CN113387538B - Automatic reinforced glass smelting pot - Google Patents

Abstract

The invention relates to an automatic charging glass melting furnace, which comprises a melting furnace, a furnace cover, a traveling assembly and a hopper; the furnace cover is arranged at the top end of the smelting furnace; the hopper is arranged on the walking component, the hopper can move in the furnace cover along a first direction and a second direction which are vertical to each other under the driving of the walking component, and the plane where the first direction and the second direction are located is parallel to the top end surface of the smelting furnace; the hopper can be opened or closed under the driving of the walking component; the hopper and the walking component are both made of metal parts. According to the automatic feeding glass melting furnace provided by the invention, the hopper and the walking assembly are arranged in the furnace cover, the hopper moves in a plane parallel to the top end face of the melting furnace in the furnace cover by virtue of the walking assembly, and glass materials can be conveyed to any position of the top end face of the melting furnace through the hopper to shield molten glass in time.

Description

Automatic reinforced glass smelting pot

Technical Field

The invention relates to the field of glass processing smelting furnace equipment, in particular to an automatic charging glass smelting furnace.

Background

In a glass product factory, quartz sand and recycled glass are required to be mixed according to a certain proportion, added into a smelting furnace and gradually output to a glass product production line in a molten state. Nowadays, large-scale factories rarely adopt a manual feeding production mode, and most of the large-scale factories adopt automatic conveying equipment to input glass materials into a glass melting furnace.

Glass melting furnaces are often large, and in order to avoid excessive liquid surface temperatures, glass frits are generally used to cover molten glass, i.e., red tops in glass melting furnaces are avoided in factories. As the new glass frit on the inner surface of the glass melting furnace is heated to be continuously melted and finally becomes molten glass melt, the red top phenomenon occurs again, so that the new glass frit needs to be continuously added to the surface of the glass melt in the glass melting furnace.

In the existing equipment, a conveyor belt is usually extended into a glass melting furnace, and glass frits are uniformly added to the surface of a glass melt through the extension and contraction and the swing of the conveyor belt. However, the conveyor belt stays in the high-temperature glass melting furnace for a long time, so that the service life of the conveyor belt is short, the conveyor belt needs to be replaced frequently, the production cost is high, and the production efficiency is influenced.

Disclosure of Invention

In view of this, there is a need to provide an automatic charging glass furnace that addresses at least one of the problems noted above.

The invention provides an automatic charging glass melting furnace, which comprises a melting furnace, a furnace cover, a traveling assembly and a hopper; the furnace cover is arranged at the top end of the smelting furnace;

the hopper is arranged on the walking assembly, the hopper can move in a first direction and a second direction which are perpendicular to each other in the furnace cover under the driving of the walking assembly, and the plane of the first direction and the plane of the second direction are parallel to the top end surface of the smelting furnace; the hopper can be driven by the walking assembly to open or close;

the hopper and the walking assembly are both parts made of metal materials.

In one embodiment, the walking assembly comprises a cross beam, a walking base, a bracket and a driving part, wherein the driving part is arranged on the walking base, and the walking base is arranged on the bracket and can move on the bracket along the first direction; the driving part is in transmission connection with the walking base and the hopper respectively, the driving part can drive the hopper to move on the cross beam, and the length direction of the cross beam is the second direction; the beam is movably connected to the inner side wall of the furnace cover opposite to the support.

In one embodiment, the hopper comprises a connecting seat, a traction rope and a hopper body capable of being opened and closed, the connecting seat is movably arranged on the cross beam, a threaded through hole is formed in the connecting seat, a lead screw is arranged on the cross beam, and the lead screw is arranged in the threaded through hole in a penetrating mode; the lead screw and the traction rope are in transmission connection with the driving part; the bucket body is fixedly connected to the connecting seat, and the traction rope is connected with the bucket body.

In one embodiment, the driving part includes a first driving part, a second driving part, and a third driving part;

the first driving part is used for driving the walking base to move on the bracket;

the second driving part is in transmission connection with the lead screw and is used for driving the lead screw to rotate;

the third driving part is connected with the traction rope and used for traction the traction rope.

