KR20000044993A - Glass fusion furnace - Google Patents

Abstract

PURPOSE: A glass fusion furnace is provided which heats mutual contact areas between a bowl and an orifice holder by a heater so that it inhibits inferior glasses arising from the temperature difference between an inflow air from the outside and a fusion glass. CONSTITUTION: A glass fusion furnace has the following parts of: a bowl(1) which forms a flow path(3) of a fusion glass in the edge area; an orifice ring(7) which is located in the edge of a flow path of a fusion glass; and an orifice holder(9) which supports the orifice ring that is combined with the bowl and is removable wherein a first heating part(13) is formed to heat a neighboring area of the inner edge of the bowl. The first heating part contains heater receiving parts(14,18) cut in the lower direction from the bowl contact face of the orifice holder and a removable heater inside the heater receiving parts.

Description

Glass Melting Furnace

The present invention relates to a glass melting furnace, and more particularly, a bowl for forming a flow path of molten glass in the end region, an orifice ring disposed at the end of the flow path of the molten glass, and detachable to the bowl It relates to a glass melting furnace having an orifice holder that is coupled so as to support the orifice ring.

Glass melting furnace is to provide a compression molding apparatus for compression molding a glass product in the form of a molten glass gob by heating and melting the glass raw material. Glass melting furnace is a melter for supplying glass raw materials and melting them by heating, refiner which removes bubbles in the molten glass to make high quality glass, and is formed to communicate with the refiner to form molten glass. It has a feeder for providing a compression molding apparatus and the like 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.

2 is a cross-sectional view of the glass discharge region of the conventional glass melting furnace. As shown, the bowl 101 formed with a molten flow path is coupled to the outlet region of the molten glass formed in the end region of the feeder (not shown) to guide the flow of the molten glass. A truncated cone-shaped orifice ring 103 is disposed below the bowl 101, and the orifice ring 103 is supported by the orifice holder 105 to be detachably attached to the bowl 101. In the glass flow path of the bowl 101, a needle (not shown) is installed to rotate and move up and down to agitate and discharge the molten glass.

On the other hand, the bowl heater 109 is provided in the inner lower edge region of the bowl 101 to heat the contact area between the bowl 101 and the orifice holder 105. The bowl heater 109 has a heater cover 111 coupled to form an accommodation space provided between the upper surface of the orifice holder 105 and the bowl 101 and a heater coil 113 disposed in the accommodation space.

The orifice holder 105 is provided with an orifice heater 115 to heat the contact area of the orifice ring 103. The orifice heater 115 has a coil accommodating part 117 recessed from an inner diameter surface of the orifice holder 105 and a heater coil 119 accommodated in the coil accommodating part 117 and electrically connected to each other.

By the way, in the conventional glass melting furnace, in the event of a disconnection of the bowl heater provided to heat the inner lower edge region of the bowl, it is impossible to replace or repair, so that the temperature is relatively low from the outside through the contact region between the bowl and the orifice holder. Since the air is introduced into contact with the molten glass of a relatively high temperature, the devitrification occurs in the contact area (JOINT AREA), and thus there is a problem that the glass product is degraded.

Accordingly, an object of the present invention is to provide a heater which is easy to exchange and repair in the mutual contact area of the bowl and the orifice holder to heat the mutual contact area, thereby causing a temperature difference between the air introduced from the outside through the mutual contact area and the molten glass. It is to provide a glass melting furnace that can suppress the glass defects caused by.

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

2 is a cross-sectional view of the glass discharge region of the conventional glass melting furnace.

* Explanation of symbols for the main parts of the drawings

1: bowl 3: glass flow path

7: orifice ring 9: orifice holder

11 bowl heater 13 first heating unit

14, 18: coil receiving portion 15: the second heating portion

16,20: heater coil

The object is, according to the present invention, a bowl for forming a flow path of molten glass in the end region, an orifice ring disposed at the end of the flow path of the molten glass, and detachably coupled to the bowl to support the orifice ring A glass melting furnace having an orifice holder, wherein the orifice holder is formed by a glass melting furnace, characterized in that a first heating portion is formed to heat an adjacent region of an inner edge of the bowl.

