CN209853974U - Glass electric melting furnace glass liquid feed way - Google Patents

Abstract

The utility model is suitable for a glass electric melting furnace technical field provides a glass electric melting furnace glass liquid feed way, including feed way subassembly and homogenization subassembly, the feed way subassembly includes glass liquid material way, high temperature resistant layer, electrode and heat preservation, high temperature resistant layer with glass liquid material way fixed connection, and be located on the inside wall of glass liquid material way, the electrode with high temperature resistant layer fixed connection, and be located the middle part of the inside wall in the high temperature resistant layer, the heat preservation with glass liquid material way fixed connection; through being provided with spiral helicine stirring vane, agitator motor and (mixing) shaft, after agitator motor and external power source electric connection, drive the (mixing) shaft, and then drive agitator blade stirring glass liquid, both can improve the temperature difference of high-temperature region and low-temperature region in the glass liquid material way, guarantee the stability and the homogeneity of feed to spiral helicine stirring vane can make itself have the more smooth and easy of the glass liquid circulation of consistency.

Description

Glass electric melting furnace glass liquid feed way

Technical Field

The utility model belongs to the technical field of the glass electric melting furnace, especially, relate to a glass electric melting furnace glass liquid feed way.

Background

Glass is an electrical conductor at high temperatures. The molten glass contains alkali metal sodium and potassium ions, and has conductivity. Joule heat is generated when the current passes through, and if the heat is large enough, it can be used to melt glass, which is called "glass melting".

The glass liquid feed channel in the prior glass electric melting furnace forms a high-temperature area due to the fact that glass liquid at the center of the feed channel is relatively slow in heat dissipation, and glass liquid at two sides of the feed channel is fast in heat dissipation to form a low-temperature area, so that the temperature difference of the glass liquid is large, the temperature of the glass liquid at the high-temperature area is high, flowing is fast, forming of the glass liquid is difficult, the temperature of the glass liquid at two sides is low, and the distribution is not smooth due to the fact that the glass liquid has viscosity, and the difference between the high-temperature area and the low-temperature area affects the uniformity and stability of feeding.

SUMMERY OF THE UTILITY MODEL

The utility model provides a glass electric melting furnace glass liquid feed way, the glass liquid feed way that aims at solving original glass electric melting furnace is because the glass liquid at feed way center dispels the heat relatively slower, high temperature region has been formed, and the glass liquid heat dissipation on feed way both sides is very fast, the low temperature zone has been formed, the temperature difference that leads to glass liquid like this is great, high temperature region's glass liquid temperature is high simultaneously, it is fast to flow, lead to glass liquid shaping difficulty, the glass liquid temperature on both sides is low, add the viscidity that glass liquid itself has again, lead to the circulation unsmooth, high temperature region influences the homogeneity and the problem of stability of feed with the difference of low temperature region.

The utility model is realized in such a way, the glass electric melting furnace glass liquid feed channel comprises a feed channel component and a homogenizing component, wherein the feed channel component comprises a glass liquid material channel, a high temperature resistant layer, an electrode and a heat preservation layer, the high temperature resistant layer is fixedly connected with the glass liquid material channel and is positioned on the inner side wall of the glass liquid material channel, the electrode is fixedly connected with the high temperature resistant layer and is positioned in the middle of the inner side wall of the high temperature resistant layer, the heat preservation layer is fixedly connected with the glass liquid material channel and is positioned on the outer side wall of the glass liquid material channel, the homogenizing component comprises a stirring motor, a stirring shaft and stirring blades, the stirring motor is fixedly connected with the glass liquid material channel and is positioned on one side of the glass liquid material channel, the stirring shaft is fixedly connected with the output end of the stirring motor and is positioned in the glass liquid material channel, the stirring blades are fixedly connected with the stirring shaft respectively and are positioned on two sides of the stirring shaft respectively.

The utility model discloses still provide preferred, the feed says that the subassembly still includes feed inlet and discharge gate, the feed inlet with glass liquid material says fixed connection, and is located the top that glass liquid material said, the discharge gate with glass liquid material says fixed connection, and is located the below that glass liquid material said.

The utility model discloses still provide preferred, the homogenization subassembly still includes the motor room, the motor room with glass liquid material says fixed connection, and is located one side that glass liquid material said.

