KR20240035710A - Residual thickness measuring device, residual thickness measuring method, and glass manufacturing method - Google Patents

Abstract

The object of the present invention is to provide a technique for measuring the residual thickness of the wall of the melting tank without stopping the electric heating of the molten glass.
A residual thickness measuring device measures the residual thickness of the wall of a dissolution tank that stores molten glass that is electrically heated. The residual thickness measuring device includes a metal scale inserted into a through hole in the wall, and an insulating cover covering at least a portion of the outer peripheral surface of the scale on the outside of the wall.

Description

Residual thickness measuring device, residual thickness measuring method, and glass manufacturing method {RESIDUAL THICKNESS MEASURING DEVICE, RESIDUAL THICKNESS MEASURING METHOD, AND GLASS MANUFACTURING METHOD}

The present disclosure relates to a residual thickness measuring device, a residual thickness measuring method, and a glass manufacturing method.

The dissolution tank stores molten glass obtained by dissolving glass raw materials. The wall of the dissolution tank is in contact with the molten glass and gradually erodes over time. Therefore, the thickness of the wall gradually decreases. If the wall thickness becomes smaller than the threshold, repairs are made to prolong life, or operation of the dissolution tank is stopped because its lifespan has reached the end.

Patent Document 1 describes measuring the residual thickness of the side wall of the dissolution tank by inserting a metal scale into the joints between the joints constituting the side wall of the dissolution tank (see paragraph [0006] of Patent Document 1).

Patent Documents 2, 3, and 4 disclose a technique for electrically heating molten glass. Molten glass is electrically heated by a plurality of electrode rods inside the dissolution tank. Joule heat is generated by applying a voltage to the molten glass and passing a current through the molten glass.

Japanese Patent Publication No. 2012-13512 Japanese Patent Publication No. 2018-193268 Japanese Patent Publication No. 61-21170 Japanese Patent Publication No. 4-342425

When measuring the residual thickness of the wall of a melting tank for electric heating using a metal scale, electric heating of the molten glass is temporarily stopped to prevent electric shock to workers when measuring the residual thickness.

When electric heating of molten glass is temporarily stopped, the temperature of the molten glass may fluctuate, and the quality of the product glass may fluctuate. In particular, as the erosion of the wall progresses and the residual thickness becomes thinner, the frequency of measuring the residual thickness increases, thereby increasing the risk of temporarily stopping electric heating.

One aspect of the present disclosure provides a technique for measuring the residual thickness of the wall of a dissolution tank without stopping the electric heating of the molten glass.

The residual thickness measuring device according to one embodiment of the present disclosure measures the residual thickness of the wall of a dissolution tank storing molten glass that is electrically heated. The residual thickness measuring device includes a metal scale inserted into a through hole in the wall, and an insulating cover covering at least a portion of the outer peripheral surface of the scale on the outside of the wall.

According to one aspect of the present disclosure, since at least a portion of the outer peripheral surface of the scale is covered with an insulating cover, electric shock to the worker can be suppressed, and the residual thickness of the wall of the melting tank can be measured without stopping the electric heating of the molten glass. You can.

1 is a cross-sectional view showing a residual thickness measuring device according to one embodiment, (A) is a cross-sectional view showing a state in which a scale is inserted into a through hole in the side wall, and (B) is a cross-sectional view showing a state in which a cover is in contact with the side wall. It is a cross-sectional view, and (C) is a cross-sectional view showing the scale extracted from the through hole in the side wall.
Figure 2 is a cross-sectional view showing a residual thickness measuring device and a dissolution tank according to a modification, (A) is a cross-sectional view showing the state before inserting the scale into the through-hole of the side wall, and (B) is a cross-sectional view showing the scale before inserting the scale into the through-hole of the side wall. (C) is a cross-sectional view showing the state in which the scale is extracted from the through hole in the side wall.

Hereinafter, embodiments of the present disclosure will be described with reference to the drawings. In addition, in each drawing, identical or corresponding components are given the same reference numerals and descriptions may be omitted. In the specification, “to” indicating a numerical range means including the numerical values described before and after as the lower limit and upper limit.

With reference to FIG. 1 , a residual thickness measuring device 100 according to one embodiment will be described. The residual thickness measuring device 100 measures the residual thickness of the wall of the dissolution tank 10. The dissolution tank 10 stores molten glass G formed by dissolving glass raw materials. The wall of the dissolution tank 10 is in contact with the molten glass G, and is gradually eroded over time. Therefore, the thickness of the wall of the dissolution tank 10 gradually decreases. If the thickness of the wall of the dissolution tank 10 becomes smaller than the threshold, repairs are performed to prolong life, or operation of the dissolution tank 10 is stopped because its lifespan has ended.

