KR800000199B1 - Manufacturing device for glass - Google Patents

Abstract

A method of making glasses by melting raw materials to form molten glass, refining the molten glass by gradually cooling it while flowing it longitudinally through a refiner along an established path, discharging the refined molten glass was described. A glass melting tank consisted of forward flow control equipment to prevent the glass flow from returning and lower part of the floor was bulged to do it.

Description

Glass manufacturing equipment

1 is a plan view of a glass melting tank according to the present invention

2 is a cross-sectional view taken along X-ray of FIG.

3 is a plan view showing another example of the glass melting tank according to the present invention

4 is a cross-sectional view taken along the X-X line of FIG.

5 is a plan view of a deformation of a part of the glass melting tank shown in FIG.

6 is a cross-sectional view taken along line 6-6 of FIG.

7 is a view showing the rotation direction of the stirrer bank in the glass melting tank of FIG.

8 and 9 show two examples of agitators used in the tanks of FIGS. 1 and 3

10 shows a variant of the plant used for the tank of FIG. 1 or FIG.

11 and 12 show two examples of a double discharge channel used in the tank of FIG. 1 or FIG.

13 is a view showing the temperature conditions of the tank according to the present invention

14 shows the temperature condition of a conventional tank.

15 is an enlarged view showing the change of composition in the center of a conventional glass sheet.

FIG. 16 is a view similar to FIG. 15 for a central section of glass formed by a flotation method after being refined and treated in accordance with the present invention.

The present invention relates to glass making, in particular glass melting tanks.

In the conventional method for producing glass in a continuous process, a raw material is supplied to one end of a glass melting tank to form and float a blanket on an existing molten bath. In this case, the raw material is supplied at a speed necessary to keep the depth of the glass in the tank constant, while the molten glass is continuously flowed to the working end opposite to the supply end, where the molten glass is taken out and used in the molding process.

The raw blank kit is converted into molten glass by the heat from the combustion of the fuel supplied to the burner or the heat from the heater, passing through the melting zone at one end of the tank and spaced above the glass level on the sidewalls. The molten glass passes through the melting zone to the refinery zone and receives heat. In this refining zone, gas bubbles still remaining in the glass are discharged or dissolved in the glass. The glass is transferred from the refining zone to the treatment zone adjacent to the working end of the tank, homogenized and in a suitable thermal state for use in the molding process. Typically, the passage is made from the working end of the tank to the molding process.

As can be known from the above, the glass melting tank is formed of a melting zone, a refining zone and a treatment zone. When the molten glass is transferred from one zone to another, it does not necessarily have to be in its final state for its operation, for example when it enters the treatment zone. It may be further refined in the processing band, and may be processed to some extent in the conventional band. Thus, the band means the part where most or all of a specific operation in the tank is performed and the person skilled in the art sets the temperature conditions necessary for the band.

The heat required to melt and refine the glass is typically obtained by burning liquid or gaseous fuel on the glass surface, by electrothermally heating the glass body, or by combining the two methods. Cooling of the glass in the treatment zone is typically accomplished by blowing air across the free surface of the glass. The temperature gradient that rises along the furnace's melting zone is adjusted by adjusting the energy supply along the length of the furnace, at its maximum at the so-called hot spot, and at the downstream of that point. This temperature gradient causes convection, whereby the convection returns the fine glass present in the upper layer of the melt zone under a batch blanket to the feed end, otherwise it is not melted once. It increases the supply of heat to the main body of the glass of the molten zone which will be prevented from being heated sufficiently by the movement of heat by the insulating layer formed.

The convection caused downstream of the hot spot by the gradient of temperature also moves the glass in the refinery upper layer forward toward the treatment zone and the colder glass in the refinery lower layer returns towards the hot spot. These convection homogenizes the glass and the colder lower layer of glass prevents the temperature of the refractory at the bottom of the furnace from rising high enough for rapid chemical erosion and corrosion.

Melting, refining and processing all depend on time and temperature, with maximum temperatures to the extent that furnace refractory can tolerate and the time the glass spends in any particular zone depends on the furnace geometry. Therefore, the maximum yield for any particular shape of furnace means a limit to the deterioration of glass quality if exceeded.

Even when the tank is operated within its designed range, it is sometimes difficult to obtain a completely homogeneous glass containing no undissolved solids and gases and having a uniform composition. This problem is exacerbated as the output of the tank increases. Glass of different composition forms a layer in the tank, which is subjected to convection and other flows given by furnace operations and other physical operations performed on the furnace glass. Generally in the final product the layers are taut to the glass surface but deflected from this parallel state in the part where the flow changes, for example in the center of the glass ribbon. Optical defects occur where the layers are not parallel to the glass surface.

