CN115477461A - Glass kiln structure without reversing - Google Patents

Abstract

The invention discloses a reversing-free glass kiln structure, which relates to the technical field of glass kiln manufacture and comprises a kiln body, channel modules, a flue gas channel, a chimney, a high-temperature gas channel, air channel flashboard modules and flue gas channel flashboard modules, wherein two channel modules are arranged on two sides of the bottom of the kiln body, one end of each channel module is connected with the chimney through a flue gas channel, the other ends of the two channel modules and the high-temperature gas channel are connected with flame port modules on two sides of the kiln body, the two channel modules are connected with the flue gas flashboard modules on two sides of the kiln body, one end of each channel module is provided with a flue gas channel flashboard module, and the other end of each channel module is provided with an air channel flashboard module. The flame and the flue gas in the whole kiln structure are not reversed, the flame is sent into the kiln body through the flame ports on the two sides, the flue gas is sent into the chimney through the flue gas ports on the two sides, and the process requirements of glass production can be met by the flame in the kiln structure on the premise of no reversing.

Description

Glass kiln structure without reversing

Technical Field

The invention relates to the technical field of glass kiln manufacturing, in particular to a reversing-free glass kiln structure.

Background

The kiln is the core of glass production, and traditional kiln need preheat gas and combustion air in order to satisfy the requirement of glass production technology, in order to reach the requirement of preheating, the kiln production need be reversed, every 20 minutes, the flame of unilateral burning switches to the contralateral. Although the method can meet the requirements of glass production, the method has great disadvantages on the service life of the kiln, the quality of the glass and the energy consumption of the production.

Disclosure of Invention

The invention aims to provide a reversing-free glass kiln structure which is used for solving the technical problem.

The technical scheme adopted by the invention is as follows:

the utility model provides a no switching-over glass kiln structure, includes kiln body, passageway module, flue gas passageway, chimney, high temperature gas passageway, air channel flashboard module and flue gas passageway flashboard module, kiln body bottom both sides are equipped with two the passageway module, each the one end of passageway module is respectively through one the flue gas passageway with the chimney is connected, two the other end of passageway module and the high temperature gas passageway with the flame mouth module of kiln body both sides is connected, two the passageway module with the flue gas bush group of kiln body both sides is connected, each the one end of passageway module is equipped with one respectively the flue gas passageway flashboard module, each the other end of passageway module is equipped with one respectively the air channel flashboard module.

Preferably, each channel module comprises an upper channel and a lower channel arranged at the lower end of the upper channel.

As a further preferred option, each air channel shutter module comprises an air channel upper shutter and an air channel lower shutter, the air channel upper shutter is disposed in the upper channel, and the air channel lower shutter is disposed in the lower channel.

Preferably, each flue gas channel gate plate module comprises an upper flue gas channel gate plate arranged in the upper channel and a lower flue gas channel gate plate arranged in the lower channel.

Preferably, the burner further comprises an air channel and a combustion air branch channel, the other ends of the upper channel and the lower channel are connected with the combustion air branch channel through the air channel, and the combustion air branch channel is connected with the flame vent module.

As a further optimization, the device further comprises a combustion-supporting air channel, a combustion-supporting air upper channel, a combustion-supporting air lower channel, a combustion-supporting air upper channel valve and a combustion-supporting air lower channel valve, wherein one end of the combustion-supporting air upper channel and one end of the combustion-supporting air lower channel are respectively connected with the combustion-supporting air channel, the other end of the combustion-supporting air upper channel is connected with the upper channel, the other end of the combustion-supporting air lower channel is connected with the lower channel, the combustion-supporting air upper channel valve is arranged on the combustion-supporting air upper channel, and the combustion-supporting air lower channel valve is arranged on the combustion-supporting air lower channel.

Preferably, the gas burner further comprises a high-temperature gas branch channel, and the high-temperature gas branch channel is connected with the flame vent module through the high-temperature gas branch channel.

