A reverberatory furnace combustion chamber based on zinc product processing

By designing the combustion chamber of the reverberatory furnace for zinc product processing, and using the combined drive components to move the combustion-supporting and dust removal components, the problem of impurity blockage in the zinc product reverberatory furnace was solved, achieving efficient combustion and dust removal, and avoiding equipment blockage.

CN116241901BActive Publication Date: 2026-06-09HENGYANG DAYU ZINC IND CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
HENGYANG DAYU ZINC IND CO LTD
Filing Date
2022-12-16
Publication Date
2026-06-09

AI Technical Summary

Technical Problem

When zinc products are reacted in a reverberatory furnace, the furnace body contains many impurities, which can easily clog the heat exchanger and cause the exhaust mechanism to become easily blocked, preventing the reaction from proceeding smoothly.

Method used

A reverberatory furnace combustion chamber based on zinc product processing is designed, comprising a reverberatory furnace combustion body, a dust removal and combustion assist assembly, and a waste heat utilization component. The combustion assist assembly and dust removal assembly are driven by the drive component of the assembly to improve combustion efficiency and dust removal efficiency and avoid device blockage.

Benefits of technology

It improves combustion efficiency and dust removal efficiency, avoids clogging of the device, and ensures smooth reaction.

✦ Generated by Eureka AI based on patent content.

Smart Images

  • Figure CN116241901B_ABST
    Figure CN116241901B_ABST
Patent Text Reader

Abstract

The application is suitable for the technical field of metal smelting, and provides a reverberatory combustion chamber based on zinc product processing, which solves the problem that the exhaust mechanism is easily blocked because of the many impurities in the furnace body and the easy blockage of the heat exchanger when zinc products react in the reverberatory. The reverberatory combustion chamber comprises a reverberatory combustion main body, the reverberatory combustion main body comprises a combustion seat, and a combustion cavity is arranged in the combustion seat. A dust removal combustion combination part is arranged in the combustion cavity, and the dust removal combustion combination part comprises a combination part driving element, a combination combustion assembly fixedly connected with the combination driving element, a combination combustion assembly for injecting combustion-supporting gas into the combustion cavity, and a combination dust removal assembly. The combination part driving element, the combination combustion assembly and the combination dust removal assembly are arranged in the application, the combination combustion assembly is driven to move by the rotation of the combination combustion assembly, the contact area between the combination dust removal assembly and the dust generated during combustion is increased, the dust removal efficiency is improved, and the blockage of the device is avoided.
Need to check novelty before this filing date? Find Prior Art

Description

Technical Field

[0001] This invention belongs to the field of metal smelting technology, and particularly relates to a reverberatory furnace combustion chamber based on zinc product processing. Background Technology

[0002] A reverberatory furnace, also known as a flame reverberatory furnace, is a metallurgical furnace that directly heats materials with a flame to smelt metals. It consists of three main parts: a combustion chamber, a smelting chamber, and an exhaust flue. Reverberatory furnaces have a simple structure, low investment, and can use a wide variety of fuels, making them an important smelting equipment for non-ferrous metals such as copper, nickel, and tin.

[0003] In the zinc product processing, the reverberatory furnace is also an important piece of equipment. However, when zinc products react in the reverberatory furnace, there are many impurities inside the furnace, which can easily clog the heat exchanger and make the exhaust mechanism easily blocked, thus preventing the reaction from proceeding smoothly. In order to solve the above problems, we propose a reverberatory furnace combustion chamber based on zinc product processing. Summary of the Invention

[0004] This invention provides a reverberatory furnace combustion chamber based on zinc product processing, aiming to solve the problem that when zinc products react in a reverberatory furnace, there are many impurities in the furnace body, which easily clog the heat exchanger and make the exhaust mechanism easily clogged.