Various methods can be used to ameliorate these optical defects, for example, to insulate furnace structures to improve thermal efficiency, to reduce corrosion and oxidation using improved refractory materials, and to change glass compositions. There is a method of reducing heat required for melting and refining glass, or a method of improving thermal efficiency by changing a method of supplying heat to glass. In general, however, further production of furnaces cannot be achieved without increasing costs, shortening furnace life or altering the glass properties.

The glass melting tank of the present invention containing molten glass includes a feed end receiving the glass forming material, a glass forming material melting band adjacent to the supply end, a molten glass refinement band downstream of the melting band, and a glass near the outlet end of the tank. It has a long fuselage with a treatment band to process the glass before going to the forming process. The part adjacent to the supply end of the fuselage is relatively wide and the remaining part leading to the outlet end forms a narrow glass flow path compared to the above-mentioned wide part. The upstream band adjacent to the wide part and the downstream band leading to the outlet. In the upstream band, the return flow occurs toward the wide part, and the downstream band is raised at the bottom to form a shallow channel so that the molten glass can flow to the outlet without actually returning flow. And also from that wide part to the rest And a flow regulating device for regulating the forward flow of molten glass.

The production rate of the melt tank can be varied within the legislation of the particular design, but to obtain the best quality glass, the glass level in the tank must be kept the same regardless of the yield. The output can be increased by increasing the amount of heat supplied to the tank or by increasing the area of the tank used to melt, but the latter takes up the area used for refining in certain tanks. These changes result in changes in quality, capacity and depth of forward and circulating flow in the tank. The effect of increasing production is to increase the amount of heat transferred forward to the front flow glass. This means that as production increases, the front flow glass must be further cooled down to a temperature suitable for the forming process. There is also a limit to the amount of surface cooling that can be applied without causing instability to the upper glass layer by cooling the glass surface to a temperature lower than the temperature of the glass layer below it (thereby limiting the yield). Such a temperature shift creates a flow in the glass that degrades the quality of the finished glass when visually identified. Conventionally, in order to overcome this phenomenon, while avoiding excessive surface cooling, in order to increase the output of the tank, convection is reduced by obstructing the flow path of the return flow, that is, by placing a physical barrier in the flow path of the return flow. It was based on reducing or cooling the return flow of the already slowly moving glass and reducing its convection velocity.

This technology did not, in fact, increase the furnace output by the proposed expectations. However, in the tank of the present invention, a means for controlling the forward flow of the molten glass from the wide fuselage portion of the tank to the narrow remainder of the tank and at the same time reducing the length of the passage through which the return flow takes place, the return glass is a natural convection limit. The heat loss is reduced compared to when flowed up to, allowing more heat to be used at the melting and refining ends of the furnace. Likewise, controlling the forward flow reduces the thermal conductivity conducted from the melt zone and the refinery zone to the tank treatment zone. Therefore, energy can be used more efficiently since heat can be used more in the melting zone and the refining zone as it has conventionally been necessary to raise the temperature of the cooled return flow of the molten glass. In addition, more time is available for heat absorption because the barrier reduces the velocity of the upstream flow glass. Relatively less cooling is required because less heat is conducted from the wider fuselage of the tank to the narrower portion and the glass that moves only forward in the treatment zone passes through. The overall thermal efficiency is thus improved and the treatment band is shorter than for a given tank capacity. Moreover, the tank according to the invention has the advantage that it is possible to use a larger area for melting and refining for a given total tank length, which helps to increase the tank yield for a given total tank size.

In another embodiment of the present invention, the present inventors can increase the output by installing a means for improving the balance of the composition and heat of the glass in the narrow fuselage portion of the tank, using a furnace of the same or smaller than conventional At the same time, it was found that glass quality could be improved. Therefore, not only the facility cost can be reduced, but also the operation cost can be reduced.

The glass entering the treatment zone is further cooled and then brought into a state suitable for supply to a forming process such as a floating process. The use of a narrow processing channel with only forward flow restricts undesirable convective circulation compared to the wide and deep treatment bands of conventional glass tanks, and also allows sufficient control of the convective circulation with conventional means. This has the desirable effect that the treatment can be carried out with little risk of causing losses due to optical defects of the glass which are deflected from parallel flow during the treatment.

The remainder of the tank has a relatively narrow portion, which is either uniform or different along its length but narrower than the wider fuselage.

The tank has one or more relatively narrow glass flow channels leading from the wide body part to the outlet end of the tank.

In particular, as the flow control means, it is preferable to position the barrier in the molten glass so as to control the overall flow of the molten glass toward the remainder of the tank. The barrier may be fluid cooled, such as water cooled, extending horizontally in the center of the glass flow passage, located upstream of, or adjacent to, the narrow remainder of the tank. The barrier is placed above the bottom of the tank, above the bottom of the tank. It is also desirable for the barrier to protrude above the surface of the molten glass or in some cases to allow the top surface of the barrier to lie on the same plane as the surface of the molten glass.