Preferably, the flue gas processing device further comprises a flue gas branch channel, one end of the flue gas branch channel is communicated with the upper channel and the lower channel, and the other end of the flue gas branch channel is connected with the flue gas port module.

As further preferred, still include the branch flue gas passageway flashboard module, the branch flue gas passageway one end is inside to be equipped with the branch flue gas passageway flashboard module.

As a further preferred, the flue gas props up the passageway flashboard module and includes that the flue gas props up flashboard and flue gas and props up flashboard under the passageway, the last flashboard of flue gas props up the passageway and locates in the flue gas props up the passageway just right the position of passageway upward, the flue gas props up the passageway and locates the flue gas props up the interior just right of passageway down the position of passageway in the passageway.

The technical scheme has the following advantages or beneficial effects:

in the invention, the flame and the flue gas in the whole kiln structure are not reversed, the flame is sent into the kiln body through the flame ports on the two sides, the flue gas is sent into the chimney through the flue gas ports on the two sides, and the flame in the kiln structure can meet the process requirements of glass production on the premise of no reversing, thereby prolonging the service life of the kiln and improving the quality of glass.

Drawings

FIG. 1 is a schematic view of the general layout of a non-reversing glass kiln construction according to the invention;

FIG. 2 is a schematic view showing the connection of combustion air passage portions in the present invention;

FIG. 3 is a schematic view of the connection between the flue gas channel section and the channel module of the present invention;

FIG. 4 is a schematic view of the connection of the flue gas channel portion to the kiln body in the present invention;

FIG. 5 is a schematic view of the connection between the high temperature gas channel part and the kiln body in the present invention;

FIG. 6 isbase:Sub>A sectional view taken along line A-A of FIG. 1;

FIG. 7 is a sectional view taken along line B-B of FIG. 1;

FIG. 8 is a sectional view taken along line C-C of FIG. 1;

FIG. 9 is a sectional view taken along line D-D of FIG. 1;

fig. 10 is a sectional view taken along line E-E in fig. 1.

In the figure: 1. a kiln body; 2. a channel module; 201. an upper channel; 202. a lower channel; 3. a flue gas channel; 4. a chimney; 5. a high temperature gas channel; 6. an air channel shutter module; 601. an upper gate plate of the air passage; 602. an air channel lower gate plate; 7. a flue gas channel gate plate module; 701. the upper flashboard of the flue gas channel; 702. a lower gate plate of the flue gas channel; 8. a flame vent; 9. a flue gas port; 10. an air passage; 11. a combustion air branch passage; 12. a combustion air passage; 13. a combustion air upper passage; 14. a combustion air lower channel; 15. a combustion air upper passage valve; 16. a combustion air lower passage valve; 17. a high temperature gas branch channel; 18. a flue gas branch channel; 19. a gate plate is arranged on the smoke branch channel; 20. a lower gate plate of the smoke branch channel; 21. a flue gas branch channel flashboard module.

Detailed Description

The technical solutions of the present invention will be described clearly and completely with reference to the accompanying drawings, and it should be understood that the described embodiments are some, but not all embodiments of the present invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the description of the present invention, it should be noted that, as the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc. appear, their indicated orientations or positional relationships are based on those shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" as appearing herein are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it should be noted that, unless otherwise explicitly stated or limited, the terms "mounted," "connected," and "connected" should be interpreted broadly, e.g., as being fixed or detachable or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

FIG. 1 is a schematic view of the general layout of a non-reversing glass kiln construction according to the invention; FIG. 2 is a schematic view showing the connection of combustion air passage portions in the present invention; FIG. 3 is a schematic view of the connection between the flue gas channel section and the channel module of the present invention; FIG. 4 is a schematic view of the connection of the flue gas channel portion to the kiln body in the present invention; FIG. 5 is a schematic view of the connection between the high temperature gas channel part and the kiln body in the present invention; FIG. 6 isbase:Sub>A sectional view taken along line A-A of FIG. 1; FIG. 7 is a sectional view taken along line B-B of FIG. 1; FIG. 8 is a sectional view taken along line C-C of FIG. 1; FIG. 9 is a sectional view taken along line D-D of FIG. 1; fig. 10 is a sectional view taken along line E-E of fig. 1, and referring to fig. 1-10, a preferred embodiment is shown.

