Energy-saving hot galvanizing tank structure with turbulence generator

By introducing a turbulence generator and circulation components into the hot-dip galvanizing tank, the problem of uneven zinc flow was solved, improving galvanizing quality and energy efficiency while reducing maintenance costs.

CN224411871UActive Publication Date: 2026-06-26ZHENJIANG DAQO RAILWAY EQUIP CO LTD +1

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
ZHENJIANG DAQO RAILWAY EQUIP CO LTD
Filing Date
2025-06-25
Publication Date
2026-06-26

AI Technical Summary

Technical Problem

The zinc liquid is mostly in a static or slow-flowing state in the hot-dip galvanizing tank, resulting in uneven coating thickness, rough surface and zinc dross deposition, which increases the difficulty and cost of cleaning and maintenance.

Method used

An energy-saving hot-dip galvanizing tank structure with a turbulence generator is adopted. Through the synergistic effect of the turbulence component, circulation component and heating component, strong turbulence and circulation of zinc liquid are promoted in the tank, ensuring the uniformity of zinc liquid and temperature, and reducing zinc dross deposition.

Benefits of technology

It achieves uniform flow and heating of zinc liquid in the tank, improves galvanizing quality, reduces energy consumption, and reduces zinc dross deposition and maintenance costs.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model relates to energy -conserving type hot galvanizing tank body structure technical field with turbulence generator, especially energy -consaving type hot galvanizing tank body structure with turbulence generator, including tank body, the tank body is provided with connecting mechanism. The turbulence generator, rotating spiral ring and other components in turbulence subassembly synergistic effect, make the zinc liquid form strong turbulence in tank body right end, cooperate the guide and stirring of guide bellowed plate and rotating stirring plate in circulating subassembly, let the zinc liquid realize even and continuous circulation flow in whole tank body. This good flow state can update the zinc liquid on the surface of the galvanizing workpiece in time, avoids the problem such as uneven plating layer thickness, surface roughness caused by zinc liquid static, makes the galvanizing layer more even, dense, improves the galvanizing quality, in addition, rotating filter bowl and partition filter plate filter the zinc liquid impurity, reduce the deposition of zinc residue in tank body bottom, reduce the difficulty and frequency of cleaning maintenance, effectively reduce the maintenance cost.
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Description

Technical Field

[0001] This utility model relates to the technical field of energy-saving hot-dip galvanizing tank structure with turbulence generator, and particularly to an energy-saving hot-dip galvanizing tank structure with turbulence generator. Background Technology

[0002] Hot-dip galvanizing, a widely used metal surface treatment process, can significantly improve the corrosion resistance and service life of metals, playing a crucial role in many fields such as construction, transportation, and machinery manufacturing. The hot-dip galvanizing tank, as the core equipment in the hot-dip galvanizing process, directly affects the quality, efficiency, and energy consumption of the galvanizing process.

[0003] Regarding solution flow, the flow state of molten zinc inside traditional hot-dip galvanizing tanks is not ideal. The molten zinc is mostly in a relatively static or slow-flowing state within the tank, resulting in untimely replenishment of the molten zinc on the surface of the workpiece to be galvanized. This easily leads to quality problems such as uneven coating thickness and surface roughness. Prolonged static molten zinc will cause zinc dross to accumulate at the bottom of the tank, which not only affects the purity of the molten zinc but also increases the difficulty and cost of cleaning and maintenance. Based on this, an energy-saving hot-dip galvanizing tank structure with a turbulence generator is proposed to solve the above problems. Utility Model Content

[0004] To address the shortcomings of existing technologies, this utility model provides an energy-saving hot-dip galvanizing tank structure with a turbulence generator. This solves the problem that when the zinc liquid is mostly in a relatively static or slow-flowing state in the tank, the zinc liquid on the surface of the workpiece to be galvanized is not updated in time, which easily leads to quality problems such as uneven coating thickness and rough surface. Long-term static zinc liquid will cause zinc dross to be deposited at the bottom of the tank, which not only affects the purity of the zinc liquid, but also increases the difficulty and cost of cleaning and maintenance.

[0005] To solve the above-mentioned technical problems, this utility model provides the following technical solution: an energy-saving hot-dip galvanizing tank structure with a turbulence generator, including a tank, the tank being provided with a connecting mechanism, the connecting mechanism including a turbulence component provided in the right section of the tank, a circulation component provided in the middle section of the tank, and a heating component provided in the left section of the tank;

[0006] The turbulence assembly includes a mounting bracket fixedly installed on the outer wall of the right end of the tank. A drive motor is fixedly installed on the top of the mounting bracket. A rotating shaft is fixedly connected to the inner output end of the drive motor. A rotating plate is fixedly connected to the outer wall of the inner side of the rotating shaft. A connecting rod is fixedly connected to the outer wall of the rotating plate. A fixing ring is fixedly connected to the outer end of the connecting rod. A turbulence generator is fixedly connected to the inner side of the fixing ring. A rotating spiral ring is rotatably connected to the outer wall of the turbulence generator. A flow guide ring is fixedly connected to the inner wall of the right end of the turbulence generator. A rotating filter cylinder is rotatably connected to the inner wall of the flow guide ring. A partition filter plate is fixedly connected to the outer wall of the rotating filter cylinder. An annular rail is fixedly connected to the outer wall of the left end of the rotating filter cylinder. A horn-shaped flow guide frame is rotatably connected to the arc-shaped groove opened on the outer wall of the annular rail.