In particular, the barrier is preferably such that its ends are supported adjacent to the outer frame or other support of the tank structure so that the predetermined position, ie height and length position, in the glass can be adjusted. The barrier extends perpendicularly to the flow of molten glass through the narrow channel or is slightly inclined at other angles to the flow direction.

The barrier also acts to cool the forward flow molten glass in the form of a water cooled pipe. In particular, it is advisable to provide a vertical stairway at the base of the tank at the junction between the upstream and downstream of the tank remainder. Gradually changing the depth is undesirable, but in some cases it can be steep.

The length of the tank in which the return of the glass occurs is limited by the position of the staircase with a slight return upstream, but once the molten glass has passed this position, it actually flows forward. Therefore, when the staircase is installed, the return flow passage cannot extend to the natural range of the tank cooling section, and thus the return glass becomes hotter because it is shorter than that of the normal deep treatment zone.

In fact, in the case of a special stage tank or a specially designed tank for the life of the tank, the shortening effect of the flow passage causes the return glass to become hotter than can be tolerated, thus reducing the temperature of the return glass. There is a need. This, depending on the problem

(1) the use of highly conductive refractory to the base of the relatively narrow part of the tank where feedback occurs, or to allow heat loss through this refractory; or

(2) There are two ways to arrange cooling means such as water-cooled pipes in the return flow.

This lowers the overall thermal efficiency but is necessary to prevent degradation of glass quality due to too hot feedback. In order to reduce the forward flow temperature of the molten glass in the upstream portion of the tank residue, it is preferable to provide cooling means. In addition, the same means can be used to equalize the forward flow of the glass upstream of the tank remainder. In particular, it is preferable to form at least one stirrer bank as a means for equalizing the forward flow of the molten glass, and each stirrer bank includes at least one stirrer, and the stirrer can rotate about a vertical axis. Secure in parallel to the deep part of the remainder. The stirrers in one bank are connected to the driving means and are arranged to stir the molten glass so that they are not angularly different from each other in at least one position at each rotation. If more than one stirrer bank is provided, the position where the angle difference is zero is different for each bank. Each stirrer may be equipped with blades or paddles, and in either stirrer bank each stirrer may rotate in the same direction so that the blades or paddles of different stirrers may be parallel to each other in rotation. In this case, each stirrer is kept in the same phase. When each stirrer of the bank rotates in the opposite direction, all blades or paddles of each stirrer are arranged so as to be parallel to each other at a predetermined position at each rotation so that there is no difference in the rotational positions. Alternatively, the stirrer may be formed of a member such as a cylinder shaped stalk which is symmetric about the rotating side. In this case, each stirrer does not show a difference in its rotational position despite the rotation. In the case of driving, each stirrer is designed so that the vertical flowing component does not reach the glass.

In particular, the stirrer is preferably part or all of the fluid cooling, the fluid is convenient to use water. The stirrer is preferably placed in a deep narrow part downstream of the barrier.

Furthermore, the glass may need to be lowered to a temperature at which its quality does not deteriorate on the passage of the next shallow channel, or the glass of forward flow adjacent to a staircase formed by one or more fluid-cooled stirrer banks or in a narrow section of the tank, or Achievement is achieved by fluid cooled immersion immersed in the glass of the forward flow in the shallow channel. At this time, the mound is arranged to reciprocate across the glass flow line. The cooler is designed so that the vertical flow component is virtually invisible to the glass. In some cases, it is preferable that the cooling means is fixed, i.e., that each stirrer is not rotated and the chuck is not reciprocated.

For special tanks, the depth of the forward and return flows depends on the tank production and the tank operating conditions, and adjustment of the barrier depth is necessary when these conditions change, and depending on the change of these conditions Sometimes it is necessary to replace with one.

The barriers are arranged so that the glass flow does not cross its top, controlling the forward flow and altering the downstream return flow, as well as scraping away contaminants from the glass surface, thereby removing contaminants from the sides of the tank or through the barriers. Make sure to remove it periodically when you replace it.

The stirrer is placed at a predetermined position relative to the barrier to achieve an optimal homogenization that determines the tank production and operating conditions, and the immersion depth is made to thin the front flow layer of the molten glass without penetrating the lower layer of the return flow. do. Thinner layers of glass reduce the effect of compositional differences between adjacent layers on the optical properties of the final product, and reducing the thickness of the layer at a moderate temperature allows for faster diffusion of glass between layers, resulting in less compositional differences. do.

The design of the stirrer and the positioning of the stirrer, in particular, minimize the movement of the glass in the vertical direction of the glass from the return flow so that the glass layers are parallel to each other on the free surface of the molten glass, Do not adversely affect thermal homogenization.