In the present application, referring to fig. 2, the combustion air channel 12 includes an air channel 10, a combustion air branch channel 11, a combustion air channel 12, a combustion air upper channel 13, a combustion air lower channel 14, a combustion air upper channel valve 15, and a combustion air lower channel valve 16;

referring to fig. 3, the flue gas channel part comprises a flue gas channel 3, a flue gas branch channel 18, a flue gas branch channel upper gate plate 19 and a flue gas branch channel lower gate plate 20;

referring to fig. 5, the high temperature gas passage portion includes a high temperature gas passage 5 and a high temperature gas branch passage 17.

The utility model provides a no switching-over glass kiln structure, including kiln body 1, passageway module 2, flue gas channel 3, chimney 4, high temperature gas passageway 5, air channel flashboard module 6 and flue gas channel flashboard module 7, 1 bottom both sides of kiln body are equipped with two passageway modules 2, the one end of each passageway module 2 is connected with chimney 4 through a flue gas channel 3 respectively, the other end of two passageway modules 2 and high temperature gas passageway 5 are connected with the flame mouth module of 1 both sides of kiln body, two passageway modules 2 are connected with the flue gas bush module of 1 both sides of kiln body, the one end of each passageway module 2 is equipped with a flue gas channel flashboard module 7 respectively, the other end of each passageway module 2 is equipped with an air channel flashboard module 6 respectively. In this embodiment, as shown in fig. 1-3, two channel modules 2 are disposed on the left and right sides of the bottom of the kiln body 1, and the high-temperature gas channel 5 is also disposed on the two sides of the kiln body 1, wherein the channel modules 2 are communicated with the flue gas channel 3, the flue gas channel 3 is communicated with the chimney 4, the high-temperature gas channel 5 is communicated with the flame vent modules on the two sides of the kiln body 1, the flame vent modules on the left side of the kiln body 1 and the right side of the kiln body 1 respectively include a plurality of flame vents 8, the left high-temperature gas channel 5 is communicated with the left flame vents 8, the right side high-temperature gas channel 5 is communicated with the right side flame vents 8, the left high-temperature gas channel 5 is communicated with the left flame vents 8, and each flame vent 8 has two air inlets, which can be specifically shown in fig. 7. The high-temperature gas channel 5 is used for providing high-temperature gas to a flame port 8 of the kiln body 1. The gas port module on the kiln body 1 is distributed on the left side and the right side of the kiln body 1, and the gas port module comprises a plurality of gas ports 9.

Further, as a preferred embodiment, each channel module 2 includes an upper channel 201 and a lower channel 202 disposed at the lower end of the upper channel 201. Referring to fig. 9 and 10, the upper channel 201 and the lower channel 202 are arranged side by side up and down.

Further, as a preferred embodiment, each air channel shutter module 6 includes an air channel upper shutter 601 and an air channel lower shutter 602, the air channel upper shutter 601 is disposed in the upper channel 201, and the air channel lower shutter 602 is disposed in the lower channel 202. Referring to fig. 9, the lower damper 602 of the air channel is used for controlling the opening or closing of the other end of the lower channel 202, and the upper damper 601 of the air channel is used for controlling the opening or closing of the other end of the upper channel 201, so as to control the entry of combustion air into the kiln body 1.

Further, as a preferred embodiment, each flue gas channel shutter module 7 comprises a flue gas channel upper shutter 701 disposed in the upper channel 201 and a flue gas channel lower shutter 702 disposed in the lower channel 202. Referring to fig. 10, the upper damper 701 of the flue gas channel is used for controlling the opening or closing of one end of the upper channel 201, and the lower damper 702 of the flue gas channel is used for controlling the opening or closing of one end of the lower channel 202, so as to control the flue gas to enter the chimney 4.