[0005] In the zinc product processing, the reverberatory furnace is also an important piece of equipment. However, when zinc products react in the reverberatory furnace, there are many impurities inside the furnace, which easily clog the heat exchanger and cause the exhaust mechanism to become blocked, preventing the reaction from proceeding smoothly. To solve the above problems, we propose a reverberatory furnace combustion chamber based on zinc product processing. The reverberatory furnace combustion chamber based on zinc product processing includes: a reverberatory furnace combustion body, which includes a combustion seat and a combustion chamber disposed within the combustion seat; a dust removal and combustion assist assembly disposed within the combustion chamber, which includes: an assembly drive component, a combined combustion assist component fixedly connected to the assembly drive component, the combined combustion assist component being used to inject combustion assist gas into the combustion chamber, and a combined dust removal component. During operation, zinc product raw materials are placed into the combustion chamber. Then, the drive mechanism of the assembly is activated, and combustion-supporting gas is injected into the combined combustion-supporting assembly. The activation of the drive mechanism rotates the combined combustion-supporting assembly, ensuring the combustion-supporting gas is evenly distributed within the combustion chamber, thus improving combustion efficiency. Simultaneously, the rotation of the combined flame-retardant assembly drives the combined dust removal assembly, increasing the contact area between the combined dust removal assembly and the dust generated during combustion, thereby improving dust removal efficiency and preventing clogging of the device. This application includes a drive mechanism, a combined combustion-supporting assembly, and a combined dust removal assembly. The rotation of the combined flame-retardant assembly drives the combined dust removal assembly, increasing the contact area between the combined dust removal assembly and the dust generated during combustion, thus improving dust removal efficiency and preventing clogging of the device.

[0006] This invention is implemented as follows: a reverberatory furnace combustion chamber based on zinc product processing, the reverberatory furnace combustion chamber based on zinc product processing comprising:

[0007] The reverberatory furnace combustion body includes a combustion seat, and a combustion chamber is provided inside the combustion seat;

[0008] A dust removal and combustion aid assembly is installed in the combustion chamber. The dust removal and combustion aid assembly is used to aid combustion during zinc product processing and to assist in the removal of dust from the flue gas after combustion.

[0009] The dust removal and combustion aid assembly includes:

[0010] The assembly drive unit is fixedly installed inside the combustion chamber;

[0011] A combined combustion-supporting assembly fixedly connected to the combined drive component, the combined combustion-supporting assembly is used to inject combustion-supporting gas into the combustion chamber and to purify the combustion-supporting gas;

[0012] A combined dust removal component is disposed inside the combustion chamber and connected to the combined combustion aid component for collecting impurities inside the combustion chamber.

[0013] Preferably, the combined combustion-supporting component includes:

[0014] Gas purification unit, used for the injection and purification of combustion-supporting gases;

[0015] A gas release section is connected to the gas purification section, and the gas release section is provided with multiple sets of gas release ports for releasing combustion-supporting gases.

[0016] Preferably, the gas purification unit includes:

[0017] The gas injection seat is rotatably connected to the gas release part via a bearing and is sleeved on the gas release part;

[0018] At least one set of gas purification seats is installed inside the gas injection seat and is in through communication with the gas release section.

[0019] At least one set of gas purification components is detachably installed inside the gas purification base for gas purification treatment.

[0020] Preferably, the combined dust removal assembly includes:

[0021] The dust removal component drive unit is fixedly connected to the gas release unit and is used to adjust the impurity adsorption position of the combined dust removal component;

[0022] A movable dust removal mechanism is connected to the dust removal component drive unit and is located inside the combustion chamber.

[0023] Preferably, the dust removal component drive unit includes:

[0024] The dust removal drive rod is fixedly connected to the gas release part;

[0025] A dust removal transmission rod is provided on one side of the dust removal drive rod. The dust removal transmission rod is hinged to the dust removal drive rod, and a dust removal transmission frame is fixedly connected to one end of the dust removal transmission rod.

[0026] At least one set of hinged push blocks is fixedly installed on the dust removal transmission frame, and the hinged push blocks are connected to the movable dust removal mechanism.

[0027] Preferably, the movable dust removal mechanism includes:

[0028] A dust removal mechanism hinge seat, wherein the interior of the dust removal mechanism hinge seat is hollow and is sleeved on the hinge push block;

[0029] The dust removal mechanism support is fixedly connected to the dust removal mechanism hinge seat, and one end of the dust removal mechanism support is rotatably connected to the combustion seat.

