KR20210082443A - Method for making glass articles - Google Patents

Abstract

This invention prevents the formation of stripe-shaped convex defects on the surface of a glass ribbon, and makes it a subject to provide a high-quality glass article. In the present invention, a forming process of flowing a molten glass Gm from a molded body 5 in a forming furnace 1 to shape a glass ribbon G, and a glass ribbon G molded in the forming process in a conveying direction It is a manufacturing method of the glass article provided with the heat processing process of heat-processing to glass ribbon G, conveying along it. The molding process flows down from the molded body 5 and uses the lower refractory brick 7 of the molding furnace 1 opposite to the surface of the glass ribbon G in the thickness direction of the glass ribbon G to form the glass ribbon G. A cooling step is provided. The lower fire brick 7 is divided|segmented into plurality in the width direction of the glass ribbon G, When it observes from the upstream of a conveyance direction, the position of the width direction of the joint 9 between the adjacent lower fire bricks 7 is change in the thickness direction.

Description

Method for making glass articles

The present invention relates to a method for making a glass article.

As a manufacturing method of a glass article, down-draw methods, such as an overflow down-draw method, a slot down-draw method, and a re-draw method, are mentioned.

The manufacturing method of the glass article using such a down-draw method is the shaping|molding process of flowing molten glass from a molded object in a shaping|molding furnace, and shaping|molding a glass ribbon, In the heat treatment furnace arrange|positioned below the shaping|molding furnace, the shape|molded glass ribbon It is equipped with the heat processing process of giving heat processing (slow cooling process) for reducing curvature and distortion to a glass ribbon, conveying downward (for example, refer patent document 1). And after a heat processing process, the glass ribbon cooled to room temperature vicinity is cut|disconnected to predetermined length, a glass plate is manufactured, or it winds up in roll shape and manufactures a glass roll.

Japanese Patent Laid-Open No. 2014-122124

The said shaping|molding process WHEREIN: The process of cooling the surface of the glass ribbon flowed down from the molded object may be performed separately from the heat processing process. At this cooling process, a glass ribbon is cooled by radiating the heat|fever of a glass ribbon out of a furnace using the lower firebrick of the shaping|molding furnace which opposes in the thickness direction of the surface of a glass ribbon, and a glass ribbon.

By the way, the lower firebrick may become a structure divided|segmented into plurality in the width direction of a glass ribbon in consideration of exchange easiness, etc. However, in the case of this structure, there exists a possibility that the stripe-shaped convex defect extended along a conveyance direction may form on the surface of a glass ribbon in the position opposing the joint between adjacent lower firebricks. When such a stripe-shaped convex defect is formed, the smoothness of the surface of the glass article manufactured will lose|eliminate, and there exists a problem that it becomes impossible to manufacture a high-quality glass article.

Here, it is thought that the stripe-shaped convex defect generate|occur|produced for the following reason. That is, gas easily flows into and out of the molding furnace through the joint of the lower fire brick. As a result, heat dissipation of a glass ribbon becomes large in the position opposing the joint of a lower firebrick, and only the predetermined site|part of a glass ribbon is easy to cool locally. And when such local cooling generate|occur|produces, it is thought that the surface of a glass ribbon will shrink|contract and swell locally, and it will become a stripe-shaped convex defect.

This invention prevents that stripe-shaped convex defect is formed in the surface of a glass ribbon, and makes it a subject to provide a high-quality glass article.

The present invention, devised to solve the above problems, is a forming process of forming a glass ribbon by flowing molten glass from a molded body in a forming furnace, and conveying the glass ribbon molded in the forming process along the conveying direction to the glass ribbon In the manufacturing method of the glass plate provided with the heat processing process which heat-processes, the shaping|molding process uses the lower firebrick of the shaping|molding furnace which opposes in the thickness direction of the surface of the glass ribbon flowed from a molded object, and a glass ribbon, a glass ribbon When the process of cooling is provided, the lower firebrick is divided|segmented into plurality in the width direction of a glass ribbon, and when it observes from the upstream of a conveyance direction, the position of the width direction of the joint between adjacent lower firebricks is a glass ribbon It is characterized in that it changes in the thickness direction of When it does in this way, it can inhibit that the gas inside and outside a shaping|molding furnace flows through the joint of a lower firebrick, and the sealing property of the joint of a lower firebrick improves. Therefore, the situation that only the predetermined site|part of a glass ribbon is locally cooled in the position opposing the joint of a lower firebrick can be suppressed, and it can prevent that stripe-shaped convex defect is formed in the surface of a glass ribbon.