The front flow glass may be further cooled prior to passing through the shallow portion of the narrow channel. This can be achieved by rotating the fluid cooled cylinder-like member in the forward flow direction of the glass thereby cooling the glass and improving the uniformity of temperature. In the glass of such a fluid-cooled cylinder type member, the immersion depth is preferably arranged so that the lower end thereof does not substantially adversely affect the return flow. The immersion depth in this case is different from that described for the stirrer described above, and is provided to control the temperature over the depth of the molten glass.

Cooling, on the other hand, can be achieved by allowing the fluid cooled chuck to reciprocate cross the flow of the front flow glass without substantial penetration of the return flow. The shallower portion of the tank's narrow body is designed to cool more as the glass flows along the channel without introducing convection that adversely affects glass quality or causes flow to be diverted. Following this part of the tank, the dropping temperature is at least 50 ° C or at most 200 ° C. To deal with these changes, shallow areas are equipped with adjustable insulators along the bottom and sides, and burners are operated above the glass surface.

In addition, when more cooling is required, a means of feeding cooling air across the glass surface or along the lower side of the channel base may be provided. In any cross section of the glass that resides in the narrow part of the tank, the cooling rate and temperature are respectively formed in the narrow part ceiling to cool the central part of the glass and the burner operating adjacent to each side wall to heat each end of the glass. Controlled by a variable heat dissipation slot. Both burners and heat sinks can be manually controlled to achieve the desired temperature conditions or automatically controlled by a signal sent from a temperature sensor placed on a glass or chamber on a glass surface.

The present invention will be described in detail with reference to the accompanying drawings.

1 and 2 show a glass melting tank used for glass production, which has a structure of an elongated body 10 formed of a refractory material for accommodating molten glass. The tank has a feed end 11 for introducing a batch of glass forming material and an outlet end 12 for sending molten glass along an outlet transfer path 13 to a forming process such as a floater (not shown). The glass melting tank has a relatively wide body portion 14 adjacent to the feed end 11, which body portion 14 is formed of a melting zone 15 and a refining zone 16. The wider body portion 14 terminates in the wall 17 and the remainder 18 of the tank connected to the outlet end 12 provides a relatively narrow glass flow passage leading to the outlet end. Although the narrow part 18 differs in the width | variety of a cross section, each cross section becomes narrow compared with the wide fuselage | body part 14. As shown in FIG. The narrow portion 18 provides a treatment zone 19 for treating the glass before the glass leaves the tank. The wide fuselage portion 14 is generally rectangular in shape and has steep slopes to reduce the tank fuselage width at the junction of the wide portion 14 and the remainder 18. The remainder 18 has parallel side walls with inclined steps 20 of varying width. The outlet end of the narrow portion 18 has an inclined portion 12 which is guided to the outlet transfer path 13.

As shown in FIGS. 1 and 2, the wide part of the tank body is the opposite end adjacent to the government or crown 22, the side walls 23, 24, the supply end 11 and the narrow part 18. FIG. It has a subwall 17. The supply end 11 is provided with a filling pocket 25 for supplying a quantity of solid glass forming material from the supply device 26. The first glass forming material forms a solid raw material friendly material 27 floating on the surface of the molten glass 28, and is opened in the melting zone and the refinement zone above the level of the molten glass existing on the opposite side of the tank. It is gradually melted in the melting zone 15 by an open hole 29 or a burner provided in proximity thereto. After melting, the glass is transported downstream of the refining zone 16 where the glass is refined. The glass is then conveyed through the treatment zone 19 through the narrow remainder 18 of the tank and via the exit feed path l3 to the forming process.

As indicated in FIG. 2, the tank balance 18 has a low top 30. Moreover, the base of the narrow remnant 18 is formed in steps and forms two different depth levels in conjunction with the tank remnant 18. The upstream or inlet portion 31 has a base at the same level as the base of the wide part 14 of the tank, thereby making the molten glass the same depth. However, the downstream or treatment zone 19 has an elevated base 32 with a steep vertical staircase 33 at the junction of the upstream portion 31 and the downstream portion. This provides a relatively shallow channel through which glass flow is directed to treatment zone 19. The shallow cross-water cooled barrier 34 is disposed in the body of molten glass adjacent to the junction of the narrow remainder 18 and the wider body portion 14. This barrier is formed of two water-cooled pipes extending on opposite sides of the tank, each pipe having a rectangular U shape with two arms in contact with each other. Six further stirrers 35 are arranged downstream and upstream of the barrier 34, and these stirrers are arranged in parallel to extend across the glass flow channel. Each stirrer is connected to a conventional drive 36. It can rotate about a vertical axis by this.