In one embodiment, the cross beam is located inside the furnace enclosure and the support is located outside the furnace enclosure.

In one embodiment, the inner side wall of the furnace cover is provided with a guide rail and a slide block, and the slide block is arranged in the guide rail and can move along the guide rail; the cross beam is connected to the sliding block.

In one embodiment, three baffles are arranged on the top end surface of the furnace cover, and the baffles form a cuboid-shaped space with one side open on the top end surface of the furnace cover; and a movable piston plate is further arranged in the cuboid space, and two sides of the piston plate are abutted against the baffle plates on two sides of the cuboid space.

In one embodiment, a hopper opening is arranged on a side wall of the furnace cover parallel to the second direction, and the hopper can enter and exit the furnace cover through the hopper opening; the side wall is provided with a flow guide box, the top end of the flow guide box corresponds to the opening of the rectangular space, and the bottom opening of the flow guide box can be in butt joint with the hopper. The technical scheme provided by the embodiment of the invention has the following beneficial technical effects:

according to the automatic feeding glass melting furnace provided by the invention, the hopper and the walking assembly are arranged in the furnace cover, the hopper moves in a plane parallel to the top end face of the melting furnace in the furnace cover by virtue of the walking assembly, and the glass material can be conveyed to any position of the top end face of the melting furnace through the hopper, so that molten glass can be shielded in time, and the phenomenon of red top can be avoided for a long time.

Additional aspects and advantages of the present application will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention.

Drawings

FIG. 1 is a schematic view of a first perspective plan view of an automatic feed glass furnace according to an embodiment of the present invention;

FIG. 2 is a schematic view of a first perspective plan view of an automatic feed glass furnace according to another embodiment of the present invention;

FIG. 3 is a schematic view of a second perspective plan view of an automatic feed glass furnace according to another embodiment of the present invention.

Detailed Description

To facilitate an understanding of the invention, the invention will now be described more fully with reference to the accompanying drawings. Possible embodiments of the invention are given in the figures. The invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. The embodiments described by way of example with reference to the figures are intended to provide a more complete understanding of the disclosure of the present invention and are not to be construed as limiting the invention. In addition, if a detailed description of known technologies is not necessary for the features of the present invention shown, such technical details may be omitted.

It will be understood by those skilled in the relevant art that, unless otherwise defined, all terms (including technical and scientific terms) used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. It will be further understood that terms, such as those defined in commonly used dictionaries, should be interpreted as having a meaning that is consistent with their meaning in the context of the art and will not be interpreted in an idealized or overly formal sense unless expressly so defined herein.

As used herein, the singular forms "a", "an", "the" and "the" are intended to include the plural forms as well, unless the context clearly indicates otherwise. It will be further understood that the terms "comprises" and/or "comprising," when used in this specification, specify the presence of stated features, integers, steps, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, and/or groups thereof. It will be understood that, as used herein, the term "and/or" includes all or any element and all combinations of one or more of the associated listed items.

The automatic charging glass melting furnace 100 provided by the invention application is shown in fig. 1 and comprises a melting furnace 100, a furnace cover 200, a walking component 300 and a hopper 400; the furnace mantle 200 is provided at the top end of the furnace 100. The melting furnace 100 is an electric melting furnace 100 commonly used in glass factories, and the furnace cover 200 is used for sealing the top of the electric melting furnace 100, however, the furnace cover does not need to be completely sealed, and some material or equipment access space may be reserved. The furnace cover 200 can be made of refractory and heat-insulating materials, and the specific space size is determined according to actual needs. A charging hole for adding glass material to the hopper 400 is also required to be arranged on the furnace cover 200 or outside the furnace cover 200, and the glass material is fed into the charging hole by means of a conveyor belt and then loaded into the hopper 400.