The utility model discloses it is preferred still to provide, stirring vane is the heliciform.

The utility model discloses still provide preferred, the quantity of electrode be four, respectively with glass liquid material says fixed connection, and is located respectively glass liquid material says that the inside wall of mid portion is all around.

The utility model discloses it is preferred still to provide, the electrode with agitator motor all with external power source electric connection.

Compared with the prior art, the beneficial effects of the utility model are that: the utility model discloses a glass electric melting furnace glass liquid feed way, through being provided with spiral helicine stirring vane, agitator motor and (mixing) shaft, after agitator motor and external power source electric connection, drive the (mixing) shaft, and then drive agitator blade stirring glass liquid, both can improve the temperature difference of glass liquid material way interior high temperature region and low temperature zone, guarantee the stability and the homogeneity of feed to spiral helicine stirring vane can make itself have more smooth and easy of the glass liquid circulation of consistency.

Drawings

Fig. 1 is a schematic view of the internal structure of the present invention;

FIG. 2 is a schematic side view of an electrode according to the present invention;

fig. 3 is a schematic top view of the present invention;

in the figure: 1-a feed channel component, 11-a glass liquid channel, 12-a high temperature resistant layer, 13-an electrode, 14-a heat insulation layer, 15-a feed inlet, 16-a discharge outlet, 2-a homogenizing component, 21-a stirring motor, 22-a stirring shaft, 23-a stirring blade and 24-a motor chamber.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

Referring to fig. 1-3, the present invention provides a glass electric melting furnace glass liquid feed channel technical solution: comprises a feed channel component 1 and a homogenizing component 2, wherein the feed channel component 1 comprises a glass frit channel 11, a high temperature resistant layer 12, an electrode 13 and a heat insulation layer 14, the high temperature resistant layer 12 is fixedly connected with the glass frit channel 11, and is positioned on the inner side wall of the glass frit channel 11, the electrode 13 is fixedly connected with the high temperature resistant layer 12, and is positioned in the middle of the inner side wall of the high temperature resistant layer 12, the heat insulation layer 14 is fixedly connected with the glass liquid channel 11, and is positioned on the outer side wall of the glass frit channel 11, the homogenizing assembly 2 comprises a stirring motor 21, a stirring shaft 22 and stirring blades 23, the stirring motor 21 is fixedly connected with the glass frit channel 11, and is positioned at one side of the glass liquid channel 11, the stirring shaft 22 is fixedly connected with the output end of the stirring motor 21, and is located the inside of glass frit way 11, and stirring vane 23 quantity is a plurality of, and stirring vane 23 is respectively with (mixing) shaft 22 fixed connection, and is located the both sides of (mixing) shaft 22 respectively.

In this embodiment, through being provided with spiral helicine stirring vane 23, agitator motor 21 and (mixing) shaft 22, after agitator motor 21 and external power source electric connection, drive (mixing) shaft 22, and then drive agitator blade 23 stirring glass liquid, both can improve the temperature difference of high temperature region and low temperature zone in the glass liquid material way 11, guarantee the stability and the homogeneity of feed to spiral helicine stirring vane 23 can make itself have the more smooth and easy of the glass liquid circulation of viscidity.

Further, the feed channel assembly 1 further comprises a feed port 15 and a discharge port 16, wherein the feed port 15 is fixedly connected with the glass frit channel 11 and is located above the glass frit channel 11, and the discharge port 16 is fixedly connected with the glass frit channel 11 and is located below the glass frit channel 11.

In this embodiment, the feeding channel assembly 1 further includes a feeding port 15 and a discharging port 16, the feeding port 15 is fixed above one side of the glass frit channel 11, and the discharging port 16 is fixed below the other side of the glass frit channel 11 for feeding and discharging, respectively.

Further, the homogenizing assembly 2 further comprises a motor chamber 24, and the motor chamber 24 is fixedly connected with the glass frit channel 11 and is located on one side of the glass frit channel 11.

In this embodiment, the homogenizing assembly 2 further comprises a motor chamber 24, the motor chamber 24 is used for placing the stirring motor 21, and the motor chamber 24 protects the stirring motor 21.

Further, the stirring blade 23 has a spiral shape.