Said structure WHEREIN: When it observes from the upstream of a conveyance direction, it is preferable that the joint between adjacent lower firebricks has a bending part. When it does in this way, the joint of a lower firebrick will bend by a bending part, and the sealing property will further improve. Therefore, the situation that only the predetermined member of a glass ribbon is locally cooled in the position opposing a joint can be suppressed more reliably.

Said structure WHEREIN: When it observes from the glass ribbon side, it is preferable that the position of the width direction of the joint between adjacent lower firebricks changes in a conveyance direction. Since the position where a glass ribbon and the joint of a lower firebrick oppose changes in this way, the situation that only the predetermined site|part of a glass ribbon cools can be suppressed more reliably.

Said structure WHEREIN: When it observes from the glass ribbon side, it is preferable that the joint between adjacent lower firebricks extends in the direction which inclines with respect to a conveyance direction. Since the position where a glass ribbon and the joint of a lower firebrick oppose changes continuously when it does in this way, the situation that only the predetermined site|part of a glass ribbon is locally cooled can be suppressed more reliably.

In the above configuration, the forming furnace includes an upper fire brick facing the molded body, and a connection fire brick connecting the lower end of the upper fire brick and the upper end of the lower fire brick so that the lower fire brick approaches the glass ribbon side rather than the upper fire brick. You may have it ready. In this way, since a lower firebrick can be made close to a glass ribbon and the space between both can be made small, the glass ribbon flowed down from a molded object using a lower firebrick can be cooled efficiently.

The said structure WHEREIN: When the firebrick for a connection is divided|segmented into plurality by the width direction and it observes from the upstream of a conveyance direction, the position of the width direction of the joint between adjacent firebricks for a connection is the thickness direction of a glass ribbon. It is preferable to change from When it does in this way, the sealing property of the joint of the fire brick for a connection improves. Therefore, it becomes difficult for the gas inside and outside a forming furnace to flow directly through the joint of the firebrick for a connection. Therefore, the situation that only the predetermined member of a glass ribbon is locally cooled in the position opposing the joint of the firebrick for a connection can be suppressed, and it can prevent that stripe-shaped convex defect is formed.

Said structure WHEREIN: When it observes from the upstream of a conveyance direction, it is preferable that the joint between adjacent firebricks for a connection has a bending part. When it does in this way, the joint of the fire brick for a connection will bend by a bending part, and the sealing property will further improve. Therefore, the situation that only the predetermined member of a glass ribbon is locally cooled in the position opposing a joint can be suppressed more reliably.

Said structure WHEREIN: When it observes from the glass ribbon side, it is preferable that the position of the width direction of the joint between adjacent firebricks for a connection changes in a conveyance direction. Since the position where a glass ribbon and the joint of a firebrick for a connection oppose changes in this way, the situation that only the predetermined site|part of a glass ribbon is cooled locally can be suppressed more reliably.

Said structure WHEREIN: When it observes from the glass ribbon side, it is preferable that the joint between adjacent firebricks for a connection extends in the direction which inclines with respect to a conveyance direction. Since the position where a glass ribbon and the joint of a firebrick for a connection oppose changes continuously when it does in this way, the situation that only the predetermined site|part of a glass ribbon is cooled locally can be suppressed more reliably.

The present invention, devised to solve the above problems, is a forming process of forming a glass ribbon by flowing molten glass from a molded body in a forming furnace, and conveying the glass ribbon molded in the forming process along the conveying direction to the glass ribbon The manufacturing method of the glass article provided with the heat processing process which heat-processes WHEREIN: The shaping|molding process uses the lower refractory brick of the shaping|molding furnace which opposes in the thickness direction of the surface of the glass ribbon flowed down from a molded object, and a glass ribbon, A glass ribbon When a lower fire brick is divided into a plurality in the width direction of the glass ribbon and observed from the glass ribbon side, the position in the width direction of the joint between adjacent lower fire bricks changes in the conveyance direction. characterized by being Since the position in which a glass ribbon and the joint of a lower firebrick oppose changes in this way, the situation that only the predetermined site|part of a glass ribbon cools locally can be suppressed. Accordingly, it is possible to prevent the formation of stripe-shaped convex defects on the surface of the glass ribbon.