The hopper 400 is arranged on the walking assembly 300, the hopper 400 can move in a first direction and a second direction which are perpendicular to each other in the furnace cover 200 under the driving of the walking assembly 300, and the plane of the first direction and the plane of the second direction are parallel to the top end surface of the smelting furnace 100; the hopper 400 can also be driven by the walking assembly 300 to open or close. The hopper 400 moves laterally or longitudinally in a plane above the top end face of the furnace 100, the first direction being considered to be lateral and the second direction being considered to be longitudinal. The hopper 400 is moved in both directions by means of some moving structure on the traveling assembly 300.

The hopper 400 and the walking assembly 300 are made of metal parts. Since the temperature in the furnace cover 200 is high and the parts made of rubber or plastic cannot adapt to a high-temperature environment for a long time, the parts constituting the hopper 400 and the traveling unit 300 may be made of aluminum alloy or steel. The hopper 400 may be operated in the furnace cover 200 all the time, or may be received outside the furnace cover 200 and then fed into the furnace cover 200. The walking assembly 300 may be partially placed within the furnace housing 200 to ensure that the hopper 400 can reach any position on a plane above the top of the furnace 100.

According to the automatic feeding glass melting furnace 100 provided by the invention, the hopper 400 and the walking component 300 are arranged in the furnace cover 200, the hopper 400 moves in a plane parallel to the top end face of the melting furnace 100 in the furnace cover 200 by virtue of the walking component 300, glass frit can be conveyed to any position of the top end face of the melting furnace 100 through the hopper 400, molten glass is shielded in time, and the phenomenon of red top is avoided for a long time.

Optionally, in an embodiment of the present application, as shown in fig. 1, the walking assembly 300 includes a cross beam 310, a walking base 320, a bracket 330, and a driving part 340, one end of the cross beam 310 is connected to the walking base 320, the driving part 340 is disposed on the walking base 320, the walking base 320 is disposed on the bracket 330 and can move on the bracket 330 along a first direction; the driving part 340 is respectively in transmission connection with the walking base 320 and the hopper 400, the driving part 340 can drive the hopper 400 to move on the cross beam 310, and the length direction of the cross beam 310 is a second direction; the other end of the cross member 310 is movably connected to an inner side wall of the furnace cover 200 opposite to the bracket 330.

The beam 310 is used for carrying the hopper 400, and can drive the hopper 400 to move in a first direction, specifically realized by the walking base 320. One end of the beam 310 is connected to the walking base 320, and the beam 310 can reciprocate in a first direction when the walking base 320 moves on the bracket 330. The other end of the cross beam 310 is movably connected to the side wall of the furnace cover 200, and can be clamped into a groove arranged on the side wall of the furnace cover 200, so that the cross beam 310 is supported and the cross beam 310 is allowed to move along the first direction. Further, since the hopper 400 is movable on the cross member 310, that is, in the second direction, the hopper 400 can reach any position in a certain plane by the cooperation of the cross member 310, the traveling base 320, and the driving unit 340, and the glass frit can be poured.

Optionally, in a specific implementation manner of an embodiment of the application of the present invention, as shown in fig. 1, the hopper 400 includes a connecting seat 410, a pulling rope 420, and a hopper body 430 that can be opened and closed, the connecting seat 410 is movably disposed on the cross beam 310, a threaded through hole (not identified in the figure) is disposed on the connecting seat 410, a lead screw 311 is disposed on the cross beam 310, and the lead screw 311 is disposed in the threaded through hole in a penetrating manner; the lead screw 311 and the traction rope 420 are in transmission connection with the driving part 340; the bucket body 430 is fixedly connected to the connecting seat 410, and the traction rope 420 is connected with the bucket body 430. The bucket body 430 of the hopper 400 can adopt a common grab bucket, and specifically comprises a containing space formed by two or more bucket-shaped jaws which can be opened and closed together, wherein the jaws are closed in a glass frit pile during charging, the glass frit is grabbed into the containing space, the jaws are opened in a suspended state above the glass melt during discharging, the glass frit is scattered on the glass melt, and the opening and closing of the jaws are controlled by a traction rope 420 driven by a driving part 340. By providing the lead screw 311 on the cross member 310 such that the lead screw 311 is parallel to the cross member 310, the bucket body 430 can be driven to move when the lead screw 311 is rotated.