Further, as a preferred embodiment, the combustion-supporting device further comprises an air channel 10 and a combustion-supporting air branch channel 11, the other ends of the upper channel 201 and the lower channel 202 are connected with the combustion-supporting air branch channel 11 through the air channel 10, and the combustion-supporting air branch channel 11 is connected with the flame vent module. Referring to fig. 2, the other end of the upper channel 201 and the other end of the lower channel 202 are communicated with the air channel 10, and the air channel 10 is provided with a plurality of combustion air branch channels 11, and the combustion air branch channels 11 are communicated with the flame ports 8. The combustion air in the upper channel 201 or the lower channel 202 of one channel module 2 enters the flame ports 8 from the air channel 10 and the combustion air branch channel 11. The flue gas generated by combustion in the kiln body 1 enters the upper channel 201 or the lower channel 202 in the other channel module 2 from the flue gas port 9 on one side of the kiln body 1, and then enters the chimney 4 from the flue gas channel 3.

Further, as a preferred embodiment, the combustion-supporting air conditioning system further comprises a combustion-supporting air channel 12, an upper combustion-supporting air channel 13, a lower combustion-supporting air channel 14, an upper combustion-supporting air channel valve 15 and a lower combustion-supporting air channel valve 16, wherein one end of the upper combustion-supporting air channel 13 and one end of the lower combustion-supporting air channel 14 are respectively connected with the combustion-supporting air channel 12, the other end of the upper combustion-supporting air channel 13 is connected with the upper channel 201, the other end of the lower combustion-supporting air channel 14 is connected with the lower channel 202, the upper combustion-supporting air channel 13 is provided with the upper combustion-supporting air channel valve 15, and the lower combustion-supporting air channel 14 is provided with the lower combustion-supporting air channel valve 16. In this embodiment, referring to fig. 2, the combustion air passage 12, the combustion air upper passage 13, and the combustion air lower passage 14 are provided at one end of the passage module 2. The combustion air upper channel 13 and the combustion air lower channel 14 are both communicated with the combustion air channel 12, the combustion air upper channel 13 is communicated with the upper channel 201, the combustion air lower channel 14 is communicated with the lower channel 202, the combustion air upper channel valve 15 is used for controlling the opening or closing of the combustion air upper channel 13, and the combustion air lower channel valve 16 is used for controlling the opening or closing of the combustion air lower channel 14, so that the combustion air can enter the upper channel 201 or the lower channel 202 conveniently.

Further, as a preferred embodiment, still include the branch passageway 17 of high temperature gas, high temperature gas passageway 5 is connected with the flame vent module through branch passageway 17 of high temperature gas. Referring to fig. 5, two high-temperature gas channels 5 are provided and located on two sides of the kiln body 1, the high-temperature gas channels 5 are communicated with a high-temperature gas branch channel 17, and the high-temperature gas branch channel 17 is communicated with the flame ports 8. The high-temperature fuel gas enters the high-temperature fuel gas branch channel 17 from the high-temperature fuel gas channel 5 and enters the flame port 8 from the high-temperature fuel gas branch channel 17. Referring to fig. 7, the high temperature gas channel 5 is located at the lower side of the air channel 10, and the high temperature gas branch channel 17 and the combustion air branch channel 11 respectively face an air inlet of the flame ports 8.

Further, as a preferred embodiment, the flue gas processing device further comprises a flue gas branch channel 18, one end of the flue gas branch channel 18 is communicated with the upper channel 201 and the lower channel 202, and the other end of the flue gas branch channel 18 is connected with the flue gas port module. In this embodiment, referring to fig. 3 and 4, the flue gas branch channel 18 is communicated with the flue gas port 9 on the kiln body 1, the upper channel 201 and the lower channel 202, and flue gas in the kiln body 1 enters the flue gas branch channel 18 from the flue gas port 9 into the upper channel 201 or the lower channel 202, and then enters the chimney 4.

