object can be transferred to a second furnace area for the second heating-up phase.

In particular, it can advantageously be provided that the glass object is first heated at a first oven temperature and then at a second oven temperature, which is higher than the first oven temperature. It is of particular advantage here if the glass object is exposed to the second oven temperature for a heating time in the range from 30 seconds to 120 seconds, in particular from 80 seconds to 100 seconds, or for a heating time of 90 seconds. In this way it is achieved that the glass object reaches the primary temperature everywhere without the glass object becoming deformed.

In the case of alkali-earth-alkaline silicate glass, the upper furnace temperature can advantageously be in the range from 680° Celsius to 730° Celsius.

In an advantageous embodiment, the chilling is carried out without delay once the glass article has reached the first temperature. At a minimum, the chilling is preferably carried out with a delay of no more than one minute after the glass article has reached the first temperature. In this way it is avoided that the glass object heated to the first temperature initially cools down again slowly, in particular to a temperature outside a range of 100 Kelvin to 300 Kelvin above the transformation temperature, before the shock cooling takes place. Particularly good strength values are achieved when the second temperature is in a range from 50 Kelvin to 200 Kelvin below the transformation temperature.

In a particularly advantageous embodiment, the chilling is carried out by bringing the glass object into contact with a cooling agent which is a liquid or a suspension.

The cooling medium has the second temperature. In particular, the shock cooling can be carried out by immersing the glass object in a cooling bath that contains the cooling agent. Alternatively, it is also possible, for example, for the contacting to take place by spraying or by sprinkling with the cooling agent, which preferably has the second temperature.

In a manner according to the invention, it was recognized in particular that particularly good results are achieved when the glass object—in contrast to conventional tempering, for example—is not quenched to room temperature but to the second temperature at which the ion exchange process is also carried out. Preferably, there is no time lag and/or reheating of the glass article between the process of shock cooling by contacting the glass article with the cooling agent and the start of the ion exchange process. Such a procedure is particularly efficient and leads to particularly good results with regard to the strength, in particular the transverse rupture strength, of the glass object.

It was also recognized that the initial cooling rate is essentially determined by the difference between the primary temperature and the temperature of the coolant and by the material-specific heat transfer coefficient. In particular, particularly good results in terms of breaking strength are achieved when the first temperature and the cooling medium temperature are selected such that the initial cooling rate is in the range from 80 Kelvin to 120 Kelvin per second, in particular in the range from 90 Kelvin to 110 Kelvin per second , or 100 Kelvin per second.

The ion exchange process preferably includes ions, in particular alkali ions, in particular sodium ions, to be removed from the glass object and to be replaced by spatially larger ions, in particular alkali ions, in particular potassium ions. Preferably, as previously mentioned, the ion exchange process involves contacting the glass article with an exchange agent.

In a particularly advantageous embodiment, a replacement agent is used in the form of a replacement salt melt or in the form of a paste or suspension containing a replacement salt. In this case, in particular, it can advantageously be provided that the exchange salt is potassium nitrate or contains potassium nitrate.

In particular, the glass object can be brought into contact with the exchange agent by immersion or by spraying or by sprinkling.

In a particularly advantageous embodiment, the cooling medium is also the exchange medium at the same time. In particular, provision can advantageously be made for the glass object to be immersed in the exchange medium, which simultaneously acts as the cooling medium, after heating to the first temperature, as a result of which the shock cooling takes place immediately and the ion exchange process begins immediately. This procedure is particularly advantageous in particular with regard to a short process time.

According to the invention, the ion exchange process is carried out for a period ranging from 15 minutes to 45 minutes. However, it has been shown that very high strength values are achieved if the ion exchange process lasts for a period in the range from 20 minutes to 40 minutes, in particular for about 30 minutes.

The glass material is preferably not an aluminosilicate glass because such glass is too complex and, in particular, too expensive to produce. The glass material preferably has an aluminum oxide content of less than 5% (percent by mass) (Al2O3<5%), in particular less than 4.5% (percent by mass) (Al2O3<4.5%).