Optionally, the driving part 340 includes a first driving part 341, a second driving part 342, and a third driving part 343; the first driving unit 341 is configured to drive the traveling base 320 to move on the support 330; the second driving part 342 is in transmission connection with the cross beam 310 and is used for driving the cross beam 310 to rotate; the third driving part 343 is connected to the traction rope 420 for drawing the traction rope 420. The driving unit 340 may be a motor, but may be adapted to different power connection objects, and may further need a pulley, a transmission, or other parts.

Alternatively, in another specific implementation of an embodiment of the present application, as shown in fig. 1, the cross beam 310 is located inside the furnace housing 200, and the support 330 is located outside the furnace housing 200. The cross beam 310 of the walking component 300 is arranged in the furnace cover 200, so that the hopper 400 can be ensured to freely convey glass frits, the bracket 330 is arranged outside the furnace cover 200, namely, the driving part 340 can be correspondingly arranged outside the furnace cover 200, and the influence of high temperature can be avoided under the condition that high-temperature prevention measures are not needed.

Optionally, in another specific implementation manner of an embodiment of the present application, as shown in fig. 1, a guide rail 210 and a slider 230 are disposed on an inner side wall of the furnace cover 200, and the slider 230 is disposed in the guide rail 210 and can move along the guide rail 210; the beam 310 is attached to the slider 230. The guide rail 210 and the slider 230 are disposed on the inner side wall, and a ball (not shown) may be disposed between the slider 230 and the guide rail 210 to reduce friction therebetween, thereby facilitating movement of the slider 230. The connection of the slider 230 to the beam 310 enables the beam 310 to be better supported and move more smoothly in the first direction. The lead screw 311 may also be connected to the slider 230, pivotally connected to the slider 230.

Alternatively, in another embodiment of the present application, as shown in fig. 2 and 3, the top end surface of the furnace cover 200 is provided with three baffles 240, and the baffles 240 form a rectangular parallelepiped space with one side open at the top end surface of the furnace cover 200; a movable piston plate 250 is also arranged in the cuboid space, and two sides of the piston plate 250 abut against the two side baffles 240 of the cuboid space.

In the production process of glass products, a large amount of recovered cullet is often used, the cullet is washed by water, a large amount of water is inevitably remained in the cullet, and if the cullet is directly fed into molten glass in a molten state, more heat is consumed, explosion points possibly occur, and safety is affected. Although the furnace cover 200 is made of a heat insulating material to minimize heat loss, the furnace cover 200 itself is heated and dissipated to the surrounding environment, and a part of the heat in the furnace 100 is inevitably wasted. The top end face of the furnace cover 200 is provided with a cuboid space capable of containing a part of glass materials by means of the three baffles 240, the top end face of the furnace cover 200 can be made of heat-conducting materials such as steel plates or aluminum plates, and the cleaned glass materials are temporarily placed in the cuboid space for a period of time, so that the glass materials are preliminarily heated, and evaporation of water in the glass materials is accelerated.

Optionally, in some specific implementations of another embodiment of the present application, as shown in fig. 2 and 3, a hopper opening 210 is provided on a side wall of the furnace cover 200 parallel to the second direction, and the hopper 400 can enter and exit the furnace cover 200 through the hopper opening 210; the side wall is provided with a flow guiding box 260, the top end of the flow guiding box 260 corresponds to the opening of the rectangular space, and the bottom end opening of the flow guiding box 260 can be butted with the hopper 400. After the glass frit is primarily dried, the glass frit can be pushed down from the top end surface of the furnace cover 200 at a certain speed by the piston plate 250 and fall to a set position, and when the diversion box 260 is not arranged, the glass frit can fall out of the glass melting furnace 100 to form a material pile, and the diversion box 260 is arranged to directly feed the dried glass frit into the hopper 400, provided that the hopper 400 is already butted with the bottom end opening of the diversion box 260 before the glass frit is pushed down. In this case, the hopper 400 may be moved to the outside of the furnace housing 200, and accordingly, the bracket 330 may have a length to support the movement of the hopper 400 to the outside of the furnace housing 200, and a corresponding outlet may be provided on the furnace housing 200.