ADVANTAGE OF THE INVENTION According to this invention, it can prevent that stripe-shaped convex defect is formed in the surface of a glass ribbon, and a high-quality glass article can be provided.

1 is a schematic longitudinal sectional view of an apparatus for manufacturing a glass article;
It is AA sectional drawing of FIG. 1, and shows the state of the joint of the lower firebrick at the time of observing from the glass ribbon side, and the firebrick for a connection.
It is BB sectional drawing of FIG. 1, and shows the state of the joint of the lower firebrick at the time of observing from the upstream of a conveyance direction.
It is CC sectional drawing of FIG. 1, and shows the state of the joint of the firebrick for a connection at the time of observing from the upstream of a conveyance direction.
It is sectional drawing which shows the modified example of the joint of the lower firebrick at the time of observing from the upstream of a conveyance direction.
It is sectional drawing which shows the modified example of the joint of the lower firebrick at the time of observing from the upstream of a conveyance direction.
It is sectional drawing which shows the modified example of the joint of the lower firebrick at the time of observing from the upstream of a conveyance direction.
It is sectional drawing which shows the modified example of the joint of the lower firebrick at the time of observing from the upstream of a conveyance direction.
It is AA sectional drawing of FIG. 1, and shows the modified example of the joint of the lower firebrick at the time of observing from the glass ribbon side.

EMBODIMENT OF THE INVENTION Hereinafter, one Embodiment which concerns on this invention is described based on an accompanying drawing. In addition, XYZ in a figure is a Cartesian coordinate system. The X direction and the Y direction are horizontal directions, and the Z direction is a vertical direction. While conveying the glass ribbon G in a vertical posture, the X direction is the thickness direction of the glass ribbon G (henceforth, it is only called "thickness direction"), and the Y direction is the width direction of the glass ribbon G ( Hereinafter, only a "width direction") and Z direction turn into the conveyance direction (henceforth only a "conveyance direction") of the glass ribbon G.

As shown in FIG. 1, the manufacturing apparatus of the glass article for embodying the manufacturing method of the glass article which concerns on this embodiment is an apparatus which shape|molds glass ribbon G continuously. A glass plate and a glass roll are contained in the glass article manufactured from the glass ribbon G.

The manufacturing apparatus of a glass article cools the shaping|molding furnace 1 which shape|molds the glass ribbon G, the heat processing furnace 2 which heat-processes the glass ribbon G, and the glass ribbon G to room temperature vicinity. A cooling zone (3), and a pair of rollers (4) provided in a plurality of upper and lower stages in each of the heat treatment furnace (2) and the cooling zone (3) are provided.

Here, the manufacturing apparatus of a glass article is the downstream of the cooling zone 3 WHEREIN: The cutting apparatus which cut|disconnects the glass ribbon G and obtains a glass plate, the end surface processing apparatus which processes the end surface of a glass plate, and washing|cleaning which wash|cleans a glass plate You may be further equipped with the inspection apparatus etc. which test|inspect an apparatus and a glass plate. Or the manufacturing apparatus of a glass article is the downstream of the cooling zone 3 WHEREIN: It winds up the cutting apparatus which cut|disconnects and removes the both ends of the width direction of glass ribbon G, and glass ribbon G in roll shape, and glass You may be further equipped with the winding-up apparatus etc. which obtain a roll.

In the internal space of the molding furnace 1, the molded object 5 which shape|molds the glass ribbon G from the molten glass Gm by the overflow down-draw method is arrange|positioned. The molten glass Gm supplied to the molded object 5 overflows from the groove part 5a formed in the top part of the molded object 5, and the molten glass Gm which overflowed is the cross-section wedge of the molded object 5. The plate-shaped glass ribbon G is continuously shape|molded by joining at the lower end along the both side surface 5b which shows a shape. The glass ribbon G shape|molded is a vertical attitude|position (preferably a vertical attitude|position).

The forming furnace 1 has an upper fire brick 6, a lower fire brick 7, and a connection fire brick 8 connecting the lower end of the upper fire brick 6 and the upper end of the lower fire brick 7 are doing The firebrick 8 for a connection is connecting the upper firebrick 6 and the lower firebrick 7 so that the lower firebrick 7 may approach the glass ribbon G side rather than the upper firebrick 6 . In addition, you may abbreviate|omit the fire brick 8 for a connection.