[0030] At least one set of dust adsorption seats, which are detachably installed on the dust removal mechanism support for adsorbing dust during combustion.

[0031] Preferably, it further includes an impurity recovery assembly for recovering combustion impurities, the impurity recovery assembly being installed within the combustion chamber, the impurity recovery assembly comprising:

[0032] An impurity recovery seat, wherein the impurity recovery seat is in through communication with the combustion chamber;

[0033] An impurity screening section is installed within the impurity recovery unit, and

[0034] A screening anti-clogging unit is used to prevent clogging of the impurity screening section. The screening anti-clogging unit is fixedly connected to the impurity screening section. The screening anti-clogging unit includes an anti-clogging drive and an anti-clogging lifting seat fixedly connected to the anti-clogging drive. The anti-clogging lifting seat is fixedly connected to the impurity screening section.

[0035] Preferably, the impurity screening unit includes:

[0036] The upper screening component is used to screen impurities after combustion.

[0037] A lower screening component is fixedly connected to the upper screening component. The lower screening component works in conjunction with the upper screening component to further screen impurities after combustion.

[0038] Preferably, it further includes a waste heat utilization component, which is disposed on one side of the combustion seat and communicates with the combustion chamber. The waste heat utilization component includes:

[0039] An air extraction pump is fixedly installed on the side wall of the combustion chamber, and the air extraction pump is in continuous communication with the combustion chamber.

[0040] The flue gas recovery tank is connected to the air extraction pump and fixed on the side wall of the combustion seat. The flue gas recovery tank is equipped with a flue gas recovery chamber.

[0041] Preferably, the waste heat utilization component further includes:

[0042] At least one set of flue gas diversion pipes are installed in the flue gas recovery chamber and are used for heat transfer of the flue gas after combustion.

[0043] At least one waste heat exchange seat is provided to assist in the transfer of heat in the flue gas;

[0044] A heat-absorbing sleeve, fitted onto the waste heat exchange base, is used for absorbing and exchanging waste heat in the flue gas.

[0045] A flue gas absorption box is installed in the flue gas recovery chamber. The flue gas absorption box is used to absorb the flue gas after combustion.

[0046] Compared with the prior art, the embodiments of this application have the following main advantages:

[0047] This application includes a combined drive component, a combined combustion-supporting component, and a combined dust removal component. The rotation of the combined flame-retardant component can drive the combined dust removal component to move, increasing the contact area between the combined dust removal component and the dust generated during combustion, improving dust removal efficiency, and preventing clogging of the device. Attached Figure Description

[0048] Figure 1 This is a schematic diagram of the structure of a reverberatory furnace combustion chamber based on zinc product processing, provided by the present invention.

[0049] Figure 2 This is a schematic diagram of the gas purification unit provided by the present invention.

[0050] Figure 3 This is a schematic diagram of the movable dust removal mechanism provided by the present invention.

[0051] Figure 4 This is a schematic diagram of the structure of the dust removal mechanism support provided by the present invention.

[0052] Figure 5 This is a schematic diagram of the structure of the impurity recovery component provided by the present invention.

[0053] Figure 6 This is a schematic diagram of the waste heat utilization component provided by the present invention.

[0054] In the diagram: 1-Reverberatory furnace combustion body, 11-Combustion seat, 12-Combustion chamber, 2-Dust removal and combustion aid assembly, 21-Assembly drive unit, 22-Gas purification unit, 221-Gas injection seat, 222-Gas purification seat, 223-Gas purification component, 23-Gas release unit, 231-Gas release port, 24-Dust removal assembly drive unit, 241-Hinged push block, 242-Dust removal drive rod, 243-Dust removal transmission rod, 244-Dust removal transmission frame, 3-Movable dust removal mechanism, 31-Dust removal mechanism 32-Hinged seat, 33-Dust removal mechanism support seat, 4-Dust adsorption seat, 41-Impurity recovery component, 42-Screening anti-clogging part, 421-Anti-clogging drive component, 422-Anti-clogging lifting seat, 43-Impurity screening part, 431-Upper screening component, 432-Lower screening component, 5-Waste heat utilization component, 51-Flue gas recovery tank, 511-Flue gas recovery chamber, 512-Flue gas absorption box, 52-Flue gas diversion pipe, 521-Waste heat exchange seat, 522-Heat absorption sleeve, 53-Air pump. Detailed Implementation