In this embodiment, after agitator motor 21 and external power source electric connection, agitator motor 21's output drove (mixing) shaft 22 and rotates to drive stirring vane 23 and rotate, because stirring vane 23 is the heliciform, can drive its and remove toward the discharge end when stirring glass liquid.

Furthermore, the number of the electrodes 13 is four, and the electrodes are respectively and fixedly connected with the glass frit channel 11 and are respectively located around the inner side wall of the middle part of the glass frit channel 11.

In this embodiment, the electrodes 13 are fixedly connected around the inner side wall of the glass frit channel 11, and are arranged in a staggered manner to form a parallelogram, so that the temperature in the glass frit channel 11 is relatively stable to a certain extent.

Further, the electrode 13 and the stirring motor 21 are electrically connected to an external power source.

In this embodiment, the electrode 13 needs power for heating the molten glass and the stirring motor 21 needs power for stirring, and an external power source is electrically connected to the electrode 13 and the stirring motor 21 to provide power.

The utility model discloses a theory of operation and use flow: the utility model discloses install the back, add glass liquid from feed inlet 15, with electrode 13 and agitator motor 21 all with external power supply electric connection, electrode 13 can heat the glass liquid that enters into in glass liquid material way 11, agitator motor 21 drives the (mixing) shaft 22 rotation, and then drive stirring vane 23 and rotate, can promote glass liquid to one side in the homogenization temperature, thereby increase the mobility of glass liquid, flow by discharge gate 16 at last, the use flow of a glass electric melting furnace glass liquid feed way has been accomplished.

The above description is only exemplary of the present invention and should not be taken as limiting the scope of the present invention, as any modifications, equivalents, improvements and the like made within the spirit and principles of the present invention are intended to be included within the scope of the present invention.

Claims (6)

1. The glass melting furnace glass liquid feed channel is characterized in that: the glass liquid homogenizing device comprises a feeding channel assembly (1) and a homogenizing assembly (2), wherein the feeding channel assembly (1) comprises a glass liquid material channel (11), a high temperature resistant layer (12), an electrode (13) and a heat insulating layer (14), the high temperature resistant layer (12) is fixedly connected with the glass liquid material channel (11) and is positioned on the inner side wall of the glass liquid material channel (11), the electrode (13) is fixedly connected with the high temperature resistant layer (12) and is positioned in the middle of the inner side wall of the high temperature resistant layer (12), the heat insulating layer (14) is fixedly connected with the glass liquid material channel (11) and is positioned on the outer side wall of the glass liquid material channel (11), the homogenizing assembly (2) comprises a stirring motor (21), a stirring shaft (22) and stirring blades (23), the stirring motor (21) is fixedly connected with the glass liquid material channel (11) and is positioned on one side of the glass liquid material channel (11), (mixing) shaft (22) with the output fixed connection of agitator motor (21), and be located the inside of glass frit way (11), stirring vane (23) quantity is a plurality of, stirring vane (23) respectively with (mixing) shaft (22) fixed connection, and be located respectively the both sides of (mixing) shaft (22).

2. A molten glass supply channel for a glass electric melter according to claim 1 wherein: the feed channel assembly (1) further comprises a feed inlet (15) and a discharge outlet (16), wherein the feed inlet (15) is fixedly connected with the glass frit channel (11) and is located above the glass frit channel (11), and the discharge outlet (16) is fixedly connected with the glass frit channel (11) and is located below the glass frit channel (11).

3. A molten glass supply channel for a glass electric melter according to claim 1 wherein: the homogenizing assembly (2) further comprises a motor chamber (24), wherein the motor chamber (24) is fixedly connected with the glass liquid material channel (11) and is positioned on one side of the glass liquid material channel (11).

4. A molten glass supply channel for a glass electric melter according to claim 1 wherein: the stirring blade (23) is spiral.

5. A molten glass supply channel for a glass electric melter according to claim 1 wherein: the number of the electrodes (13) is four, the electrodes are respectively and fixedly connected with the glass frit channel (11), and the electrodes are respectively positioned on the periphery of the inner side wall of the middle part of the glass frit channel (11).

6. A molten glass supply channel for a glass electric melter according to claim 1 wherein: the electrode (13) and the stirring motor (21) are both electrically connected with an external power supply.