KR20050073269A - Indirect heating apparatus which heat glass - Google Patents

Abstract

The present invention provides a glass indirect heating apparatus for indirectly heating molten glass material, comprising: a flow tube through which molten glass flows in a glass melting furnace; Refractories surrounding the outer side of the flow tube and delivers thermal energy to the flow tube; The inner side of the refractory is provided with a receiving groove, characterized in that it comprises a heating conductor accommodated in the receiving groove to heat the refractory. As a result, when a temperature change occurs due to external noise, a glass indirect heating device capable of supplying stable molten glass material by slowing the reaction of the flow tube according to the temperature change can be improved, thereby improving the quality of the glass product.

Description

Indirect Heating Apparatus which heat glass}

The present invention relates to a glass indirect heating device for indirectly heating a molten glass material, and more particularly, to a glass indirect heating device capable of supplying a stable molten glass material by slowing a reaction of a flow tube due to a temperature change.

4 is a block diagram of a conventional glass heating apparatus, as shown, the heating device 101 for heating the molten glass water, the flow pipe 110 through which the molten glass flows, and the flow pipe 110 is heated It consists of a plurality of heating conductors 120, and a transformer 130 for converting the voltage applied to the flow pipe (110).

The flow pipe 110 through which the dissolved glass flows in the glass melting furnace 110 has protrusions 115 at both ends, and the protrusions 115 are wrapped with a conductor (not shown).

The plurality of heating wires 120 are connected to a voltage supply unit (not shown), a transformer 130, and a conductor (not shown) of the protrusion 115 of the flow pipe 110, and a voltage is supplied from the voltage supply unit (not shown). 130 is applied to the flow pipe 110 and the voltage converted in the transformer 130. Here, the voltage supplied from the voltage supply unit (not shown) preferably uses an AC voltage.

The transformer 130 having the first induction coil 133 and the second induction coil 136 is provided corresponding to the flow pipe 110 and is applied to the first induction coil 133 from a voltage supply unit (not shown). The converted voltage is converted into a high voltage by electromagnetic induction with the second induction coil 136.

By this configuration, the voltage of the voltage supply unit (not shown) is applied to the transformer 130 is converted into a high voltage and the high voltage is applied to the flow pipe (110). Here, the voltage applied to the flow tube 110 generates heat energy by Joule's law to heat the flow tube 110.

By the way, in the conventional heating apparatus for heating the molten glass material, the heating conductor is connected to the flow tube, and the flow tube was directly heated by the heating conductor. Therefore, when external noise is generated, the flow tube reacts quickly to external noise, causing a temperature change in the flow tube, thereby stably supplying molten glass, thereby degrading the quality of the glass product.

Accordingly, an object of the present invention is to provide a glass indirect heating apparatus which can supply stable molten glass material by slowing the reaction of the flow tube according to the temperature change when a temperature change occurs due to external noise, thereby improving the quality of the glass product. To provide.

According to the present invention, there is provided a glass indirect heating apparatus for indirectly heating a molten glass, comprising: a flow tube through which molten glass flows in a glass melting furnace; Refractories surrounding the outer side of the flow tube and delivers heat energy to the flow tube; An accommodation groove is provided inside the refractory, and the glass indirect heating device is provided in the accommodation groove and includes a heating conductor for heating the refractory.

On the other hand, the heating conductor is made of one of platinum wire, platinum plate and the flow tube is made of a platinum tube, which can withstand high temperature and does not cause corrosion can be used for a long time.

In addition, by further including an insulator surrounding the outside of the flow tube to a predetermined thickness, it is possible to prevent the heating conductor from applying a voltage to the flow tube.

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

1 is a perspective view of a glass indirect heating apparatus according to the present invention, Figure 2 is a front view of the first refractory according to the present invention, Figure 3 is a cross-sectional view taken along line III-III of FIG. As shown in this figure, the glass indirect heating device 1 for indirectly heating the molten glass material includes a flow tube 10 through which molten glass flows in a glass melting furnace, a refractory surrounding the outside of the flow tube 10, and a refractory material. It has the heating conductor 30 which heats.