[0055] Unless otherwise defined, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this application belongs; the terminology used herein in the specification of the application is for the purpose of describing particular embodiments only and is not intended to be limiting of the application; the terms "comprising" and "having," and any variations thereof, in the specification, claims, and foregoing drawings of this application are intended to cover non-exclusive inclusion. The terms "first," "second," etc., in the specification, claims, or foregoing drawings of this application are used to distinguish different objects, not to describe a particular order.

[0056] In this document, the term "embodiment" means that a particular feature, structure, or characteristic described in connection with an embodiment may be included in at least one embodiment of this application. The appearance of this phrase in various places throughout the specification does not necessarily refer to the same embodiment, nor is it a separate or alternative embodiment mutually exclusive with other embodiments. It will be explicitly and implicitly understood by those skilled in the art that the embodiments described herein can be combined with other embodiments.

[0057] In the zinc product processing, the reverberatory furnace is also an important piece of equipment. However, when zinc products react in the reverberatory furnace, there are many impurities inside the furnace, which can easily clog the heat exchanger and cause the exhaust mechanism to become blocked, preventing the reaction from proceeding smoothly. To solve the above problems, we propose a reverberatory furnace combustion chamber based on zinc product processing. The reverberatory furnace combustion chamber based on zinc product processing includes: a reverberatory furnace combustion body 1, which includes a combustion seat 11 and a combustion chamber 12 disposed within the combustion seat 11; a dust removal and combustion assist assembly 2 disposed within the combustion chamber 12, which includes: an assembly drive component 21, a combined combustion assist component fixedly connected to the assembly drive component for injecting combustion assist gas into the combustion chamber 12, and a combined dust removal component. During operation, zinc product raw materials are fed into the combustion chamber 11, then the combined drive component 21 is activated, and combustion-supporting gas is injected into the combined combustion-supporting assembly. The activation of the combined drive component 21 drives the combined combustion-supporting assembly to rotate, ensuring the combustion-supporting gas is evenly distributed within the combustion chamber 12, thus improving combustion efficiency. Simultaneously, the rotation of the combined flame-retardant assembly drives the combined dust removal assembly, increasing the contact area between the combined dust removal assembly and the dust generated during combustion, thereby improving dust removal efficiency and preventing clogging of the device. This application includes a combined drive component 21, a combined combustion-supporting assembly, and a combined dust removal assembly. The rotation of the combined flame-retardant assembly drives the combined dust removal assembly, increasing the contact area between the combined dust removal assembly and the dust generated during combustion, thus improving dust removal efficiency and preventing clogging of the device.

[0058] This invention provides a reverberatory furnace combustion chamber based on zinc product processing, such as... Figure 1 As shown, the reverberatory furnace combustion chamber based on zinc product processing includes:

[0059] The reverberatory furnace combustion body 1 includes a combustion seat 11, and a combustion chamber 12 is provided inside the combustion seat 11;

[0060] The feature is that a dust removal and combustion assisting assembly 2 is provided in the combustion chamber 12, the dust removal and combustion assisting assembly 2 is used to assist combustion in the processing of zinc products and to assist in the dust removal of flue gas after combustion;

[0061] The dust removal and combustion aid assembly 2 includes:

[0062] The assembly drive component 21 is fixedly installed inside the combustion seat 11;

[0063] The combined combustion-supporting assembly is fixedly connected to the combined drive component. The combined combustion-supporting assembly is used to inject combustion-supporting gas into the combustion chamber 12 and to purify the combustion-supporting gas.

[0064] A combined dust removal component is disposed inside the combustion chamber 12 and connected to the combined combustion aid component for collecting impurities inside the combustion chamber 12.