As shown in FIG. 1 and FIG. 2, two water-cooled cylinder coolers 37 are arranged downstream and upstream of the stirrer 35, which coolers 37 are deep in the narrow glass flow channel. It is arranged in parallel to extend across. These coolers 37 are arranged to be rotated at the same time around the vertical axis by a drive motor (not shown). In the case of the device shown in this example, the cylinder-shaped enlarged lower end of each cooler is immersed in the upper portion of the molten glass flowing forward of the relatively shallow treatment zone l9. The coolant is continuously transferred through the cooler as the cooler rotates. Each cooler 37 adjusts the immersion depth and lateral position by a mechanism outside the tank (not shown) so that the temperature according to the depth of the glass and the temperature according to the width of the glass are desired before the glass enters the treatment zone 19. It can be controlled in the range of.

In the tanks shown in FIGS. 1 and 2, the second water-cooled barrier 38 extends across the narrow portion 8 between the cooler 37 and the stairs 33. Generally the barrier 38 extends deeper into the molten glass but is similar to the barrier 34.

The tanks shown in Figs. 3 and 4 show variants which are different from the structure of the tanks shown in Figs. 1 and 2, in which case the same reference numerals denote the same parts. However, in the variant shown in FIGS. 3 and 4 the relatively narrow portion 18 of the tank is uniform in width from the wall 17 of the tank to the outlet end 12. Furthermore, in the variants of FIGS. 3 and 4, the second water-cooled barrier 38 is omitted, and the barrier 34 adjacent to the wall 17 of the tank is deeper in the molten glass, as shown in FIG. Serialized until. Barrier 34 is formed of a water-cooled pipe, which is a rectangular U-shape having two arms in contact with each other, as shown in FIG. 6, and extends on opposite sides of the tank. The two pipes are indicated by numerals 34a and 34b, and the horizontal arms of each pipe are denoted by numerals 39 and 40. Arm 39 is connected to outlet pipe 42 while arm 40 is connected to inlet pipe 41. Pipes 41 and 42 are adjustablely fixed to an adjustable supporter 43 disposed outside the opposite side walls of the tank.

As shown in FIG. 6, the pipes 34a and 34b are disposed at a position higher than the bottom of the tank so as to be located at the top of the molten glass. As shown in FIG. 3, the two pipes contact in the middle of the tank and are inclined in opposite directions with respect to the rear side of the tank so that the central portion of the barrier is located closer to the inlet end of the tank.

In the tank shown in FIG. 3, two rows of agitators 35a and 36b are provided, and four rows of agitators 35b are arranged in parallel. The stirrers used in the tanks of FIGS. 1 and 3 are the same in each case, each stirrer has a blade or paddle at its lower end, and the paddle is located on top of the molten glass. The blades of each stirrer 35a shown in FIG. 7 are arranged in parallel with each other, and the drive motors are installed such that the stirrers are all rotated in the same direction so that they are kept in the same phase at the same speed. The stirrers are all water-cooled and variations of the other structures are as shown in FIGS. 8 and 9.

The stirrer shown in FIG. 8 is formed of a hollow loop formed by a tube 44 connecting the outlet 45 and the inlet 46. 9 shows a modification of the casting in which the hollow part sealed by the hollow loop is filled with the center plate 47. The stirrer is cooled by passing water through the hollow tube.

The tanks shown in FIGS. 3 and 4 are as described above with respect to FIGS. 1 and 2, and the operation of the tank is described in detail by the tanks shown in FIG. 3.

The batch of glass forming material is melted by the heat applied adjacent to the melting zone 15, at which time the temperature moving downstream from the feed end 11 is raised. The rising temperature reaches the hot point of the maximum temperature in the molten glass downstream of the melting zone. In the refining zone the temperature is controlled to fall downstream from the hot spot. These temperatures cause the forward and return flows of the molten glass, a description of which is shown in FIG. In the refining zone 16, there is a front flow of hot glass existing at the top of the glass and a return flow flowing in front of the inlet end near the bottom of the tank. This return is lower in temperature than the top glass in the refinery and tends to protect the refractory at the bottom of the tank. Moreover, the return of hot glass from the hot spot in front of the melting zone bears the supply of heat used to melt the batch of glass forming material introduced. The depth of treatment zone 19 is relatively shallow and the tank is operated so that glass flow through the treatment zone occurs along exit 12. Manipulating in this way there is no feedback flow through the treatment band and back to the refining band 16. The flow passage formed in the upstream portion 31 at the inlet of the shallow channel is as shown in FIG. Similarly, the flow passage is also shown in FIG. The water-cooled barrier 34 is arranged at a height capable of controlling the glass-level forward flow to the narrow channel 18. This barrier does not extend low enough to inhibit the return flow of the tank bottom flowing back from the upstream portion 31 to the refining zone 16. Similarly, the stirrers 35a and 35b are arranged to act only on the forward flow of the glass passing through the treatment zone 19.