[0007] A further improvement is that the circulation component includes a flow-guiding baffle, a rotating rod is fixedly connected to the inner wall of the middle section of the tank, and a rotating agitator is rotatably connected to the outer wall of the rotating rod.

[0008] A further improvement is that the heating assembly includes a connecting rod rotatably connected to the inner wall of the left end of the tank, an agitator blade is fixedly connected to the outer wall of the connecting rod, an mounting plate is fixedly connected to the inner walls of the front and rear ends of the tank, a heating tube is fixedly installed on the top of the mounting plate, and a baffle plate is fixedly connected to the top of the inner walls of the front and rear ends of the tank.

[0009] A further improvement is that the rotating shaft is rotatably connected to the inner wall of the right end of the tank, and the turbulence generator has a transverse through hole with the through hole arranged circumferentially; when the rotating shaft rotates, the rotating plate fixed to its inner outer wall rotates accordingly, and the rotating plate drives the fixed ring and the turbulence generator inside the fixed ring to make a circular motion at the right end of the tank through the connecting rod.

[0010] A further improvement is that the flow-guiding baffle is fixedly installed on the inner wall of the bottom right end of the tank, and the flow-guiding baffle has equidistant discharge ports. The rotating agitator is equidistantly arranged on the outer wall of the rotating rod, and the rotating agitator has equidistant liquid outlets. When the turbulence generated by the turbulence component drives the zinc liquid to flow, the zinc liquid passes through the flow-guiding baffle and drives the rotating agitator on the outer wall of the rotating rod to rotate. The rotating agitator is equidistantly arranged and has liquid outlets. During its rotation, it further agitates the zinc liquid, so that the zinc liquid forms a circulating flow in the middle section of the tank, ensuring the uniformity of the zinc liquid composition and temperature.

[0011] A further improvement is that the connecting rod is inclinedly disposed on the inner wall of the left end of the tank, and the mounting plate and the heating pipe are symmetrically disposed on the inner walls of the front and rear ends of the tank. When the zinc liquid circulates in the tank, it will drive the agitator blade on the connecting rod to rotate. The rotation of the agitator blade promotes the flow of zinc liquid in the heating area, so that the zinc liquid can fully contact the heating pipe.

[0012] A further improvement is that the outer wall of the rotating spiral ring is provided with spiral discs at equal intervals, and the inner side of the rotating spiral ring is provided with a circumferential array of through holes. The outer wall of the partition filter plate is rotatably connected to the inner wall of the turbulence generator. The rotating spiral ring on the outer wall of the turbulence generator rotates relative to the zinc liquid due to the flow resistance of the zinc liquid. The spiral discs on its outer wall and the through holes in the inner circumferential array cause the zinc liquid to form a strong turbulent motion around the turbulence generator, thereby enhancing the fluidity and mixing effect of the zinc liquid.

[0013] By means of the above technical solution, this utility model provides an energy-saving hot-dip galvanizing tank structure with a turbulence generator, which has at least the following beneficial effects:

[0014] 1. The turbulence generator and rotating spiral ring in this utility model's turbulence assembly work together to create strong turbulence in the zinc liquid at the right end of the tank. Combined with the guidance and stirring of the flow-guiding baffles and rotating agitator plates in the circulation assembly, this ensures uniform and continuous circulation of the zinc liquid throughout the tank. This excellent flow state promptly replenishes the zinc liquid on the surface of the workpiece to be galvanized, avoiding problems such as uneven coating thickness and surface roughness caused by stagnant zinc liquid. This results in a more uniform and dense galvanized layer, improving the galvanizing quality. Furthermore, the rotating filter cartridge and baffle plate filter impurities in the zinc liquid, reducing zinc dross deposition at the bottom of the tank, lowering the difficulty and frequency of cleaning and maintenance, and effectively reducing maintenance costs.

[0015] 2. In the heating assembly of this utility model, the mounting plate and heating tubes are symmetrically arranged on the inner walls of the front and rear ends of the tank. Together with the agitator blades and baffle plates on the connecting rod, they can achieve uniform heating of the zinc liquid and form a good convection circulation in the heating area. This avoids the local overheating or undercooling phenomenon caused by uneven distribution of heating tubes in traditional tanks, and reduces the ineffective consumption of energy. The turbulence assembly and circulation assembly promote the continuous circulation of zinc liquid in the tank, accelerate the transfer and diffusion of heat, further improve the heating efficiency, and reduce heat loss during the heating process. Compared with traditional tanks, it can significantly reduce energy consumption costs and has a significant energy-saving effect. Attached Figure Description

[0016] The accompanying drawings, which are provided to further illustrate this application and form part of this application, illustrate exemplary embodiments of this application and are used to explain this application, but do not constitute an undue limitation of this application.

