KR100340462B1 - Temperature control device for glass melting furnace feeder - Google Patents

Abstract

The present invention relates to a feeder temperature control apparatus for a glass melting furnace having a plurality of burners and a temperature sensing unit, comprising: a combustion air supply valve for supplying combustion air to the burner through a combustion air supply pipe; A fuel gas supply valve for supplying fuel gas to the burner through a fuel gas supply pipe; A flow rate sensing unit which senses flow rates of combustion air and fuel gas flowing into the combustion air supply valve and the fuel gas supply valve, respectively; And a plurality of flow controllers for controlling the flow rates of the combustion air and the fuel gas by comparing the flow rates of the combustion air and the fuel gas detected by each of the flow rate sensing units with a preset value. As a result, the flow rate on the upstream side of the combustion air supply valve and the fuel gas supply valve is kept constant, so that the amount of combustion air and fuel gas ultimately introduced into the burner can be properly controlled.

Description

Temperature control device for glass melting furnace feeder

The present invention relates to a temperature control apparatus for a feeder of a glass melting furnace, and more particularly, to the combustion air that ultimately flows into the burner by maintaining a constant flow rate upstream of the combustion air supply valve and the fuel gas supply valve. And a temperature control device for a feeder of a glass melting furnace capable of appropriately controlling the amount of fuel gas.

In general, the glass melting furnace is a melting furnace in which glass raw materials are introduced to dissolve glass raw materials, a clarification unit for clarifying molten glass dissolved in the melting furnace, a plurality of feeders through which the molten glass clarified from the clarification unit flows, and a distal end of the feeder. It has a bowl that is combined to supply molten glass to the molding apparatus.

4 is a block diagram of a conventional temperature control device for a feeder, and FIG. 5 is a block diagram of a conventional temperature control device. As shown in these figures, the feeder 105 is divided into a plurality of areas along the longitudinal direction, and burners 113 and a temperature sensing unit 111 are provided in these sections, respectively. Each burner 113 is provided with a combustion air supply pipe 115 and a fuel gas supply pipe 117 so that combustion air and fuel gas can be supplied, and the burner (burner) is provided in the combustion air supply pipe 115 and the fuel gas supply pipe 117. A combustion air supply valve 123 for adjusting the amount of combustion air supplied to 113 and a fuel gas supply valve 125 having a predetermined opening degree are respectively provided.

On the other hand, the temperature control unit 127 is installed to adjust the opening degree of the combustion air supply valve 123 by comparing the result detected by the temperature detection unit 111 with a preset value. In addition, the temperature sensing unit 127 is composed of a thermocouple 119 for sensing the temperature of each region, and the radiation heat sensing unit 121 for sensing the temperature by light.

By the above configuration, when the result detected by the temperature detector 111 is input to the temperature controller 127, the temperature controller 127 compares the detected temperature with a preset value. The opening degree of the combustion air supply valve 123 is adjusted by the result compared with the temperature control part 127, and the fuel gas supplied through the fuel gas supply valve 123 is the combustion air supply pipe 115 at the input of the burner 113. Is connected to communicate with) is introduced into the burner 113 by the combustion air and the venturi effect introduced into the burner 113.

By the way, in the conventional temperature control apparatus for feeders, even if the opening degree of the combustion air supply valve 123 is adjusted by the temperature control part 127 by the detection result of the temperature detection part 111 of the combustion air supply valve 123, Since the supply flow rates of the combustion air and fuel gas supplied from the upstream side and the fuel gas supply valve 125 upstream are not kept constant, it is difficult to properly control the amounts of the combustion air and fuel gas supplied to the burner 113. have.

Accordingly, an object of the present invention is to control the flow rate of the upstream side of the combustion air supply valve and the fuel gas supply valve and ultimately the feeder of the glass melting furnace capable of appropriately controlling the amount of combustion air and fuel gas flowing into the burner. It is to provide a temperature control device.

1 is a schematic configuration diagram of a typical glass melting furnace,

2 is a configuration diagram of a temperature control device for a feeder according to the present invention;

3 is a block diagram of a temperature control device according to the present invention;

4 is a configuration diagram of a conventional feeder temperature control device;

5 is a block diagram of a conventional temperature control device.

* Explanation of symbols for the main parts of the drawings

11 temperature sensing unit 13 burner

23: combustion air supply valve 25: fuel gas supply valve

27: temperature control unit 29: combustion air flow meter

31: fuel gas flow meter 33a, 33b: flow control unit

35a, 35b: drive motor 37: combustion air flow valve

39: fuel gas flow valve

According to the present invention, there is provided a temperature control apparatus for a feeder of a glass melting furnace having a plurality of burners and a temperature sensing unit, comprising: a combustion air supply valve for supplying combustion air to a burner through a combustion air supply pipe; A fuel gas supply valve for supplying fuel gas to the burner through a fuel gas supply pipe; A flow rate sensing unit which senses flow rates of combustion air and fuel gas flowing into the combustion air supply valve and the fuel gas supply valve, respectively; Temperature control for the feeder of the glass melting furnace comprising a plurality of flow control unit for controlling the flow rate of the combustion air and fuel gas by comparing the flow rate of the combustion air and fuel gas detected by the flow rate detection unit with a predetermined value Achieved by the device.

Here, the fuel gas flow valve and the combustion air flow valve which is provided upstream of the fuel gas supply valve and the combustion air supply valve, respectively; And a drive motor for adjusting the opening degree of the fuel gas flow valve and the combustion air flow valve by a signal of the flow control unit, thereby controlling the inflow flow rates of the combustion air and fuel gas.