[0065] For example, the side wall of the combustion seat 11 is provided with an electromagnetic heating plate. Compared with the prior art, the heating of zinc product raw materials is achieved by the electromagnetic heating plate provided on the side wall, which has high heating efficiency and avoids the phenomenon of uneven heating of raw materials.

[0066] In this embodiment, during operation, zinc product raw materials are put into the combustion chamber 11, and then the combination drive 21 is turned on, and combustion-supporting gas is injected into the combination combustion-supporting assembly. The turning on of the combination drive 21 can drive the combination combustion-supporting assembly to rotate, so that the combustion-supporting gas is evenly distributed in the combustion chamber 12, improving the combustion efficiency. At the same time, the rotation of the combination flame-retardant assembly can drive the combination dust removal assembly to move, increasing the contact area between the combination dust removal assembly and the dust generated during combustion, improving the dust removal efficiency and avoiding clogging of the device.

[0067] This application includes a combined drive component 21, a combined combustion-supporting component, and a combined dust removal component. The rotation of the combined flame-retardant component can drive the combined dust removal component to move, which increases the contact area between the combined dust removal component and the dust generated during combustion, improves the dust removal efficiency, and avoids clogging of the device.

[0068] In a further preferred embodiment of the present invention, such as Figure 1 As shown, the combined combustion-supporting assembly includes:

[0069] Gas purification unit 22 is used for the injection and purification of combustion-supporting gas;

[0070] A gas release section 23 is connected through the gas purification section 22. The gas release section 23 is provided with multiple sets of gas release ports 231, which are used to release combustion-supporting gases.

[0071] In this embodiment, the combined drive unit 21 is specifically a servo motor, and the output end of the combined drive unit 21 is interference-fitted with a gas release unit 23. The gas release unit 23 can be a rectangular tube or a round tube, and is hollow inside. At the same time, the gas purification unit 22 is sleeved on the gas release unit 23, and multiple sets of connecting grooves are provided at the connection between the two, so as to facilitate the entry of the combustion-supporting gas into the gas release unit 23. The gas release port 231 can be a rectangular port or a round port. A baffle can also be provided in the gas release port 231. The baffle can cut and turbulent the gas, further improving the combustion efficiency. In this application, the combustion-supporting gas can be natural gas or air with a high oxygen content.

[0072] In a further preferred embodiment of the present invention, such as Figure 2 As shown, the gas purification unit 22 includes:

[0073] The gas injection seat 221 is rotatably connected to the gas release part 23 via a bearing and is sleeved on the gas release part 23;

[0074] At least one set of gas purification seats 222 is installed inside the gas injection seat 221 and is in through communication with the gas release part 23.

[0075] At least one set of gas purification components 223 is detachably installed in the gas purification base 222 for gas purification treatment.

[0076] In this embodiment, the gas purification component 223 can be detachably installed by means of clips or bolts, and the gas purification component 223 can be a filter core.

[0077] In a further preferred embodiment of the present invention, such as Figure 1 As shown, the combined dust removal assembly includes:

[0078] The dust removal component drive unit 24 is fixedly connected to the gas release unit 23 and is used to adjust the impurity adsorption position of the combined dust removal component.

[0079] The movable dust removal mechanism 3 is connected to the dust removal component drive unit 24 and is disposed inside the combustion chamber 12.

[0080] In this embodiment, during operation, the rotation of the gas release unit 23 can drive the dust removal component drive unit 24 to move, and the dust removal component drive unit 24 drives the movable dust removal mechanism 3 to move, thereby realizing the adjustment of the position of the movable dust removal mechanism 3 and improving the dust adsorption efficiency.

[0081] In a further preferred embodiment of the present invention, such as Figure 1 As shown, the dust removal component drive unit 24 includes:

[0082] The dust removal drive rod 242 is fixedly connected to the gas release part 23;

[0083] A dust removal transmission rod 243 is provided on one side of the dust removal drive rod 242. The dust removal transmission rod 243 is hinged to the dust removal drive rod 242, and one end of the dust removal transmission rod 243 is fixedly connected to a dust removal transmission frame 244.

[0084] At least one set of hinged push blocks 241 are fixedly installed on the dust removal transmission frame 244, and the hinged push blocks 241 are connected to the movable dust removal mechanism 3.