The dissolution tank 10 has a side wall 11 that surrounds molten glass G from the side, and a bottom wall 12 that supports molten glass G from below. The side wall 11 and the bottom wall 12 are collectively referred to as simply a wall. The wall of the dissolution tank 10 is composed of a plurality of cavities. The plurality of cavities are arranged with gaps between them so as not to contact each other due to thermal expansion. The gap is large enough to prevent molten glass G from leaking, for example, from 0.1 mm to 5 mm. The gap between adjacent grooves can be used as a through hole 13 for measuring the residual thickness. Since there are multiple gaps between adjacent cavities, the residual thickness can be measured at multiple locations.

The residual thickness measuring device 100 is used to measure the residual thickness of the side wall 11, for example. Additionally, the residual thickness measuring device 100 may be used to measure the residual thickness of the bottom wall 12. The residual thickness measuring device 100 includes a scale 110. As shown in FIG. 1(A), the scale 110 is inserted into the through hole 13 of the side wall 11 and comes into contact with the molten glass G. Since the molten glass G loses heat to the wall of the dissolution tank 10, it becomes hard to some extent near the wall and prevents the invasion of scale 110.

The scale 110 is, for example, plate-shaped. The thickness of the plate-shaped scale 110 is large enough to allow the scale 110 to be inserted into the gap between adjacent grooves, for example, 0.1 mm to 3 mm. Additionally, the scale 110 may be bar-shaped. The diameter of the rod-shaped scale 110 is, for example, 0.1 mm to 3 mm.

The scale 110 has a tip surface 111 in contact with the molten glass G, a proximal end surface 112 in a direction opposite to the tip surface 111, and an outer peripheral surface 113. Additionally, the scale 110 has a graduation 114 indicating the distance from the tip surface 111. The scale 114 may represent the distance from the proximal end surface 112. In any case, as will be described in detail later, the residual thickness of the side wall 11 can be measured using the scale 114 as shown in FIGS. 1A to 1C.

When the scale 110 is inserted into the through hole 13 of the side wall 11 or pulled out from the through hole 13, the scale 110 rubs against the grooves constituting the side wall 11. If the scale 110 is made of metal, the scale 110 is difficult to bend, making work easy. Therefore, in this embodiment, a metal scale 110 is used.

Molten glass G is electrically heated inside the dissolution tank 10 by a plurality of electrodes (not shown). By applying a voltage to the molten glass G and passing a current through the molten glass G, Joule heat is generated. The electrode is, for example, rod-shaped. A rod-shaped electrode is inserted into the molten glass G from the bottom wall 12 of the dissolution tank 10. Additionally, the rod-shaped electrode may be inserted into the molten glass G from above or from the side.

When the tip surface 111 of the scale 110 is in contact with the molten glass G and a plurality of electrodes heat the molten glass G with electricity, electricity flows through the molten glass G to the metal scale 110. Additionally, as a heater for heating the molten glass G, a plurality of electrodes and a gas burner may be used together. In this case as well, electricity flows through the molten glass G to the metal scale 110.

Therefore, the residual thickness measuring device 100 is provided with an insulating cover 120 that covers at least a portion of the outer peripheral surface 113 of the scale 110 on the outside of the side wall 11. The operator holds and supports the scale 110 through the cover 120. Therefore, electric shock to the worker can be suppressed, and the residual thickness of the side wall 11 can be measured without stopping the electric heating of the molten glass G. When measuring the residual thickness, temperature fluctuations of the molten glass G can be suppressed, and fluctuations in the quality of the product glass can be suppressed. The insulation resistance of the cover 120 is preferably 0.4 MΩ or more, more preferably 100 MΩ or more, and even more preferably 1 GΩ or more. The larger the insulation resistance of the cover 120, the more desirable it is. Although it is not particularly limited, it is preferably 100 TΩ or less from the viewpoint of feasibility.

The cover 120 may be provided on the outside of the side wall 11 and, unlike the scale 110, does not need to be inserted into the through hole 13 of the side wall 11. This is because the worker performs work outside the side wall 11. In addition, by not inserting the cover 120 into the through hole 13 of the side wall 11, it is possible to prevent the cover 120 from bending inside the through hole 13, thereby eliminating fragments of the cover 120. This can prevent it from being left in the through hole (13).

The cover 120 has a covering portion 121 that covers at least a portion of the outer peripheral surface 113 of the scale 110. In a cross section perpendicular to the long side direction of the scale 110 (left and right directions in FIG. 1), it is preferable that the entire outer peripheral surface 113 of the scale 110 is covered with the coating portion 121. The cover 120 can slide in the long side direction of the scale 110 in this embodiment, but may not be slideable.