It will be appreciated by those skilled in the art that the terms "first", "second" and "first" have been discussed herein for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicit to any number of technical features being indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present application, "a plurality" means two or more unless otherwise specified.

In the description of the present application, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in this application will be understood to be a specific case for those of ordinary skill in the art.

In the description herein, particular features, structures, materials, or characteristics may be combined in any suitable manner in any one or more embodiments or examples.

The foregoing is only a partial embodiment of the present application, and it should be noted that, for those skilled in the art, several modifications and decorations can be made without departing from the principle of the present application, and these modifications and decorations should also be regarded as the protection scope of the present application.

Claims (7)

1. An automatic charging glass melting furnace is characterized by comprising a melting furnace, a furnace cover, a walking assembly and a hopper; the furnace cover is arranged at the top end of the smelting furnace; the top end face of the furnace cover is provided with three baffles, and the baffles form a cuboid space with an opening at one side on the top end face of the furnace cover; a movable piston plate is further arranged in the cuboid-shaped space, and two sides of the piston plate abut against the baffle plates on two sides of the cuboid-shaped space;

the hopper is arranged on the walking assembly, the hopper can move in a first direction and a second direction which are perpendicular to each other in the furnace cover under the driving of the walking assembly, and the plane where the first direction and the second direction are located is parallel to the top end surface of the smelting furnace; the hopper can be driven by the walking assembly to open or close;

the hopper and the walking assembly are both parts made of metal materials.

2. The automatic charging glass melting furnace of claim 1, wherein the traveling assembly includes a beam, a traveling base, a support, and a driving portion, one end of the beam being connected to the traveling base, the driving portion being provided on the traveling base, the traveling base being provided on the support and being movable in the first direction on the support; the driving part is in transmission connection with the walking base and the hopper respectively, the driving part can drive the hopper to move on the cross beam, and the length direction of the cross beam is the second direction; the other end of the cross beam is movably connected to the inner side wall, opposite to the support, of the furnace cover.

3. The automatic charging glass melting furnace according to claim 2, wherein the hopper comprises a connecting seat, a traction rope and a hopper body capable of being opened and closed, the connecting seat is movably arranged on the cross beam, a threaded through hole is formed in the connecting seat, a lead screw is arranged on the cross beam, and the lead screw is arranged in the threaded through hole in a penetrating manner; the lead screw and the traction rope are in transmission connection with the driving part; the bucket body is fixedly connected to the connecting seat, and the traction rope is connected with the bucket body.

4. The automatic feed glass melting furnace of claim 3, wherein the drive section comprises a first drive section, a second drive section, and a third drive section;

the first driving part is used for driving the walking base to move on the bracket;

the second driving part is in transmission connection with the lead screw and is used for driving the lead screw to rotate;

the third driving part is connected with the traction rope and used for traction the traction rope.

5. The automatic charging glass furnace of claim 2, wherein the cross beam is located within the furnace enclosure and the brackets are located outside the furnace enclosure.

6. The automatic charging glass furnace of claim 2, wherein the furnace mantle has guide rails and slide blocks on the inner side walls, the slide blocks being disposed in the guide rails and movable along the guide rails; the cross beam is connected to the sliding block.

7. The automatic charging glass furnace of claim 1, wherein a hopper opening is provided in a side wall of the furnace enclosure parallel to the second direction, the hopper being movable into and out of the furnace enclosure through the hopper opening; the side wall is provided with a flow guide box, the top end of the flow guide box corresponds to the opening of the rectangular space, and the bottom opening of the flow guide box can be in butt joint with the hopper.

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