[0085] In a further preferred embodiment of the present invention, such as Figure 3-4 As shown, the movable dust removal mechanism 3 includes:

[0086] The dust removal mechanism hinge seat 31 is hollow inside and is sleeved on the hinge push block 241.

[0087] The dust removal mechanism support 32 is fixedly connected to the dust removal mechanism hinge seat 31, and one end of the dust removal mechanism support 32 is rotatably connected to the combustion seat 11.

[0088] At least one set of dust adsorption seats 33, which are detachably installed on the dust removal mechanism support seat 32, are used for adsorbing dust during combustion.

[0089] In this embodiment, the dust adsorption seat 33 can be an electrostatic adsorption net or a vacuum cleaner. At the same time, when the gas release part 23 rotates during operation, the gas release part 23 can drive the dust removal drive rod 242 to rotate. The dust removal drive rod 242 drives the dust removal transmission rod 243 to move, so that the dust removal transmission rod 243 pulls the dust removal transmission frame 244 and the hinge push block 241 to move, thereby realizing the adjustment of the position of the dust removal mechanism support seat 32 and the dust removal mechanism hinge seat 31.

[0090] In a further preferred embodiment of the present invention, such as Figure 5 As shown, this application also includes an impurity recovery assembly 4 for recovering combustion impurities. The impurity recovery assembly 4 is installed within the combustion chamber 11, and the impurity recovery assembly 4 includes:

[0091] Impurity recovery seat 41, which is in through communication with combustion chamber 12;

[0092] An impurity screening section 43 is installed inside the impurity recovery seat 41, and

[0093] A screening anti-clogging part 42 is used to prevent the impurity screening part 43 from clogging. The screening anti-clogging part 42 is fixedly connected to the impurity screening part 43. The screening anti-clogging part 42 includes an anti-clogging drive 421 and an anti-clogging lifting seat 422 fixedly connected to the anti-clogging drive 421. The anti-clogging lifting seat 422 is fixedly connected to the impurity screening part 43.

[0094] For example, the impurity screening unit 43 includes:

[0095] The upper screening element 431 is used for screening impurities after combustion;

[0096] The lower screening member 432 is fixedly connected to the upper screening member 431. The lower screening member 432 works in conjunction with the upper screening member 431 to screen impurities again after combustion.

[0097] In this embodiment, the anti-clogging drive 421 can be a hydraulic cylinder, a pneumatic cylinder, or an electric push rod. The anti-clogging drive 421 is fixedly installed in the impurity recovery seat 41 by a clamp. When working, the anti-clogging drive 421 is turned on, and the anti-clogging drive 421 drives the anti-clogging lifting seat 422 and the impurity screening section 43 to move up and down, thus avoiding the clogging of the impurity screening section 43.

[0098] In a further preferred embodiment of the present invention, such as Figure 6 As shown, this application also includes a waste heat utilization component 5, which is disposed on one side of the combustion seat 11 and communicates with the combustion chamber 12. The waste heat utilization component 5 includes:

[0099] The air extraction pump 53 is fixedly installed on the side wall of the combustion chamber 11, and the air extraction pump 53 is in continuous communication with the combustion chamber 12.

[0100] The flue gas recovery tank 51 is connected to the air pump 53 and fixed on the side wall of the combustion seat 11. The flue gas recovery tank 51 is provided with a flue gas recovery chamber 511.

[0101] At least one set of flue gas diversion pipes 52 are installed in the flue gas recovery chamber 511. The flue gas diversion pipes 52 are used for heat transfer of the flue gas after combustion.

[0102] At least one set of waste heat exchange seats 521 is used to assist in the transfer of heat in the flue gas;

[0103] The heat-absorbing sleeve 522 is fitted onto the waste heat exchange base 521 and is used for absorbing and exchanging waste heat in the flue gas.

[0104] A flue gas absorption box 512 is installed in the flue gas recovery chamber 511. The flue gas absorption box 512 is used to absorb the flue gas after combustion.