Here, the first heating unit preferably includes a heater accommodating portion cut down from the bowl contact surface of the orifice holder and a heater accommodated in the heater accommodating portion.

In addition, the heater may vary the amount of heat generated, and it is effective to form a second heating part in the orifice holder to heat the end region of the orifice.

In addition, the first heating unit and the second heating unit preferably operates independently of each other.

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 region of the glass melting furnace according to the present invention. As shown, the bowl (1) is coupled to the glass outlet region formed at the end of the feeder (not shown) to guide the flow of the glass, the glass flow path (3) of the bowl (1) along the vertical direction A needle (not shown) is installed to lift and rotate to release the molten glass by stirring and pressing. An orifice ring 7 is arranged below the bowl 1 so that the molten glass can be provided to the compression molding apparatus or the like in the form of a gob of a predetermined size. The orifice ring 7 is housed inside the orifice holder 9 which is detachably coupled to the lower side of the bowl 1. A bowl heater 11 is provided in the mutual contact area between the orifice holder 9 and the bowl 1 so as to heat the mutual contact area between the orifice holder 9 and the bowl 1.

On the other hand, the first heating portion 13 is formed on the upper surface of the orifice holder 9 so as to heat the mutual contact area between the orifice holder 9 and the bowl 1 corresponding to the bowl heater 11. The first heating unit 13 is a coil accommodating part 14 cut down from the upper surface of the orifice holder 9 and the amount of heat generated in the coil accommodating part 14 can be varied according to the magnitude of the supplied voltage. It has a heater coil (16).

The second heating part 15 is formed in the contact area of the orifice ring 7 of the orifice holder 9 so as to heat the lower area of the orifice ring 7. The second heating part 15 is recessed from the inner diameter surface of the orifice holder 9 and extends along the circumferential direction to have a coil accommodating part 18 having an annular shape, and housed in the coil accommodating part 18 to supply power from the outside. When it is applied to have a ring-shaped heater coil 20 to generate heat.

Here, the first heating unit 13 and the second heating unit 15 are configured to be a power circuit that acts independently of each other.

With this configuration, the first heating unit 13 heats the contact area between the bowl 1 and the orifice holder 9 in cooperation with the bowl heater 11 with a relatively low heat generation amount. When the bowl heater 11 becomes inoperable due to disconnection or the like, the calorific value of the first heating unit 13 is increased to sufficiently heat the mutual contact area between the bowl 1 and the orifice holder 9. do.

Thereby, the air which flows in from the outside through mutual contact area | region is heated, and it can reduce the temperature difference between molten glass, and can easily suppress the devitrification defect of the molten glass resulting from a temperature difference. In addition, the first heating part 13 may be formed in the orifice holder 9 which is detachably coupled to the bowl 1, thereby facilitating repair and replacement.

As described above, according to the present invention, the heater and the orifice holder is provided with a heater which is easy to exchange and repair, and the mutual contact area is heated, thereby allowing air and molten glass introduced from the outside through the mutual contact area. A glass melting furnace is provided which can suppress glass defects caused by a temperature difference of.

Claims (5)

A glass melting furnace having a bowl forming a flow path of molten glass in an end region, an orifice ring disposed at an end of the flow path of molten glass, and an orifice holder detachably coupled to the bowl to support the orifice ring. , And the first heating portion is formed in the orifice holder to heat the adjacent region of the inner edge of the bowl. The method of claim 1, And the first heating portion includes a heater accommodating portion cut down from the bowl contact surface of the orifice holder and a heater accommodated in the heater accommodating portion. The method of claim 2, The heater is a glass melting furnace, characterized in that the amount of heat can be varied. The method according to any one of claims 1 to 3, And the second heating part is formed in the orifice holder to heat the end region of the orifice. The method of claim 4, wherein And the first heating unit and the second heating unit operate independently of each other.