When the scale 110 is plate-shaped, the covering portion 121 includes, for example, a pair of insulating plates 121a and 121b. A pair of insulating plates 121a and 121b are arranged with a plate-shaped scale 110 sandwiched between them. The pair of insulating plates 121a and 121b is obtained, for example, by processing a soft shell. The width of the pair of insulating plates 121a and 121b is preferably larger than the width of the scale 110. Contact between the scale 110 and the worker can be limited.

The covering portion 121 may include an insulating tape (not shown) in addition to the pair of insulating plates 121a and 121b. The insulating tape is wound around a pair of insulating plates 121a and 121b. As a result, the entire outer peripheral surface 113 of the scale 110 can be covered with the coating portion 121 in a cross section perpendicular to the long side direction of the scale 110.

Additionally, when the scale 110 is rod-shaped, the covering portion 121 includes, for example, a hollow insulating cylinder. The hollow insulating cylinder is obtained, for example, by processing a soft shell. A scale 110 is inserted into the hollow insulating cylinder. As a result, the entire outer peripheral surface 113 of the scale 110 can be covered with the coating portion 121 in a cross section perpendicular to the long side direction of the scale 110.

The residual thickness measuring device 100 includes a limiting member 130 between the scale 110 and the cover 120 to limit the movement of heat from the scale 110 to the cover 120. The limiting member 130 has a lower thermal conductivity than both the scale 110 and the cover 120, for example. As a result, the temperature rise of the cover 120 can be suppressed. Additionally, if the thermal conductivity of the cover 120 is sufficiently low, the limiting member 130 may be omitted.

In a cross section perpendicular to the long side direction of the scale 110, it is preferable that the entire outer peripheral surface 113 of the scale 110 is covered with the limiting member 130. The limiting member 130 is integrated with the cover 120 and can slide along the long side of the scale 110 together with the cover 120. Additionally, the limiting member 130 may be non-slidable.

The limiting member 130 is obtained, for example, by processing a pericarp. The grooves constituting the limiting member 130 have lower thermal conductivity than the ribs constituting the cover 120. On the other hand, the grooves constituting the cover 120 preferably have a higher electrical resistivity than the ribs constituting the limiting member 130.

The limiting member 130 may be a spacer that forms an air layer (not shown) between the scale 110 and the cover 120. The thermal conductivity of the air layer is lower than that of the air layer. Therefore, by forming an air layer, the movement of heat from the scale 110 to the cover 120 can be further restricted.

Next, referring again to FIG. 1, an example of a method for measuring residual thickness will be described. The operator inserts the scale 110 into the through hole 13 of the side wall 11, for example, as shown in FIG. 1 (A), and inserts the tip surface 111 of the scale 110 into the molten glass G. The position of the outer surface 15 of the side wall 11 is read using the graduations 114 of the scale 110. The residual thickness T of the side wall 11 is equal to the distance L1 from the tip surface 111 of the scale 110 to the outer surface 15 of the side wall 11.

As shown in FIG. 1(B), the operator slides the cover 120 with respect to the scale 110 with the tip surface 111 of the scale 110 in contact with the molten glass G, thereby opening the cover. (120) may be brought into contact with the side wall (11). In this case, the operator reads the distance L2 from the proximal end surface 112 of the scale 110 to the end surface 129 on the opposite side to the side wall 11 of the cover 120, thereby determining the remaining side wall 11. Measure the thickness T. The length of the scale 110 and the length of the cover 120 are measured in advance and are referred to when measuring the residual thickness T.

The worker prohibits the slide of the cover 120 with respect to the scale 110 in the state of FIG. 1(B), and then allows the scale 110 to penetrate the side wall 11 as shown in FIG. 1(C). It may be taken out from the hole 13. In this case, the operator reads the distance L1 from the front end surface 111 of the scale 110 to the end surface 128 opposite the side wall 11 of the cover 120, thereby determining the residual thickness of the side wall 11. Measure T.

In addition, as shown in FIG. 1 (C), the operator extracts the scale 110 from the through hole 13 of the side wall 11 and then removes the cover 120 from the proximal end surface 112 of the scale 110. ), the residual thickness T of the side wall 11 may be measured by reading the distance L2 to the end surface 129 on the opposite side to the side wall 11. The length of the scale 110 and the length of the cover 120 are measured in advance and are referred to when measuring the residual thickness T.