Further, as a preferred embodiment, the flue gas branch channel gate module 21 is further included, and the flue gas branch channel gate module 21 is arranged inside one end of the flue gas branch channel 18.

Further, as a preferred embodiment, the flue gas branch channel gate plate module 21 includes a flue gas branch channel upper gate plate 19 and a flue gas branch channel lower gate plate 20, the flue gas branch channel upper gate plate 19 is disposed in the flue gas branch channel 18 at a position opposite to the upper channel 201, and the flue gas branch channel lower gate plate 20 is disposed in the flue gas branch channel 18 at a position opposite to the lower channel 202. Referring to fig. 6, when the lower shutter 20 of the smoke branch channel is opened, the smoke in the smoke branch channel 18 can enter the lower channel 202, and when the upper shutter 19 of the smoke branch channel is opened, the smoke can enter the upper channel 201.

In the embodiment, high-temperature gas with various components is used as fuel, and high-temperature coal gas generated by entrained flow coal gas is used; all the combustion air channels 12 and the flue gas channels 3 adopt a lattice body structure, and the flue gas and the combustion air exchange heat in the lattice body; all the high-temperature gas channels 5 are made of heat-resistant steel, heat-resistant bricks and other materials; the flame and the flue gas in the whole kiln are not reversed, the flame is sent into the kiln through the flame ports 8 on the left side and the right side, and the flue gas is sent into the chimney 4 through the flue gas ports 9 on the left side and the right side of the kiln body 1.

When the combustion-supporting air burner is used, a small furnace on the right is taken as an example for explanation, during normal combustion, combustion-supporting air enters from the combustion-supporting air passage 12 on the right, the combustion-supporting air upper passage valve 15 on the right is opened, the combustion-supporting air lower passage valve 16 on the right is closed, the flue gas passage upper flashboard 701 on the right is closed (the flue gas passage lower flashboard 702 is opened), combustion-supporting air is sent into the upper passage 201 on the right from the combustion-supporting air upper passage 13 on the right, the flue gas passage upper flashboard 601 on the right is opened (the flue gas passage lower flashboard 602 is closed), combustion-supporting air enters into the air passage 10 on the right, and is sent into the flame port 8 on the right through the combustion-supporting air branch passage 11 on the right.

The high-temperature fuel gas can be fed through the right high-temperature fuel gas channel 5 and fed into the right flame port 8 through the right high-temperature fuel gas branch channel 17. The flue gas after burning is discharged through the left flue gas port 9, and is sent into the left lower channel 202 through the left flue gas branch channel 18, the left flue gas branch channel lower gate plate 20 is opened (the flue gas branch channel upper gate plate 19 is closed), the left flue gas channel lower gate plate 702 is opened (the flue gas channel upper gate plate 701 is closed), and the flue gas is sent into the chimney 4 through the left flue gas channel 3.

After twenty minutes of combustion, the lower combustion air channel valve 16 on the right side is opened, the upper combustion air channel valve 15 on the right side is closed, the lower flue gas channel damper 702 on the right side is closed (the upper flue gas channel damper 701 is opened), combustion air is fed into the lower right channel 202 from the lower right combustion air channel 14, the lower right air channel damper 602 is opened (the upper air channel damper 601 is closed), combustion air enters the right air channel 10, flame continues to burn, the burned flue gas is still discharged through the left flue gas port 9 and fed into the left upper channel 201 through the left flue gas branch channel 18, the upper left flue gas branch channel damper 19 is opened (the lower flue gas branch channel damper 20 is closed), then the flue gas is fed into the chimney 4 through the left flue gas channel 3, and the control mode of the left small furnace is the same as that of the right small furnace.