At the position corresponding to the upper firebrick 6, the temperature of the molten glass Gm which flows down the surface of the molded object 5 is adjusted. The temperature of the molten glass Gm which flows down the surface of the molded object 5 can be adjusted with heating apparatuses (not shown), such as a heater provided in the position corresponding to the upper firebrick 6, for example. The heating device can be installed inside the furnace or outside the furnace of the upper refractory brick 6 . Alternatively, the heating device may be embedded in the upper refractory brick (6).

The lower fire brick 7 is opposing in the thickness direction with the surface of the glass ribbon G flowed down from the molded object 5, and the glass ribbon G is cooled using the lower fire brick 7. This cooling aims at adjusting the thickness variation of the glass ribbon G, and is implemented by radiating the heat|fever of the glass ribbon G out of a furnace through the lower firebrick 7. That is, the lower fire brick 7 corresponds to a heat dissipation zone. In addition, heating apparatuses, such as a heater, are not provided in the position corresponding to the lower fire brick 7 .

Here, for example, the upper refractory brick 6 and the lower refractory brick 7 are formed of silicon carbide (SiC) brick or the like, and the connection fire brick 8 is formed of an alumina zircon brick or the like. .

The internal space of the heat treatment furnace 2 has a predetermined temperature gradient downward. As the glass ribbon G of the vertical orientation moves downward in the internal space of the heat treatment furnace 2, it is slowly cooled (annealed) so that temperature may become low. This slow cooling is for adjusting (reducing) the curvature and deformation|transformation of the glass ribbon G. The temperature gradient of the internal space of the heat treatment furnace 2 can be adjusted by, for example, a heating device (not shown) such as a heater provided at a position corresponding to the heat treatment furnace 2 . The heating device may be installed inside or outside the furnace of the heat treatment furnace 2 . Alternatively, the heating device may be embedded in the furnace wall of the heat treatment furnace 2 .

The some roller pair 4 clamps each of the width direction both ends of the glass ribbon G of a vertical posture from front and back both sides. In addition, the roller pair 4 is not provided in the area|region from the lower end of the molded object 5 to the lower end of the lower firebrick 7 .

The uppermost roller pair 4a among the plurality of roller pairs 4 is provided near the upper end of the heat treatment furnace 2 and is composed of a cooling roller (edge roller) that cools both ends of the glass ribbon G in the width direction. has been This cooling roller is for suppressing the shrinkage|contraction of the width direction of the glass ribbon G.

In addition, in the internal space of the heat treatment furnace 2, etc., the thing which does not pinch the width direction edge part of the glass ribbon G among the some roller pair 4 may be contained. In other words, you may make the opposing space|interval of the roller pair 4 larger than the thickness of the width direction edge part of the glass ribbon G, and you may make it pass between the roller pairs 4, the glass ribbon G.

As shown in FIG. 2, the lower firebrick 7 and the firebrick 8 for a connection are divided|segmented into plurality by the width direction. Therefore, the joints 9 and 10 are formed between each brick 7 and 8 adjacent in the width direction. In addition, the firebrick 8 for a connection is not divided|segmented into plurality in the width direction, and the integrated structure without a joint may be sufficient.

When observed from the glass ribbon G side, the joint 9 of the lower firebrick 7 is the linear shape inclined with respect to a conveyance direction, and the position of the width direction is changing in a conveyance direction. Similarly, when it observes from the glass ribbon G side, the joint 10 of the fire brick 8 for a connection is also the linear shape inclined with respect to a conveyance direction, and the position of the width direction is changing in a conveyance direction. Thereby, since the position of the width direction which the glass ribbon G and the joints 9 and 10 oppose changes sequentially in a conveyance direction, only the predetermined site|part of the width direction of the glass ribbon G continues locally The situation of cooling can be suppressed. In addition, in the example of illustration, although the inclination direction of the joint 9 and the inclination direction of the joint 10 are mutually opposite, the same direction may be sufficient. Moreover, the thing used as the inclination direction different in the joint 9 (or the joint 10) may be included. In addition, when observed from the glass ribbon G side, if the position of the width direction of the joints 9 and 10 changes in the conveyance direction, the shape of the change of the joints 9 and 10 is not limited to a linear shape. does not However, if it is linear, there exists an advantage that it is easy to process the bricks 7 and 8.