In particular, alkali-earth-alkaline silicate glass has the particular advantage that it can be obtained inexpensively, but can still be processed into particularly break-resistant glass objects using the method according to the invention. Especially at When using alkali-alkaline earth silicate glass as the glass material, the first temperature can advantageously be in the range from 700° Celsius to 760° Celsius, in particular in the range from 720° Celsius to 740° Celsius. Accordingly, the temperature of the coolant, especially if the coolant is, for example, a molten salt, such as molten sodium salt or molten potassium salt, can advantageously be in the range from 350° Celsius to 500° Celsius, in particular in the range from 390° Celsius to 450° Celsius or in the range from 420 °Celsius to 440 °Celsius, in particular in order to achieve the advantageous cooling rate mentioned above.

The glass material can advantageously have a silicon dioxide content (SiO?) of more than 58% (percent by mass) and less than 85% (percent by mass), in particular more than 70% (percent by mass) and less than 74% (percent by mass). . In particular, a glass material that is an alkali-earth-alkaline silicate glass can advantageously have a silicon dioxide content of more than 70% (percent by mass) and less than 74% (percent by mass).

Alternatively or additionally, it can advantageously be provided that the glass material has an alkali oxide content, in particular sodium oxide content (No2O) and/or lithium oxide content (U2O), in the range from 5% (percent by mass) to 20% (percent by mass), in particular in the range from 10% ( Mass percent) to 14.5% (mass percent) or in the range of 12% (mass percent) to 13.5% (mass percent).

The glass material can (alternatively or additionally) advantageously have a potassium oxide (K2O) content of at most 7% (percent by mass), in particular at most 3% (percent by mass) or at most 1% (percent by mass). In particular, the glass material can have a potassium oxide content in the range from 0.5% (percent by mass) to 0.9% (percent by mass).

Alternatively or additionally, it can advantageously be provided that the glass material has a boron trioxide content (B2O3) of less than 15% (percent by mass), in particular of at most 5% (percent by mass).

As already mentioned, a glass article according to the invention process, has particularly good strength values, although it can be made of an inexpensive glass material. In particular, a strength of the glass object, in particular a strength measured according to DIN EN 1288-5, can be achieved which is at least 1.5 times, in particular at least twice or at least three times or at least four times or at least five times higher than the strength of an identical untreated one Glass object, in particular a glass object of the same shape and size and the same glass material.

For example, it could be proven that commercially available float glass with a thickness of 0.95 mm, which is made of alkali-earth-alkaline silicate glass as the glass material, after a treatment according to the invention, in which a 30-minute ion exchange process was carried out, in a double ring bending test according to DIN EN 1288-5 shows a much higher strength than the same untreated float glass. Float glass with a thickness of 0.95 mm is used for displays, for example. Specifically, the average double ring flexural strength for the samples of untreated float glass was 550 MPa, while the average double ring flexural strength for the samples treated according to the invention was 1,600 MPa.

For example, with the method according to the invention, strength values can be achieved which are at least comparable to the strength of conventional display glasses (in particular display glasses made from special glass and treated with more complex conventional methods).

The glass object can be designed, for example, as a hollow body, in particular a drinking glass, a vase, a mug, a bowl or a bottle. It is also possible for the glass object to be designed as a crockery object, in particular as a plate or platter. The glass object can also be in the form of flat glass, for example for a flat screen.

The subject of the invention is shown schematically and by way of example in the drawing and is described below with reference to the figures, with elements that are the same or have the same effect, even in different exemplary embodiments, are usually provided with the same reference symbols. show: 1 shows a representation of the method according to the invention with regard to the different temperatures during execution, and

2 shows a representation of the temperature conditions when carrying out an exemplary embodiment of a method according to the invention.

1 schematically shows a representation, not true to scale, of the temperature conditions during the implementation of the method according to the invention for increasing the strength, in particular the transverse rupture strength, of a glass article made of a glass material.