Note that the barrier 34 (and barrier 38 shown in FIG. 1) acts as a physical barrier that regulates the forward flow of molten glass exiting the refining zone l6. The forward velocity of the molten glass upper layer is reduced so that the glass can use more heat at the refined portion of the tank so that refining is satisfactorily achieved. Moreover, the barrier causes a second return flow in the refinery zone, causing the molten glass to be returned along the return flow path from the barrier portion rather than the cooling portion downstream of the barrier. If this return flow occurs early in the tank, the return glass becomes hotter and requires less heat from the burner to achieve satisfactory melting and refining. Moreover, barrier 34 prevents some of the heat from passing into the treatment zone by the forward flow of glass. Thus, when cooling of molten glass is performed to bring the glass into a thermal state suitable for the next forming process, the amount of cooling required in this processing zone is reduced and shorter processing zones are available. This can be seen by comparing Figs. 13 and 14 in which the tank of the present invention and a known tank are arranged in parallel. FIG. 14 shows a known tank having a main body portion 10 extending from a feed end 11 providing a melting zone 15 and a refining zone 16, in which case a heated hole 29 The tank is guided through a recess 48 to a treatment zone l9 that is the same width as the main body portion 10 of the tank. Then, the outlet transfer path 13 is installed and the depth of the glass is constant in the melting zone, the refining zone and the treatment zone.

FIG. 13 shows the tank of the present invention, which has the same overall length as the tank shown in FIG. 14, but has a remainder 18 in which the main body portion 10 is connected to an outlet transport path 13 narrower than this. In the remainder, there is a staircase 33 at the base of the tank. It should be noted that in this case the special temperature conditions in the glass melt tank can be changed depending on several factors, such as the type of glass produced. However, for the purpose of comparing the results achieved in known types of glass melting tanks with the tanks of the present invention, for example, for the purpose of comparison, the molten glass is a soda-lime-silica composition of the kind used to produce flat glass. Same as

In the case of the known tank shown in FIG. 14, the glass at the inlet is heated to a position of 1,500 ± 10 ° C. at position (A), and the ionicity is raised to 1,590 ± 5 ° C. at the hot point B of the tank. After refining in the refining zone the glass enters the recess 48 and the temperature is in the range of 1,375 ± 10 ° C at position C at the inlet of the recess. After exiting the recess and entering the treatment zone 19, the temperature is in the range of 1280 ± 10 ° C at position (D). As the glass passes through the treatment zone it is cooled and enters the exit path 13 at a temperature in the range E, 090 ± 10 ° C.

In contrast, in the case of using the tank of the present invention shown in FIG. 13, the glass at the feed end is heated to a temperature of 1,500 ± 10 ° C. at position A and the temperature of l, 590 ± 5 ° C. at hot spot B. To rise. In this case, however, the refining zone extends further downstream, as can be seen from the downstream position of the wall 17 which forms the end of the wide fuselage part of the tank 10. The temperature of the glass leaving the wide fuselage reaches 1,365 ± 10 ° C at position (C). The temperature of the glass as it passes the stairs 33 reaches 1,200 ± 25 ° C. at position D and the temperature of the glass is further cooled to 1,090 ± 10 ° C. at position E as it passes through the treatment zone. Therefore, in accordance with the present invention we can see that the glass is cooled more quickly between l, 365 ^o, and a temperature of 1,200 ℃ than that of the prior art. This is achieved by cooling means arranged in the core of the narrow channel. In addition, according to the present invention, the distance between the wall 17 and the outlet transport path 13 can be significantly shortened, thereby reducing the length of the treatment zone. If the total length of the tank is fixed, the melting zone and the refining zone can be increased, and as can be seen from FIG. 13, this can be done by heating holes to melt and refining more material in tanks of the same length. To do more. Moreover, in the case of the tank shown in FIG. 13, the return flow of glass flowing to the refining zone 16 takes place in the stairs 33 at 1,200 ° C. Although the temperature in the staircase 33 is set as 1,200 degreeC in the case of this invention, it is possible to control temperature extensively in a staircase using a cooling means. In the case of the present invention, by using soda-lime-silica glass, it is possible to cool to a temperature in the range of 1,175-1,225 ° C at a refining temperature of about 1,365 ° C. Thus, this shows the flexibility that the cooling means can be used at the core of the narrow channel. Of course, the possible range and temperature drop can be altered to some extent depending on the glass composition of the base. In the case of the known tank shown in Fig. 14, such a large change is impossible, and only a range of about 1,270-1,290 ° C. at the outlet from the main part can be made according to the overall change of the tank conditions. However, in the case of the tank of the present invention, the temperature can be changed more broadly by selecting an appropriate cooling means without any change in the overall tank operating conditions in the stairs. In the known tank shown in FIG. 14, the return flow occurs at the outlet end of the treatment zone 19 where the temperature is lower, so that the return flow to the refining zone 16 takes place in the cooler glass part, further reheating. need.