As shown in FIG. 3, when it observes from the upstream of a conveyance direction, the joint 9 of the lower firebrick 7 has the bending part 9a, and the position of the width direction is changing in the thickness direction. Similarly, as shown in FIG. 4, when it observes from the upstream of a conveyance direction, the joint 10 of the fire brick 8 for a connection also has the bending part 10a, The position of the width direction changes in the thickness direction, have. Thereby, since the sealing property of the joints 9 and 10 improves, it becomes difficult for the gas inside and outside the shaping|molding furnace 1 to flow directly through the joints 9 and 10. Therefore, in the position where the glass ribbon G and the joints 9 and 10 oppose, the situation that the predetermined site|part of the width direction of the glass ribbon G is cooled locally can be suppressed.

In the present embodiment, the joint 9 of the lower fire brick 7 has two bent portions 9a. With these bent portions 9a, the joint 9 is formed by two first portions 9b extending along the thickness direction and a second portion 9c extending along the width direction between these first portions 9b. , and has a step shape (hook shape) as a whole. Similarly, the joint 10 of the fire brick 8 for a connection also has the two bent part 10a. With these bent portions 10a, the joint 10 has two first portions 10b extending along the thickness direction, and a second portion 10c extending along the width direction between these first portions 10b. , and has a step shape (hook shape) as a whole. That is, the joints 9 and 10 have a relatively simple shape, but since the second portions 9c and 10c extending along the width direction become a great resistance to the gas passing through the joints 9 and 10, the gas flows It has a difficult structure.

Here, in this embodiment, when it observes from the upstream of a conveyance direction, to the position P1 (or position P2) which faces in the furnace of the joint 9 of the lower firebrick 7 shown in FIG. 3, and FIG. Position Q1 (or position Q2) which faces in the furnace of the joint 10 of the fire brick 8 for a connection shown differs in the width direction without overlapping. That is, in the position P1 (or position P2) of the joint 9 of the lower firebrick 7, the part without the joint 10 of the firebrick 8 for a connection is located, and the firebrick 8 for a connection In the position Q1 (or position Q2) of the joint 10, the part without the joint 9 of the lower fire brick 7 is located. Thereby, the influence of the joints 9 and 10 is made to disperse|distribute in the width direction of the glass ribbon G. In addition, in FIG. 2, when it observes from the glass ribbon G side, the formation area|region covering the conveyance direction full length of the joint 9 of the lower fire brick 7, and the joint of the fire brick 8 for a connection ( The form in which the formation area|region covering the conveyance direction full length of 10) does not overlap in the width direction is illustrated.

In addition, in this embodiment, when it observes from the upstream of a conveyance direction, position P1 which faces in the furnace of the joint 9 of the one lower firebrick 7 which opposes one surface of glass ribbon G. ) and the position P2 which faces in the furnace of the joint 9 of the other lower firebrick 7 which opposes the other surface of glass ribbon G differ in the width direction without overlapping. That is, the part without the joint 9 of the other lower firebrick 7 is opposing in the thickness direction in the position which faces the inside of the furnace of the joint 9 of the lower firebrick 7 of one side. Similarly, when it observes from the upstream of a conveyance direction, position Q1 which faces in the furnace of the joint 10 of one firebrick 8 for a connection opposite to the one surface of glass ribbon G, and glass The position Q2 which faces in the furnace of the joint 10 of the other firebrick 8 for a connection opposite to the other surface of the ribbon G differs in the width direction without overlapping. That is, in the position facing the furnace of the joint 10 of the fire brick 8 for one connection, the part without the joint 10 of the fire brick 8 for another connection is opposing in the thickness direction. Thereby, the influence of the joints 9 and 10 is made to disperse|distribute in the both surfaces of the glass ribbon G. In addition, in FIG.3 and FIG.4, when it observes from the upstream of a conveyance direction, the formation area covering the thickness direction full length of the joint 9 of both lower firebrick 7 which opposes mutually overlaps in the width direction. The form which is not formed and the form which does not mutually overlap in the width direction in the thickness direction full length of the joint 10 of both the opposing firebricks 8 for a connection are illustrated respectively.