In a first step, the glass object is heated 1 from an initial temperature TA, which can be room temperature, for example, to a first temperature Ti, which is above the transformation temperature T _g of the glass material of the glass object. The first temperature Ti is preferably in a first range 3 from 100 Kelvin to 300 Kelvin above the transformation temperature T _g of the glass material.

In a second step, the glass object is shock-cooled 2 to a second temperature T2, which is below the transformation temperature T _g of the glass material. The second temperature is preferably in a second range 4 from 50 Kelvin to 200 Kelvin below the transformation temperature T _g .

Preferably, the chilling 2 is performed by contacting a cooling means having the second temperature T2 and which is at the same time also an exchange means for the third step (not shown) of performing an ion exchange process at the second temperature T2.

The ion exchange process is preferably carried out for a period of time in the range from 15 minutes to 300 minutes, in particular in the range from 20 minutes to 40 minutes, in particular for about 30 minutes.

Fig. 2 schematically shows a representation of the not true to scale Temperature conditions during the execution of an embodiment of a method according to the invention for increasing the strength, in particular the transverse rupture strength, of a glass article made from soda-lime glass.

In a first step, the glass object is heated 1 from an initial temperature TA, which can be 20 °C, for example, in a furnace (not shown) to a first temperature Ti of 745 °C, which is above the transformation temperature T _g of 530 °C of the glass material of the glass article.

In a second step, the glass object is immediately shock-cooled 2 to a second temperature T2, which is 420°C. Shock cooling 2 is carried out by immersing the glass object in a cooling bath (not shown) which contains a molten salt of potassium nitrate as a cooling agent. The molten salt has a temperature of 420 °C.

The molten salt is at the same time also the exchange medium for the third step (not shown) of carrying out an ion exchange process, which is carried out at the second temperature T2 of 420°C. For this purpose, the glass object is left in the molten salt for a period of time in the range from 15 minutes to 300 minutes, in particular in the range from 20 minutes to 40 minutes, in particular for about 30 minutes.

Thereafter, the glass article is taken out from the cooling bath and further cooled down to room temperature in a cooling position outside the cooling bath and finally cleaned.

Reference list:

1 heating

2 Blast chilling 3 First zone

4 Second area

Ti First temperature

T2 Second temperature

TA initial temperature

T _g transformation temperature

Claims

patent claims

1. A method for increasing the strength, in particular the transverse rupture strength, of a glass object made from a glass material, namely alkali-alkaline-earth silicate glass or borosilicate glass, characterized by the following steps: a. heating the glass article to a first temperature above the glass transition temperature, b. shock cooling the glass article to a second temperature which is below the transformation temperature of the glass material, the shock cooling being effected by contacting the glass article with a cooling medium which has the second temperature, c. performing an ion exchange process at the second temperature for a time ranging from 15 minutes to 45 minutes.

2. The method according to claim 1, characterized in that the first temperature is in a range from 100 Kelvin to 300 Kelvin above the transformation temperature.

3. The method according to claim 1 or 2, characterized in that the first temperature is in a range of 50 Kelvin below and 30 Kelvin above the Littleton point of the glass material.

4. The method according to any one of claims 1 to 3, characterized in that the glass object is heated in such a way that the initial heating rate is 100 Kelvin per minute, in particular over 250 Kelvin per minute.

5. The method according to any one of claims 1 to 4, characterized in that the chilling is carried out without delay as soon as the glass object has reached the first temperature, or that the chilling is carried out with a maximum delay of one minute after the glass object has reached the first temperature temperature has reached.

6. The method according to any one of claims 1 to 5, characterized in that the glass article is transferred to an oven for heating.

7. The method according to claim 6, characterized in that the oven has an oven temperature that is above the first temperature or that the oven has an oven temperature that is in a range of 10 Kelvin to 40 Kelvin above the first temperature.