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

1 is a schematic configuration diagram of a typical glass melting furnace. As shown in this figure, in general, a glass melting furnace for melting glass in order to mold a glass product is supplied with a glass raw material and an auxiliary raw material added for coloring the product, and then heated to about 1400-1500 ° C. to dissolve the furnace ( 1), the clarification part 3 for clarifying the molten glass melted in the melting furnace 1 at about 1070-1400 ° C., and the molten glass clarified at the clarification part 3, It has a feeder 5 for guiding to flow toward, and a bowl 7 which is coupled to the end region of the feeder 5 and supplies molten glass flowing through the feeder 5 to the molding apparatus. Between the melting furnace 1 and the clarification part 3, the cooling part 9 which cools the molten glass toward the clarification part 3 from the melting furnace 1 is provided.

2 is a block diagram of a temperature control apparatus for a feeder according to the present invention, Figure 3 is a block diagram of a temperature control apparatus according to the present invention. As shown in these figures, the temperature sensing unit 11 and the burner 13 are provided in each region of the feeder 5 which is divided into a plurality of regions. Each burner 13 is connected to a combustion air supply pipe 15 and a fuel gas supply pipe 17 through which combustion air and fuel gas are supplied, and the temperature sensing unit 11 detects a temperature of each region. ), And a radiant heat detector 21 for detecting radiant heat of each region.

In the combustion air supply pipe 15 and the fuel gas supply pipe 17, the combustion air supply valve 23 and the combustion air supply valve 23 and the fuel gas supply pipe 23, respectively, are controlled to control the amount of the combustion air and the fuel gas flowing into the burner 13 as a result of the temperature sensing unit 11. The fuel gas supply valve 25 is installed, and the fuel gas supply valve 25 of the supply valves 23 and 25 is opened to a certain degree, and the combustion air supply valve 23 is connected to the temperature sensing unit 11. The opening degree is adjusted by the temperature control unit 27 which compares the sensed temperature and inputs the result of the comparison.

On the other hand, upstream of the combustion air supply valve 23 and the fuel gas supply valve 25, the combustion air flow meter 29 and the fuel for detecting the flow rate of the combustion air and fuel gas flowing toward the supply valves 23 and 25, respectively. Gas flowmeters 31 are provided respectively. In addition, the flow control unit 33a, 33b for controlling the flow rate of the combustion air and fuel gas in accordance with the comparison result by comparing the inflow flow rate of the combustion air and fuel gas detected by each of these flow meters (29, 31) Is provided.

Flow rate control of the combustion air and fuel gas is carried out by the inverter type drive motors 35a and 35b driven by these flow control sections 33a and 33b. The combustion air flow rate valve 37 and the fuel gas flow rate valve 39 are opened. As it changes.

By the above configuration, the combustion air supply valve 23 and the fuel gas supply valve 25 for adjusting the amount of combustion air and fuel gas introduced into the burner 13 by the temperature sensing unit 11 are thermocouples 19. And as a result of the detection of the radiant heat detection unit 21 is input to the temperature control unit 27 is compared with the preset value. Thus, through the comparison result, the temperature control unit 27 adjusts the opening degree of the combustion air supply valve 23 provided in the combustion air supply pipe 15 to adjust the amount of combustion air flowing into the burner 13, and the combustion air supply pipe Fuel gas is introduced into the burner 13 by the venturi effect along with the combustion air passing through the combustion air supply pipe 15 through the fuel gas supply pipe 17 connected to communicate with the 15.

On the other hand, the flowmeters provided on each upstream side of the combustion air supply valve 23 and the fuel gas supply valve 25 have flow rates of the combustion air and fuel gas directed to the combustion air supply valve 23 and the fuel gas supply valve 25. As it is installed to maintain a constant, it is to sense the flow rate of combustion air and fuel gas directed to each supply valve (23, 25). In this way, the detected combustion air and fuel gas flow rates are input to the flow rate control units 33a and 33b to be compared with the flow rate values preset by the flow rate control units 33a and 33b.

As a result of the comparison, the flow rate control units 33a and 33b drive the drive motors 35 installed in the combustion air flow rate valve 37 and the fuel gas flow rate valve 39, respectively, by the flow rate control units 33a and 33b. The opening degree of each of the flow valves 37 and 39 is controlled by the operation of the driving motor 35 to be driven so that combustion air and fuel gas flow into the combustion air supply valve 23 and the fuel gas supply valve 25 at a constant flow rate. do.

Thus, when a certain amount of combustion air and fuel gas is supplied, the amount of combustion air and fuel gas flowing into the burner 13 is determined only by the opening degree of the combustion air supply valve 23 controlled by the temperature control unit 27. As a result, temperature control of each area of the feeder 5 becomes easy.

As described above, according to the present invention, it is possible to appropriately control the amount of combustion air and fuel gas flowing into the burner by maintaining a constant flow rate upstream of the combustion air supply valve and the fuel gas supply valve. A temperature control device for a feeder of a glass melting furnace is provided.

Claims (2)

In the temperature control device for a feeder of a glass melting furnace having a plurality of burners and a temperature sensing unit, A combustion air supply valve for supplying combustion air to the burner through a combustion air supply pipe; A fuel gas supply valve for supplying fuel gas to the burner through a fuel gas supply pipe; A flow rate sensing unit which senses flow rates of combustion air and fuel gas flowing into the combustion air supply valve and the fuel gas supply valve, respectively; Temperature control for the feeder of the glass melting furnace comprising a plurality of flow control unit for controlling the flow rate of the combustion air and fuel gas by comparing the flow rate of the combustion air and fuel gas detected by the flow rate detection unit with a predetermined value Device. The method of claim 1, A fuel gas flow valve and a combustion air flow valve which are respectively installed upstream of the fuel gas supply valve and the combustion air supply valve; And a drive motor for adjusting the opening degree of the fuel gas flow valve and the combustion air flow valve in response to a signal of the flow control unit.