In addition, in this embodiment, the bending part 10a (or 2nd part 10c) of the joint 10 in the firebrick 8 for a connection is outside the upper firebrick 6, ie, outside a furnace. is located Thereby, the part of the joint 10 facing the inside of the furnace is constituted only by the linear first part 10b along the thickness direction, and the shape of the joint 10 facing the inside of the furnace is simplified. In addition, the bent part 10a (or the 2nd part 10c) of the joint 10 in the firebrick 8 for a connection may be located below the upper firebrick 6, and the upper firebrick 6 ) may be located in the inner furnace.

Next, the manufacturing method of the glass article using the manufacturing apparatus comprised as mentioned above is demonstrated.

As shown in FIG. 1, the manufacturing method of a glass article flows down the molten glass Gm from the molded object 5 within the shaping|molding furnace 1, The shaping|molding process of shape|molding the glass ribbon G, The heat processing furnace 2 ) A heat treatment step of heat-treating the glass ribbon G while conveying the glass ribbon G molded in the inside along the conveying direction, and the heat-treated glass ribbon G in the cooling zone 3 along the conveying direction The cooling process of cooling the glass ribbon G to room temperature vicinity, conveying is provided.

A shaping|molding process cools the glass ribbon G flowed down from the molded object 5 using the lower refractory brick 7 of the shaping|molding furnace 1, and adjusts (reduces) the thickness dispersion|variation of the glass ribbon G. Adjustment process is in place. At an adjustment process, the glass ribbon G is cooled by radiating the heat|fever of the glass ribbon G out of a furnace through the lower firebrick 7 .

Here, the cooling in an adjustment process aims at adjusting the thickness dispersion|variation of the glass ribbon G, and cooling (slow cooling) in a heat processing process adjusts the curvature and deformation|transformation of the glass ribbon G purpose, and both have different purposes. The temperature of the glass ribbon G of an adjustment process is 1000-1300 degreeC, for example, and the temperature of the glass ribbon G of a heat processing process is 500-1000 degreeC, for example. In addition, the viscosity of the glass ribbon G of an adjustment process is 20000-30000 poise, for example, and the viscosity of the glass ribbon G of a heat processing process is 10 ^{5-10 16 poise, for example.}

In an adjustment process, as above-mentioned, when the joint 9 and 10 of the lower firebrick 7 and the firebrick 8 for a connection observe from the glass ribbon G side, the position of the width direction is a conveyance direction , and the position in the width direction changes in the thickness direction when observed from the upstream side of the conveyance direction. Therefore, in an adjustment process, the situation that only the predetermined site|part of the width direction of the glass ribbon G is cooled locally at the position opposing the joints 9 and 10 is suppressed, and the surface of the glass ribbon G It is possible to prevent the formation of stripe-shaped convex defects. Therefore, it is possible to provide a high-quality glass article having excellent surface smoothness.

In addition, this invention is not limited in any of the said embodiment, Within the range which does not deviate from the summary of this invention, it can implement in various further forms.

In the said embodiment, when the joint 9, 10 of the lower fire brick 7 and the fire brick 8 for a connection observes from the upstream of a conveyance direction, it has two bending part 9a, 10a, and as a whole Although the case where the step shape is shown has been described, the number of the bent portions 9a and 10a is not particularly limited. For example, when the joint 9 of the lower fire brick 7 is observed from the upstream side of a conveyance direction, as shown in FIG. 5, for example, the bending part 9a may be one, and in FIG. As shown, it is good also considering the bending|flexion part 9a as three, and good also considering the bending|flexion part 9a as four or more as shown in FIG. Of course, for example, as shown in FIG. 8, when it observes from the upstream of a conveyance direction, you may make the joint 9 into a linear shape inclined with respect to the thickness direction, etc., and it is good also as a shape without a bending part. These matters are similarly applicable to the joint 10 of the fire brick 8 for connection.

In the said embodiment, as shown in FIG. 9, when the joint 9 of the lower fire brick 7 is observed from the glass ribbon G side, the width direction of the upper end point 9d of the joint 9 The position may be the same as the position in the width direction of the lower end point 9e of the adjacent joint 9 . In this way, the situation of local cooling can be suppressed more reliably.

Although the said embodiment demonstrated the case where the bent part 9a, 10a was comprised by the leg part which two straight lines intersect, the bent part 9a, 10a may be comprised by curved parts, such as an arc.