8. The method according to any one of claims 1 to 7, characterized in that the glass object has a thickness and that the glass object for a heating time in the range of 35 seconds to 45 seconds per millimeter thickness, in particular for a heating time of 40 seconds per millimeter thickness, left in the oven.

9. The method according to any one of claims 1 to 8, characterized in that the glass object is a hollow body with a wall that has a wall thickness, and that the glass object for a heating time in the range of 35 seconds to 45 seconds per millimeter of wall thickness, in particular for a heating time of 40 seconds per millimeter of wall thickness, remains in the furnace.

10. The method according to any one of claims 1 to 9, characterized in that the second temperature is in a range from 50 Kelvin to 200 Kelvin below the transformation temperature.

1 1. The method according to any one of claims 1 to 10, characterized in that the cooling agent is a liquid or a suspension.

12. The method according to any one of claims 1 to 11, characterized in that the shock cooling is carried out by immersing the glass object in a cooling bath containing the cooling agent, or by spraying or sprinkling with the cooling agent.

13. The method according to any one of claims 1 to 12, characterized in that the first temperature and the cooling medium temperature of the cooling medium are selected such that the initial cooling rate is in the range from 80 Kelvin to 120 Kelvin per second, in particular in the range from 90 Kelvin to 1 is 10 Kelvin per second, or 100 Kelvin per second.

14. The method according to any one of claims 1 to 13, characterized in that the ion exchange process includes removing ions, in particular alkali ions, especially sodium ions, from the glass object and through 17 to replace spatially larger ions, in particular alkali ions, especially potassium ions.

15. The method according to any one of claims 1 to 14, characterized in that the ion exchange process includes bringing the glass article into contact with an exchange agent, in particular with an exchange agent which has the second temperature.

16. The method according to claim 15, characterized in that the exchange agent is used in the form of an exchange salt melt or in the form of a paste or suspension containing an exchange salt.

17. The method according to claim 16, characterized in that the exchange salt is potassium nitrate or contains potassium nitrate.

18. The method according to claim 16 or 17, characterized in that the glass article is brought into contact with the exchange agent by immersion or by spraying or by sprinkling.

19. The method according to any one of claims 15 to 18, characterized in that the cooling medium is also the exchange medium at the same time.

20. The method according to any one of claims 1 to 19, characterized in that the ion exchange process is carried out for a period of time in the range of 20 minutes to 40 minutes.

21. The method according to any one of claims 1 to 20, characterized in that the glass material is not aluminosilicate glass.

22. The method according to any one of claims 1 to 21, characterized in that the glass material has an aluminum oxide content of less than 5% (mass percent), in particular less than 4.5% (mass percent).

23. The method according to any one of claims 1 to 22, characterized in that the glass material has a silicon dioxide content of more than 58% (mass percent) and less than 85% (mass percent), in particular more than 70% (mass percent) and from less than 74% (mass percent).

24. The method according to any one of claims 1 to 23, characterized in that the glass material has an alkali oxide content, in particular sodium oxide content and/or lithium oxide content, in the range from 5% (mass percent) to 20%. 18

(mass percent), in particular in the range from 10% (mass percent) to 14.5% (mass percent) or in the range from 12% (mass percent) to 13.5% (mass percent). Method according to one of Claims 1 to 24, characterized in that the glass material has a potassium oxide content of at most 7% (mass percent), in particular at most 3% (mass percent) or at most 1% (mass percent), or that the glass material has a Potassium oxide content in the range of 0.5% (mass percent) to 0.9% (mass percent). Method according to one of Claims 1 to 25, characterized in that the glass material has a boron trioxide content of less than 15% (percent by mass), in particular of at most 5% (percent by mass). Glass object produced by a method according to one of Claims 1 to 26. Glass object according to Claim 27, characterized in that the glass object is designed as a hollow body, in particular a drinking glass, a vase, a mug, a bowl or a bottle. Glass article according to claim 27, characterized in that the

Glass object is designed as a crockery item, in particular as a plate. Glass article according to claim 27, characterized in that the

Glass object is designed as a flat glass pane.