[0105] In this embodiment, the waste heat exchange seat 521 can be a round seat or a square seat, and the waste heat exchange seat 521 is installed by a snap or bolt, while the heat absorption sleeve 522 can be a hollow threaded tube or a corrugated tube.

[0106] In summary, this invention provides a reverberatory furnace combustion chamber based on zinc product processing. During operation, zinc product raw materials are fed into the combustion seat 11, and then the combined drive component 21 is activated, injecting combustion-supporting gas into the combined combustion-supporting assembly. The activation of the combined drive component 21 drives the combined combustion-supporting assembly to rotate, so that the combustion-supporting gas is evenly distributed in the combustion chamber 12, improving combustion efficiency. At the same time, the rotation of the combined flame-retardant assembly drives the combined dust removal assembly to move, increasing the contact area between the combined dust removal assembly and the dust generated during combustion, improving dust removal efficiency and preventing clogging of the device.

[0107] During operation, the rotation of the gas release unit 23 can drive the dust removal component drive unit 24 to move, and the dust removal component drive unit 24 drives the movable dust removal mechanism 3 to move, thereby realizing the adjustment of the position of the movable dust removal mechanism 3 and improving the dust adsorption efficiency.

[0108] When the gas release part 23 rotates, it can drive the dust removal drive rod 242 to rotate. The dust removal drive rod 242 drives the dust removal transmission rod 243 to move, so that the dust removal transmission rod 243 pulls the dust removal transmission frame 244 and the hinge push block 241 to move, thereby realizing the adjustment of the position of the dust removal mechanism support seat 32 and the dust removal mechanism hinge seat 31.

[0109] This application includes a combined drive component 21, a combined combustion-supporting component, and a combined dust removal component. The rotation of the combined flame-retardant component can drive the combined dust removal component to move, which increases the contact area between the combined dust removal component and the dust generated during combustion, improves the dust removal efficiency, and avoids clogging of the device.

[0110] It should be noted that, for the sake of simplicity, the foregoing embodiments are all described as a series of actions. However, those skilled in the art should understand that the present invention is not limited to the described order of actions, as some steps may be performed in other orders or simultaneously according to the present invention. Furthermore, those skilled in the art should also understand that the embodiments described in the specification are preferred embodiments, and the actions and modules involved are not necessarily essential to the present invention.

[0111] It should be understood that the disclosed apparatus can be implemented in other ways, given the several embodiments provided in this application. For example, the apparatus embodiments described above are merely illustrative; the division of units described above is only a logical functional division, and in actual implementation, there may be other division methods. For example, multiple units or components may be combined or integrated into another system, or some features may be ignored or not executed. Furthermore, the coupling or communication connections shown or discussed may be through some interfaces; the indirect coupling or communication connections between devices or units may be telecommunications or other forms.

[0112] The units described above as separate components may or may not be physically separate. The components shown as units may or may not be physical units; that is, they may be located in one place or distributed across multiple network units. Some or all of the units can be selected to achieve the purpose of this embodiment according to actual needs.

[0113] The above embodiments are only used to illustrate the technical solutions of the present invention, and are not intended to limit the scope of protection of the invention. Obviously, the described embodiments are only some embodiments of the present invention, not all embodiments. Based on these embodiments, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of the present invention. Although the present invention has been described in detail with reference to the above embodiments, those skilled in the art can still combine, add, delete, or otherwise adjust the features of the various embodiments of the present invention according to the circumstances without conflict or creative effort, thereby obtaining different technical solutions that do not fundamentally depart from the concept of the present invention. These technical solutions also fall within the scope of protection of the present invention.