The inside of the flow tube 10 flows with molten glass in a glass melting furnace, and the outside is wrapped with an insulator 20 having a predetermined thickness. The insulator 20 prevents the heating conductor 30, which will be described later, from directly contacting the flow tube 10, so that the flow tube 10 is not directly heated by the heating conductor 30. In addition, the flow tube 10 is preferably made of a platinum tube that can withstand high temperature and can be used for a long time without causing corrosion.

The refractory to transfer the heat energy to the flow tube 10 wraps the insulator 20 surrounding the outside of the flow tube 10 and consists of the first refractory 40 and the second refractory 50 to facilitate separation, coupling and maintenance. Will be. Inside the first and second refractories 40 and 50, first and second accommodating grooves 45 and 55 having a zigzag shape having an equal interval of a predetermined depth are provided, respectively. 55, the heating conductor 30 to be described later is accommodated.

The heating conductor 30 is spaced apart from the insulator 20 surrounding the outer side of the flow tube 10 by a predetermined distance, respectively, in the first and second accommodating grooves 45 and 55 provided in the first and second refractories 40 and 50, respectively. It is accommodated and made of one of platinum wire or platinum plate, so it does not cause corrosion and can withstand high temperatures for long time use.

The heating conductor 30 has a zigzag shape at equal intervals in accordance with the shape of the first and second accommodation grooves 45 and 55 provided inside the first and second refractories 40 and 50, respectively. And the surface area in contact with the second refractory (40, 50) is widened to increase the heat dissipation effect. In addition, both ends of each heating conductor 30 accommodated in the first and second accommodating grooves 45 and 55 of the first and second refractories 40 and 50 are connected to a heating conductor (not shown) and a transformer (not shown). Is applied to generate a heat to heat the first and second refractory (40, 50).

By such a configuration, the heating conductor 30 applied with the high voltage converted by the transformer (not shown) through the heating conductor (not shown) connected to both ends of the heating conductor 30 generates heat energy by the law of Joule. The generated heat energy is transferred to the first and second refractory materials 40 and 50 to heat the first and second refractory materials 40 and 50, and the first and second refractory materials 40 and 50 again transmit thermal energy to an insulator ( The flow pipe 10 is heated by the flow pipe 10 through 20.

As described above, according to the present invention, a flow tube through which molten glass flows in a glass melting furnace, an insulator for preventing the heating conductor from directly contacting the flow tube, a refractory for transferring heat energy transferred from the heating conductor to the flow tube, and a refractory body are heated. By having a heating conductor, it is possible to improve the quality of glass products by supplying a stable molten glass material by slowing the reaction of the flow tube due to the temperature change when a temperature change occurs due to external noise.

Meanwhile, in the above-described embodiment, the insulator 20 is disclosed to surround the outside of the flow tube 10, but without the insulator, the heating conductor may be spaced a predetermined distance apart from the flow tube and accommodated in the accommodating groove of the refractory.

In addition, in the above embodiment, the refractory is disclosed as being separated into two, but may be separated into a plurality.

As described above, according to the present invention, when the temperature change is caused by external noise, the glass indirect heating can improve the quality of the glass product by supplying a stable molten glass material by slowing the reaction of the flow tube according to the temperature change. An apparatus is provided.

1 is a perspective view of an indirect glass heating apparatus according to the present invention,

2 is a front view of a first refractory according to the present invention;

3 is a cross-sectional view taken along line III-III of FIG. 1;

4 is a block diagram of a conventional glass heating apparatus.

* Explanation of symbols for the main parts of the drawings

 1: glass indirect heating device 10: flow tube

20: insulator 30: heating conductor

40: first refractory 45: first receiving groove

50: second refractory 55: second receiving groove

Claims (4)

In the glass indirect heating device for indirectly heating the molten glass, A flow tube through which molten glass flows in the glass melting furnace; Refractories surrounding the outer side of the flow tube and delivers heat energy to the flow tube; An accommodation groove is provided inside the refractory, And a heating conductor housed in the receiving groove to heat the refractory material. The method of claim 1, The heating conductor is a glass wire, indirect heating device, characterized in that consisting of one of the platinum plate. The method according to claim 1 or 2, Synchronous heating apparatus further comprises an insulator surrounding the outside of the flow tube to a predetermined thickness. The method of claim 3, The flow tube is a glass indirect heating device, characterized in that consisting of a platinum tube.