Therefore, according to the present invention, it can be seen that the total yield that can be obtained from the glass melt tank of a certain size can be increased compared to the total yield of the normal tank shown in FIG. The conventional tank shown in FIG. 14 is designed to produce 2,000 tons per week as the maximum output, although the overall length of the tank is similar to the tank of the present invention shown in FIG. 13, and the tank of the present invention shown in FIG. According to the report, the total production of 2,500 tons per week can be raised. Thus, according to the present invention can not only improve the production (ton / week), but also improve the thermal efficiency (that is, the heat required for a constant production of molten glass). For example, when the tank shown in FIG. 13 is used to obtain the same output (tons / week) as the tank shown in FIG. 14, the heat rate can be improved by about 5-10%. That is, by reducing the number of therms required to produce molten glass per ton. The thermal efficiency achieved by the present invention increases with increasing load capacity of the tank. In the case of producing 2,300 tons per week using the tanks shown in Figure 13, it is estimated that improved thermal efficiency is achieved at around 15-20%.

If the output of the tank shown in FIG. 13 is further increased to 2,500 tons per week, the improved thermal efficiency is estimated to be 20-25% based on the normal tank performance shown in FIG. These figures are based on the maximum possible yield of the tank shown in Figure 14 being 2,000 tonnes per week. Therefore, it cannot be a correct comparison above and below 2,000 tons.

The present invention makes it possible to improve the glass quality as well as to improve the production cost and thermal efficiency. As is known, changes in the glass composition of the melting tank leaving the melting tank cause optical defects in the next glass produced. This phenomenon is discussed, for example, in US Pat. No. 3,894,859. In order to minimize the optical coupling to a minimum, the formation layer of any glass in which the composition differs should be as small as possible, preferably the variation of the composition should be small, and in particular, the pattern of the layers formed parallel to the glass surface should be uniform. However, it is well known that undesirable "centre features" occur in the floating glass, where the composition forms an undesirable pattern in which different layers lead to optical defects. An example of such a prior art is shown in FIG. 15, which is markedly different from the result achieved by the invention shown in FIG. As can be seen from FIG. 16, according to the present invention, the glass layers with different compositions do not form undesirable "central properties" which were conventionally seen in floating glass. Layers with different compositions are substantially parallel to the glass plane, the number of layers with different glass compositions is smaller, and the strength of the lines due to changes in the composition is reduced. It is believed that the change in the basic pattern is due to the change in the flow occurring in the body of the glass due to the new tank structure and the decrease in the number and strength of the different lines of the composition due to the stirring action on the flow in the tank. The stirrer 35a is arranged to help the homogenization of the glass to thin the forward flow layer of the molten glass without causing vertical displacement of the glass. This stirrer also serves to cool the glass partially in the upstream portion 31 before the glass reaches the treatment zone.

The invention is not limited to the details of the examples shown in FIGS. 1, 2, 3 and 4. For example, the junction of the narrow portion 18 and the wide portion 14 of the tank can be modified as indicated in FIG. 5. In this case, the inlet portion 31 of the relatively narrow portion 18 has two agitators 35a and 35b banks, and in each of the two tanks each agitator is arranged to rotate in the opposite direction. Instead of using the cylinder type cooler described in connection with FIG. 1, the use of two reciprocating water coolers 49, 50 allows for further cooling in the portion 31, wherein the two reciprocating water coolers 49, 50 is immersed in the front flow glass and extends horizontally in connection with the transverse line of the narrow portion (18). Moreover, in this variant, the relatively narrow portion 18 has sidewalls 18a parallel to the junction with the wide portion 14. These sidewalls 18a are inclined inward at a staircase 33 leading to the narrower but parallel side channels 18b. The treatment zone 19 is formed of an inclined portion together with the narrow portion 18b. In this case, the parallel narrow portion 18b is very short.

In the tanks shown in FIGS. 2 and 4, the stairway descending from the top 22 of the tank recess terminates at the top 30 level of the narrow downstream portion 18 of the tank, but the two top 22 At the junction of, 30, a downward facing protruding wall 51 as shown in FIG. 10 can be formed. This downwardly protruding wall 51 extends across the entire width of the tank and terminates at substantially the same level as the top of the water-cooled barrier 34. The gap between the protruding wall 51 and the barrier 34 may be minimized to form a gas tight chamber between the refinery zone 16 and the downstream portion of the tank. Moreover, since the wall 51 significantly reduces heat transfer to the cooling zone, the amount of water cooling made at the inlet of the narrow downstream zone of the tank can be reduced. The complete hermetic chamber is formed by suspending a platinum or alloy plate between the lower end of the wall 51 and the molten glass surface.