Claims

1. A reverberatory furnace combustion chamber based on zinc product processing, the reverberatory furnace combustion chamber based on zinc product processing comprising: The reverberatory furnace combustion body includes a combustion seat, and a combustion chamber is provided inside the combustion seat; Its characteristic is that it includes a dust removal and combustion assisting assembly disposed in the combustion chamber, wherein the dust removal and combustion assisting assembly is used to assist combustion in the processing of zinc products and to assist in the dust removal of flue gas after combustion; The dust removal and combustion aid assembly includes: The assembly drive unit is fixedly installed inside the combustion chamber; A combined combustion-supporting assembly fixedly connected to the combined drive component, the combined combustion-supporting assembly is used to inject combustion-supporting gas into the combustion chamber and to purify the combustion-supporting gas; A combined dust removal component is disposed inside the combustion chamber and connected to the combined combustion aid component for collecting impurities inside the combustion chamber; The combined combustion-supporting component includes: Gas purification unit, used for the injection and purification of combustion-supporting gases; A gas release section is connected to the gas purification section, and the gas release section is provided with multiple sets of gas release ports for releasing combustion-supporting gases; The gas purification unit includes: The gas injection seat is rotatably connected to the gas release part via a bearing and is sleeved on the gas release part; At least one set of gas purification seats is installed inside the gas injection seat and is in through communication with the gas release section. At least one set of gas purification components is detachably installed in the gas purification base for gas purification treatment; The combined dust removal component includes: The dust removal component drive unit is fixedly connected to the gas release unit and is used to adjust the impurity adsorption position of the combined dust removal component; A movable dust removal mechanism connected to the dust removal component drive unit is located inside the combustion chamber; The dust removal component drive unit includes: The dust removal drive rod is fixedly connected to the gas release part; A dust removal transmission rod is provided on one side of the dust removal drive rod. The dust removal transmission rod is hinged to the dust removal drive rod, and a dust removal transmission frame is fixedly connected to one end of the dust removal transmission rod. At least one set of hinged push blocks is fixedly installed on the dust removal transmission frame, and the hinged push blocks are connected to the movable dust removal mechanism; The mobile dust removal mechanism includes: A dust removal mechanism hinge seat, wherein the interior of the dust removal mechanism hinge seat is hollow and is sleeved on the hinge push block; The dust removal mechanism support is fixedly connected to the dust removal mechanism hinge seat. One end of the dust removal mechanism support is rotatably connected to the combustion seat. It also includes at least one set of dust adsorption seats, which are detachably installed on the dust removal mechanism support for adsorbing dust during combustion.

2. The reverberatory furnace combustion chamber based on zinc product processing as described in claim 1, characterized in that, It also includes an impurity recovery assembly for recovering combustion impurities, the impurity recovery assembly being installed within the combustion chamber, the impurity recovery assembly comprising: An impurity recovery seat, wherein the impurity recovery seat is in through communication with the combustion chamber; An impurity screening section is provided in the impurity recovery seat, and an anti-clogging section is provided to prevent the impurity screening section from clogging. The anti-clogging section is fixedly connected to the impurity screening section. The anti-clogging section includes an anti-clogging drive and an anti-clogging lifting seat fixedly connected to the anti-clogging drive. The anti-clogging lifting seat is fixedly connected to the impurity screening section.

3. The reverberatory furnace combustion chamber based on zinc product processing as described in claim 2, characterized in that, The impurity screening unit includes: The upper screening component is used to screen impurities after combustion. A lower screening component is fixedly connected to the upper screening component. The lower screening component works in conjunction with the upper screening component to further screen impurities after combustion.

4. The reverberatory furnace combustion chamber based on zinc product processing as described in claim 3, characterized in that, It also includes a waste heat utilization component, which is disposed on one side of the combustion seat and communicates with the combustion chamber. The waste heat utilization component includes: An air extraction pump is fixedly installed on the side wall of the combustion chamber, and the air extraction pump is in continuous communication with the combustion chamber. The flue gas recovery tank is connected to the air extraction pump and fixed on the side wall of the combustion seat. The flue gas recovery tank is equipped with a flue gas recovery chamber.

5. The reverberatory furnace combustion chamber based on zinc product processing as described in claim 4, characterized in that, The waste heat utilization component also includes: At least one set of flue gas diversion pipes are installed in the flue gas recovery chamber and are used for heat transfer of the flue gas after combustion. At least one waste heat exchange seat is provided to assist in the transfer of heat in the flue gas; A heat-absorbing sleeve is fitted onto the waste heat exchange base for absorbing and exchanging waste heat in the flue gas, and a flue gas absorption box is installed in the flue gas recovery chamber for absorbing the flue gas after combustion.