In the said embodiment, when the joint 9 and 10 of the lower firebrick 7 and the firebrick 8 for a connection observe from the (1) glass ribbon G side, the position of the width direction is a conveyance direction (2) Although the case where the position of the width direction changes in the thickness direction when observed from the upstream of (2) conveyance direction was demonstrated, the position of the width direction of the joint 9 of the lower firebrick 7 at least A, any one of the above (1) and (2) may be satisfied. In addition, when only the above (1) is satisfied, the joint becomes a linear shape along the thickness direction when viewed from the upstream side of the conveying direction, and when only the above (2) is satisfied, the joint is observed from the glass ribbon (G) side It becomes a linear shape along a conveyance direction.

Although the said embodiment demonstrated the case where the glass ribbon G is shape|molded by the overflow down-draw method, even if you make it shape|mold the glass ribbon G by other down-draw methods, such as the slot down-draw method and the re-draw method, good.

1: molding furnace
2: Heat treatment furnace
3: cooling zone
4: Roller pair
5: molded body
6: Upper refractory brick
7: lower refractory brick
8: fire brick for connection
9: Joint of lower fire brick
10: joint of fire brick for connection
G: glass ribbon
Gm: molten glass

Claims (10)

A forming step of forming a glass ribbon by flowing molten glass from a molded body in a forming furnace, and a heat treatment step of performing heat treatment on the glass ribbon while conveying the glass ribbon molded in the forming step along a conveying direction; A method for manufacturing a glass article, comprising:
The forming step includes a step of cooling the glass ribbon using a lower refractory brick of the forming furnace that faces the surface of the glass ribbon flowing down from the formed body in the thickness direction of the glass ribbon,
The lower fire brick is divided into a plurality in the width direction of the glass ribbon,
When it observes from the upstream of the said conveyance direction, the said width direction position of the joint between the said lower firebricks which adjoins changes in the said thickness direction, The manufacturing method of the glass article characterized by the above-mentioned. The method of claim 1,
When it observes from the upstream of the said conveyance direction, the joint between the said lower firebricks adjacent has a bending part, The manufacturing method of the glass article characterized by the above-mentioned. 3. The method according to claim 1 or 2,
When it observes from the said glass ribbon side, the position of the said width direction of the joint between the adjacent said lower fire bricks changes in the said conveyance direction, The manufacturing method of the glass article characterized by the above-mentioned. 4. The method of claim 3,
When observed from the said glass ribbon side, the joint between the adjacent said lower firebricks extends in the direction inclined with respect to the said conveyance direction, The manufacturing method of the glass article characterized by the above-mentioned. 5. The method according to any one of claims 1 to 4,
The forming furnace includes an upper firebrick facing the molded body, and a lower end of the upper firebrick and an upper end of the lower firebrick so that the lower firebrick approaches the glass ribbon side rather than the upper firebrick. Fire brick is provided, The manufacturing method of the glass article characterized by the above-mentioned. 6. The method of claim 5,
The fire bricks for connection are divided into a plurality in the width direction, and when observed from the upstream side of the conveyance direction, the position of the joint between the adjacent fire bricks for connection in the width direction changes in the thickness direction A method for manufacturing a glass article, characterized in that 7. The method of claim 6,
When it observes from the upstream of the said conveyance direction, the joint between the adjacent said firebricks for a connection has a bending part, The manufacturing method of the glass article characterized by the above-mentioned. 8. The method according to claim 6 or 7,
When it observes from the said glass ribbon side, the position of the said width direction of the joint between the adjacent said firebricks for a connection changes in the said conveyance direction, The manufacturing method of the glass article characterized by the above-mentioned. 9. The method of claim 8,
When observed from the said glass ribbon side, the joint between the adjacent said firebricks for a connection extends in the direction inclined with respect to the said conveyance direction, The manufacturing method of the glass article characterized by the above-mentioned. A forming step of forming a glass ribbon by flowing molten glass from a molded body in a forming furnace, and a heat treatment step of performing heat treatment on the glass ribbon while conveying the glass ribbon molded in the forming step along a conveying direction; A method for manufacturing a glass article, comprising:
The forming step includes a step of cooling the glass ribbon using a lower refractory brick of the forming furnace that faces the surface of the glass ribbon flowing down from the formed body in the thickness direction of the glass ribbon,
The lower fire brick is divided into a plurality in the width direction of the glass ribbon,
When it observes from the said glass ribbon side, the position of the said width direction of the joint between the adjacent said lower fire bricks changes in the said conveyance direction, The manufacturing method of the glass article characterized by the above-mentioned.

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