KR20010038839A - Orifice unit for glass furnace - Google Patents

Abstract

PURPOSE: An orifice unit for a glass melting furnace is provided which keeps the temperature of the lower end of an orifice ring constant and controls badness of the glass caused by the temperature difference between the orifice ring and the molten glass materials. CONSTITUTION: The orifice unit for a glass melting furnace(35) comprises: (i) an orifice holder(37) which is connected to the lower part of a feeder(10) that guides molten glass materials(21); (ii) an orifice ring(40) which is supported by the orifice holder and supplies the molten glass materials received from the feeder to a molding device that molds the molten glass materials into an adequate form; and (iii) an insulating layer which is installed on an open area of the lower end of the orifice ring along the outer circumference of the orifice ring.

Description

Orifice unit for glass melting furnace {ORIFICE UNIT FOR GLASS FURNACE}

The present invention relates to an orifice unit for a glass melting furnace, and more particularly, an orifice holder coupled to a lower portion of a feeder for guiding molten glass water, and supported by the orifice holder and receiving molten glass material from the feeder. The present invention relates to an orifice unit for a glass melting furnace having an orifice ring for supplying a molten glass material to a lower forming apparatus for molding a molten glass material into a suitable shape.

The glass melting furnace heat-melts the glass raw material to provide a compression molding apparatus for compression molding a glass product in the form of a molten glass gob. Glass melting furnace is supplied with glass raw material to melt and melt, and refiner which removes bubbles in molten glass to make high quality glass, and is formed to communicate with refiner to form molten glass. It has a feeder (Feeder) provided to the compression molding apparatus in a form suitable for the. At the end of the feeder, a glass feed part is formed to discharge molten glass to the outside.

The feeder for guiding the molten glass water is, as shown in Figure 1, the glass flow portion 20 through which the molten glass water 21 flows and the molten glass material to provide a feeder (not shown) It has a glass supply portion 30 formed in the distal region of 10).

The glass supply unit 30 has a bowl 31 and an orifice unit 35 in which a glass outflow path 32 is formed to guide the outflow of molten glass, and the molten glass in the glass outflow path 32 of the bowl 31. The needle (not shown) is installed to rotate, lift and lower so that the stirring and discharging can be performed, and the orifice unit 35 is a compression molding apparatus (not shown) in the form of a gove 33 of a fixed size. Orifice ring 40 is coupled to the lower portion of the bowl 31 and the orifice holder 37 to support the orifice ring 40 to be provided.

The orifice ring 40 is truncated cone shape, the upper portion 41 is placed on the upper surface of the orifice holder 37 between the bowl 31 and the orifice holder 37 and the side 43 is in the orifice holder 37. It is received and supported along the circumferential surface of the side, and receives the molten glass material 21 from the bowl 31 to supply to the lower compression molding apparatus (not shown).

4 is a perspective view of a conventional orifice unit. As shown therein, the orifice ring 40 is held in close contact along the circumferential surface of the inner side of the orifice holder 37, but the orifice ring 40 and the orifice holder 37 are supported. The gap between the gaps is formed between the gaps 48 and the outside air is introduced into the gaps 48 so as to contact the orifice ring 40.

However, in the orifice ring of the conventional orifice unit for glass melting furnace, relatively low temperature external air flows into and comes into contact with the external air in the gap between the orifice ring and the orifice holder in the lower region of the orifice ring. Due to the cooling of the outer side of the lower end of the orifice ring, the inner portion of the lower end of the orifice ring is cooled by the heat conduction from the cooled outer portion to come into contact with the relatively high temperature molten glass, so that the devitrification in the contact area (JVIINT AREA) There is a problem that is generated to reduce the quality of the glass product.

Accordingly, an object of the present invention is to provide a heat insulation layer along the outer circumference of the orifice ring in the lower opening region of the orifice ring to maintain a constant temperature at the bottom of the orifice ring, thereby suppressing glass defects caused by the temperature difference between the orifice ring and the molten glass material It is to provide an orifice unit for a glass melting furnace that can be planned.

1 is a cross-sectional view of the glass discharge region of the glass melting furnace is installed orifice unit according to the present invention,

2 is an enlarged partial view of FIG.

3 is a perspective view of an orifice ring according to the present invention;

4 is a perspective view of a conventional orifice unit.

* Explanation of symbols for the main parts of the drawings

10: feeder 21: molten glass

35: orifice unit 37: orifice holder

40: orifice ring 47: air layer

49: bend

The object is, according to the present invention, the orifice holder coupled to the lower portion of the feeder for guiding the molten glass material, and supported by the orifice holder and receiving the molten glass material from the feeder to form the molten glass in a suitable form An orifice unit for a glass melting furnace having an orifice ring for supplying to a lower molding apparatus, wherein an insulating layer is provided in a lower opening area of the orifice ring along an outer circumference of the orifice ring. Is achieved.

Here, it is preferable that the said heat insulation layer is an air layer, and it is effective also if it comprises the heat insulation material layer which affixed the insulation material.

In addition, the lower end of the orifice ring is preferably bent upwardly outward along the outer periphery of the orifice ring to accommodate the heat insulating layer.