Because the traditional kiln adopts a mode of discontinuous reversing production, flame can stop once every twenty minutes, the flame stop time exceeds two minutes, during the flame stop period, the temperature in the kiln is reduced, the structural service life of the kiln is seriously influenced, glass production is a continuous process, the temperature control in the kiln is strict, during the reversing period, because the flame stops, the heating of glass liquid is stopped, the flowing state of the glass liquid in the kiln is changed, the quality of the glass can be influenced, secondly, no external heat heats the kiln during the reversing period, the whole kiln is a heat dissipation process, after twenty minutes, in order to reach the previous working condition, the required energy can be larger than the energy required by the stable flame heating kiln, the whole energy consumption of the kiln is improved, and the whole energy consumption of the glass production can also be improved. The glass kiln structure can meet the preheating requirement without reversing the flame and the flue gas combusted inside, can meet the glass production requirement, can prolong the service life of the kiln, improves the glass production quality, and can solve the problems that the service life of the kiln is influenced, the glass production quality is influenced, and the energy consumption is high due to frequent and discontinuous reversing of the transmission kiln.

While the invention has been described with reference to a preferred embodiment, it will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the invention.

Claims (10)

1. The utility model provides a no switching-over glass kiln structure, its characterized in that includes kiln body, passageway module, flue gas passageway, chimney, high temperature gas passageway, air channel flashboard module and flue gas passageway flashboard module, kiln body bottom both sides are equipped with two the passageway module, each the one end of passageway module is respectively through one the flue gas passageway with the chimney is connected, two the other end of passageway module and high temperature gas passageway with the flame mouth module of kiln body both sides is connected, two the passageway module with the flue gas mouthing module of kiln body both sides is connected, each the one end of passageway module is equipped with one respectively the flue gas passageway flashboard module, each the other end of passageway module is equipped with one respectively the air channel flashboard module.

2. The reversing-free glass furnace structure of claim 1, wherein each of the channel modules includes an upper channel and a lower channel disposed at a lower end of the upper channel.

3. The non-reversing glass kiln structure according to claim 2, wherein each air channel ram module includes an upper air channel ram and a lower air channel ram, the upper air channel ram being disposed in the upper channel and the lower air channel ram being disposed in the lower channel.

4. The non-reversing glass kiln structure according to claim 2, wherein each flue gas channel damper module comprises an upper flue gas channel damper disposed in the upper channel and a lower flue gas channel damper disposed in the lower channel.

5. The reversing-free glass kiln structure as defined in claim 2, further comprising an air passage and a combustion air branch passage, the other ends of the upper passage and the lower passage being connected to the combustion air branch passage through the air passage, the combustion air branch passage being connected to the flame port module.

6. The non-reversing glass kiln structure according to claim 2, further comprising a combustion air channel, an upper combustion air channel, a lower combustion air channel, an upper combustion air channel valve, and a lower combustion air channel valve, wherein one end of the upper combustion air channel and one end of the lower combustion air channel are connected to the combustion air channel, respectively, the other end of the upper combustion air channel is connected to the upper channel, the other end of the lower combustion air channel is connected to the lower channel, the upper combustion air channel is provided with the upper combustion air channel valve, and the lower combustion air channel is provided with the lower combustion air channel valve.

7. The reversing-free glass kiln structure of claim 1, further comprising a high temperature gas branch passage, wherein the high temperature gas branch passage is connected to the flame vent module through the high temperature gas branch passage.

8. The non-reversing glass kiln structure according to claim 2, further comprising a branch flue gas channel, one end of the branch flue gas channel being in communication with the upper channel and the lower channel, the other end of the branch flue gas channel being connected to the flue gas die set.

9. The reversing-free glass kiln structure according to claim 8, further comprising a flue gas branch channel gate plate module, wherein the flue gas branch channel gate plate module is arranged inside one end of the flue gas branch channel.

10. The reversing-free glass kiln structure as defined in claim 9, wherein the flue gas branch channel gate plate module comprises a flue gas branch channel upper gate plate and a flue gas branch channel lower gate plate, the flue gas branch channel upper gate plate is disposed in the flue gas branch channel at a position facing the upper channel, and the flue gas branch channel lower gate plate is disposed in the flue gas branch channel at a position facing the lower channel.

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