Next, with reference to FIG. 2, a residual thickness measuring device 100 according to a modified example will be described. Hereinafter, the differences will mainly be explained. The residual thickness measuring device 100 includes a metal scale 110, an insulating cover 120, and a limiting member 130. The cover 120 has a covering portion 121 that covers at least a portion of the outer peripheral surface 113 of the scale 110, and an opposing portion 122 that faces the proximal end surface 112 of the scale 110.

The covering portion 121 and the opposing portion 122 are integrated. Thereby, electric shock to workers can be further suppressed. Additionally, when the covering portion 121 and the opposing portion 122 are integrated, the cover 120 may not be able to slide in the long side direction of the scale 110. The cover 120 may have a cover portion 123 facing the side wall 11. The cover portion 123, the covering portion 121, and the opposing portion 122 may be integrated.

The residual thickness measuring device 100 is provided with a cursor 140 that contacts the side wall 11 from the outside and slides relative to the scale 110. The cursor 140 can slide in the direction of the long side of the scale 110 and indicates the current position of the cursor 140 with respect to the scale 110. In a state where the tip surface 111 of the scale 110 is in contact with the molten glass G and the cursor 140 is in contact with the outer surface 15 of the side wall 11, the cursor 140 determines the remaining thickness of the side wall 11. T is indicated on the scale 114. By providing the cursor 140, it is easy to read the residual thickness T.

Next, referring again to FIG. 2, an example of a method for measuring residual thickness will be described. The operator inserts the scale 110 into the through hole 13 of the side wall 11, for example, as shown in Figures 2 (A) to 2 (B), and inserts the scale 110 into the front end surface of the scale 110. (111) is brought into contact with the molten glass G. Before the tip surface 111 of the scale 110 abuts the molten glass G, the cursor 140 abuts the outer surface 15 of the side wall 11, and the cursor 140 is relatively in contact with the scale 110. Slide.

As shown in FIG. 2(B), the operator reads the distance L1 from the tip surface 111 of the scale 110 to the outer surface 15 of the side wall 11, thereby determining the residual thickness T of the side wall 11. Measure. The cursor 140 is preferably transparent. However, even if the cursor 140 is opaque, it is sufficient for the cursor 140 to have a shape that allows the operator to read the scale 114. For example, the cursor 140 is a window for reading the scale 114. You may have it.

After prohibiting the slide of the cursor 140 with respect to the scale 110 in the state of FIG. 2(B), the operator moves the scale 110 through the side wall 11 as shown in FIG. 2(C). It may be taken out from the hole 13. In this case, after the operator extracts the scale 110 from the through hole 13 of the side wall 11, as shown in FIG. 2(C), from the front end surface 111 of the scale 110, the cursor ( By reading the distance L1 to 140), the residual thickness T of the side wall 11 is measured.

As mentioned above, the residual thickness measuring device, the residual thickness measuring method, and the glass manufacturing method according to the present disclosure have been described, but the present disclosure is not limited to the above embodiments or the like. Various changes, modifications, substitutions, additions, deletions, and combinations are possible within the scope described in the patent claims. Those also naturally fall within the technical scope of the present disclosure.

10: Dissolution tank
11: side wall
12: low wall
13: Through hole
100: Residual thickness measuring device
110: scale
113: outer peripheral surface
120: cover

Claims (7)

It is a residual thickness measuring device that measures the residual thickness of the wall of the dissolution tank that stores molten glass that is heated electrically,
A metal scale inserted into a through hole in the wall,
An insulating cover covering at least a portion of the outer peripheral surface of the scale on the outside of the wall.
A residual thickness measuring device comprising: The device for measuring residual thickness according to claim 1, wherein the scale is plate-shaped or rod-shaped. The residual thickness measuring device according to claim 1 or 2, further comprising a limiting member between the scale and the cover that limits the movement of heat from the scale to the cover. The residual thickness measuring device according to claim 1 or 2, comprising a cursor that abuts against the wall from the outside and slides relative to the scale. The scale according to claim 1 or 2, wherein the scale has a front end surface in contact with the molten glass, a proximal end surface in a direction opposite to the front end surface, and the outer peripheral surface,
The cover has a covering portion that covers at least a portion of the outer peripheral surface of the scale, and an opposing portion that faces the proximal end surface of the scale,
A residual thickness measuring device wherein the covering portion and the opposing portion are integrated. A method for measuring residual thickness, comprising measuring the residual thickness using the residual thickness measuring device according to claim 1 or 2. A glass manufacturing method comprising measuring the residual thickness using the residual thickness measuring device according to claim 1 or 2,
A glass manufacturing method comprising heating the molten glass with electricity.