In the tanks shown in FIGS. 1 and 3, the melting and refining portions 10 of the tank are arranged to provide a single treatment zone, but may provide two or more treatment zones placed in parallel, both variants. Examples are shown in FIGS. 11 and 12. In both of these variants, two narrow tank portions 52 and 53 extend from the fuselage recess 10 to the outlet end of the tank, each of which flows entirely from the tank in the outlet direction. Stairs 33 are provided which form downstream shallow zones and upper deep zones. These channels 52 and 53 have two rows of stirrers or cylinder coolers as described above in connection with FIGS. 1 and 3, respectively. In the tank shown in FIG. 11, the water-cooled barrier is formed by horizontal water-cooled pipes 34, which are wide bodies of the tank 10, just before the inlets of the two narrow channels 52, 53. Cut off the full width of the section. The shape and location of the barrier 34 is similar to that described above in connection with FIG. 1 or FIG.

In the variant shown in FIG. 12, a separate water-cooled barrier 34 is provided for each of the channels 52 and 53 instead of using a large water-cooled pipe 34 extending across the entire width of the wide portion 10 of the tank. In general, they are similar, in which case the barriers are arranged at short distances inside the inlet of the narrow channel.

The barrier 34 is as shown in FIGS. 2, 4 and 6, but the top surface of the barrier has a surface substantially the same as that of the molten glass, and in some cases the top surface of the barrier 34 is placed on the glass surface. By protruding it serves as a device to scrape and remove contaminants on the molten glass surface. In FIG. 6, the upper and lower arms of each pipe 34 are designed to be parallel to each other with respect to the glass surface, but the lower and upper arms can be designed to converge or diverge toward the center of the channel.

In Figures 1 and 3 the barrier 34 extends horizontally across the full width of the narrow channel 18, with two half of the barrier inclined relative to the transverse direction of the tank. However, this barrier may be inclined in a slightly different direction, and in some cases may extend perpendicularly to the flow direction as indicated in FIGS. 11 and 12.

Although the agitators shown in FIGS. 8 and 9 have blades or paddles, a cylinder-type agitator without blades or paddles may be used in some cases. In some cases, it is also preferable to use a cooling device in the treatment zone 19. Occasionally, when the treatment zone 19 has a wider downstream portion of the stairs than just upstream of the stairs, an edge heating element is installed in the shallow portion of the stairs close to the glass surface to provide the edge of the glass flow in the treatment zone. It is desirable to reduce the temperature difference between the centers.

In the tank shown in FIG. 2, the cooler 37 is arranged in the depth direction of the molten glass such that its lowermost end is located directly under the return flow glass at the lower part of the portion 31. However, all coolers should be able to adjust the immersion depth and lateral position by means of an outside mechanism (not shown) to keep the temperature range in the desired range over the depth and width of the glass.

The temperature present at a particular point of the tank operating in accordance with the invention is as described above with reference to FIG. In this particular example, the temperature selected for the molten glass when passing through the stairs is around 1,200 ° C. The question of which temperature to choose among the possible temperatures depends on several requirements, including the tank operating conditions and the first water in the shallow downstream section where the molten glass flows over the stairs.

As noted above when describing soda-lime-silica glass, the temperature of the molten glass as it passes through the stairs can be selected in the range of 1,175-1,225 ° C. This temperature range is somewhat changed as the glass composition changes. In addition to the requirements described above, when selecting the temperature at which the molten glass is cooled before leaving the stairs, avoid the possibility of contamination due to air bubbles or refractory caused by the condition and temperature of the molten glass when the molten glass is in contact with the shallow downstream refractory. Consideration should be given to the need to reduce.

The shallow portion is shown with the refractory base, which in one variant typically separates the glass flowing through all or part of the zone from the refractory base by feeding a molten metal layer of tin or alloy thereof. In reducing the refractory opportunities of refractory in this way, care must be taken not to incorporate metals or their alloys as contaminants, an important requirement being the choice of the temperature at which the molten glass is cooled before entering the thin section.

Claims (1)

As described above in the text and shown in the drawings, the glass tank has a supply end for receiving the glass forming material, a glass forming material melting band adjacent to the supply end, a molten glass refinement band downstream of the melting band, and an outlet end of the tank. In a molten glass tank composed of a long fuselage with a processing zone for processing the glass before going to the forming process, the portion 10 adjacent to the feed end 11 of the fuselage is relatively wide and is connected to the outlet end 12. The remainder 18 forms an upstream portion 31 adjacent to the wide portion 10 and a downstream portion 32 leading to the outlet while forming a narrow glass flow path as compared to the wide portion 10 described above. The return flow takes place and the downstream portion 32 is bottomed up to form a shallow channel so that the molten glass can flow toward the outlet without actually returning flow, while being wide A glass melting tank, characterized in that it comprises a flow control device 34 for regulating the forward flow of molten glass in the above-described rest in part.

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