Hereinafter, with reference to the accompanying drawings will be described in detail with respect to the present invention.

1 is a cross-sectional view of the glass discharge area of the glass melting furnace is installed orifice unit according to the present invention. As shown in this, the feeder 10 for guiding the molten glass material 21, the glass flow portion 20 through which the glass flows and the molten glass to provide a compression molding apparatus (not shown) It has a glass supply part 30 formed in the distal area of the feeder 10. On the other hand, the lower portion of the glass supply unit 30 is provided with a blade 11 for cutting the molten glass material 21 in the form of a gob 33 of a constant size.

The glass supply unit 30 has a bowl 31 and an orifice unit 35 in which a glass outflow path 32 is formed to guide the outflow of the molten glass 21, and the orifice unit 35 has an orifice ring 40. And an orifice holder 37 detachably coupled to the lower portion of the bowl 31 to support the orifice ring 40, and the molten glass material 21 is formed in the glass outflow path 32 of the bowl 31. A needle (not shown) is installed to rotate, lift and lower so as to be stirred and discharged. FIG. 2 is a partially enlarged view of FIG. 1, which shows an enlarged lower area of the orifice ring. Referring to FIGS. 1 and 2, the orifice ring 40 closely adheres along the circumferential surface of the orifice holder 37. The lower end is bent upwardly outward along the outer circumference of the orifice ring 40 to be in close contact with the orifice holder 37 to receive the molten glass material 21 from the bowl 31 to provide a constant size gob 33. It is supplied to the lower compression molding apparatus (not shown) in the form.

Figure 3 is a perspective view of the orifice ring according to the present invention, referring to Figures 1 to 3, as shown therein, the orifice ring 40 is a truncated cone shape, the upper portion 41 is the bowl 31 and The orifice holder 37 is bent so as to be placed on the upper surface between the orifice holder 37 and the side portion 43 has an inclined surface to be received along the circumferential surface of the inner side of the orifice holder 37. In addition, the lower end 45 of the orifice ring 40 is bent upwardly outward along the outer circumference of the orifice ring 40 and extends to the lower side of the side 43 of the orifice ring 40 to form a receiving portion 42. Holes 46 are formed at the sides of the part 49 at predetermined intervals so that the receiving part 42 receives air introduced into the gap between the orifice holder 37 and the orifice ring 40. The air layer 47 accommodated in the accommodating part 42 serves to block heat conduction from the relatively low temperature of the outside air into the orifice ring 40 in contact with the hot glass melt.

By this configuration, the molten glass that flows into the glass outflow path 32 of the bowl 31 is received in the orifice ring 40 is formed in the form of a gob 33 of a constant size by gravity, a suitable gob 33 When the shape is completed, it is cut by the blade 11 installed in the lower portion of the glass supply unit 30 is dropped to the compression molding apparatus (not shown). At this time, in the area between the orifice ring 40 and the orifice holder 37 in the region of the lower end portion 45 of the orifice ring 40 is brought into contact with the external air of a relatively low temperature, but the orifice ring 40 Since it is insulated by the air layer 47 formed along the outer periphery, the orifice ring 40 is in contact with the hot molten glass 21 to maintain a constant temperature.

Thereby, by making it possible to reduce the temperature difference between the orifice ring 40 and the molten glass material 21, the devitrification defect of the molten glass resulting from a temperature difference can be suppressed easily.

In the above-described and illustrated embodiment, the lower end of the orifice ring 40 is bent upward along the outer periphery of the orifice ring 40 to form an insulating layer by allowing the air layer 47 to be accommodated. The lower end of the 40 may be upwardly bent outward along the outer circumference of the orifice ring 40, and an insulating layer may be formed by inserting and fixing an insulating material in the bent portion 49.

As described above, according to the present invention, by providing a heat insulating layer along the outer periphery of the orifice ring in the lower opening region of the orifice ring to maintain a constant temperature at the bottom of the orifice ring, the glass caused by the temperature difference between the orifice ring and the molten glass An orifice unit for a glass melting furnace that can suppress defects is provided.

When the heat insulation layer is an air layer, the production becomes simple, and when the heat insulation layer is provided with an insulation material attached to the lower end of the orifice ring, the effect of insulation is improved. In addition, when the lower end of the orifice ring is bent upward along the outer periphery of the orifice ring to accommodate the heat insulating layer, the formation of the heat insulating layer is simplified.

Claims (4)

An orifice holder coupled to the lower part of the feeder for guiding the molten glass material, and an orifice supported by the orifice holder and receiving the molten glass material from the feeder and supplying the molten glass material to a lower forming apparatus for forming a suitable shape. In the orifice unit for glass melting furnace having a ring, An orifice unit for a melting furnace, characterized in that the heat insulating layer is provided along the outer circumference of the orifice ring in the lower opening region of the orifice ring. The method of claim 1, Orifice unit for a glass melting furnace, characterized in that the heat insulating layer is an air layer. The method of claim 1, The heat insulation layer is a glass melting furnace orifice unit, characterized in that the heat insulating material layer. The method according to any one of claims 2 to 3, The lower end of the orifice ring is bent upwardly outward along the outer periphery of the orifice ring to accommodate the heat insulating layer.