[0017] In the attached diagram:

[0018] Figure 1 This is a schematic diagram of the overall structure of this utility model;

[0019] Figure 2 This is a schematic diagram of the front structure of this utility model;

[0020] Figure 3This is a schematic diagram of the oblique side structure of this utility model;

[0021] Figure 4 This utility model Figure 3 Enlarged structural diagram at point A in the middle;

[0022] Figure 5 This is a schematic diagram of the inclined structure of this utility model.

[0023] In the diagram: 1. Tank; 2. Connecting mechanism; 21. Turbulence assembly; 211. Mounting frame; 212. Drive motor; 213. Rotating shaft; 214. Rotating plate; 215. Connecting rod; 216. Fixed ring; 217. Turbulence generator; 218. Rotating spiral ring; 219. Guide ring; 2110. Rotating filter cylinder; 2111. Partition filter plate; 2112. Circular rail; 2113. Horn-shaped guide frame; 22. Circulation assembly; 221. Guide folding plate; 222. Rotating rod; 223. Rotating agitator plate; 23. Heating assembly; 231. Connecting rotating rod; 232. Agitator blade; 233. Mounting plate; 234. Heating tube; 235. Baffle plate. Detailed Implementation

[0024] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.

[0025] Example 1

[0026] The zinc liquid in the tank is often in a relatively static or slow-flowing state, which makes it difficult to replenish the zinc on the surface of the workpiece to be galvanized. This can easily lead to quality problems such as uneven coating thickness and rough surface. Prolonged static zinc liquid will cause zinc dross to accumulate at the bottom of the tank, affecting not only the purity of the zinc liquid but also increasing the difficulty and cost of cleaning and maintenance. This embodiment provides an energy-saving hot-dip galvanizing tank structure with a turbulence generator. Please refer to... Figures 1-5An embodiment provides an energy-saving hot-dip galvanizing tank structure with a turbulence generator, including a tank body 1. The tank body 1 is provided with a connecting mechanism 2, which includes a turbulence component 21 disposed on the right section of the tank body 1, a circulation component 22 disposed on the middle section of the tank body 1, and a heating component 23 disposed on the left section of the tank body 1. The turbulence component 21 includes a mounting bracket 211 fixedly installed on the outer wall of the right end of the tank body 1. A drive motor 212 is fixedly installed on the top of the mounting bracket 211. A rotating shaft 213 is fixedly connected to the inner output end of the drive motor 212. A rotating plate 214 is fixedly connected to the outer wall of the inner side of the rotating shaft 213. The outer wall of the rotating plate 214 is fixedly... A connecting rod 215 is fixedly connected to the outer end of the connecting rod 215. A fixed ring 216 is fixedly connected to the inner side of the fixed ring 216. A turbulence generator 217 is fixedly connected to the outer wall of the turbulence generator 217. A rotating spiral ring 218 is rotatably connected to the outer wall of the turbulence generator 217. A guide ring 219 is fixedly connected to the inner wall of the right end of the turbulence generator 217. A rotating filter cylinder 2110 is rotatably connected to the inner wall of the guide ring 219. A partition filter plate 2111 is fixedly connected to the outer wall of the rotating filter cylinder 2110. An annular rail 2112 is fixedly connected to the outer wall of the rotating filter cylinder 2110. A horn-shaped guide frame 2113 is rotatably connected to the arc-shaped groove on the outer wall of the annular rail 2112.

[0027] In this embodiment, in the turbulence assembly 21, the drive motor 212 is mounted on the top of the mounting bracket 211, and its inner output end drives the rotating shaft 213 to rotate; when the rotating shaft 213 rotates, the rotating plate 214 fixed on its inner outer wall rotates accordingly, and the rotating plate 214 drives the fixed ring 216 and the turbulence generator 217 inside the fixed ring 216 to perform circular motion at the right end of the tank 1 through the connecting rod 215; the rotating spiral ring 218 on the outer wall of the turbulence generator 217 rotates relative to the zinc liquid due to the flow resistance, and its outer wall The spiral discs and the through holes in the inner circumferential array cause the zinc liquid to form a strong turbulent motion around the turbulence generator 217, enhancing the fluidity and mixing effect of the zinc liquid. At the same time, the rotating filter cylinder 2110 on the inner wall of the guide ring 219 rotates under the action of the zinc liquid flow. The partition filter plate 2111 on the rotating filter cylinder 2110 filters impurities in the zinc liquid. The cooperation between the annular rail 2112 and the trumpet-shaped guide frame 2113 further optimizes the flow direction and flow rate of the zinc liquid, so that the zinc liquid can impact the surface of the workpiece to be galvanized more evenly.

[0028] Furthermore, the rotating shaft 213 is rotatably connected to the inner wall of the right end of the tank 1, the turbulence generator 217 has a transverse through hole, and the through hole is arranged circumferentially; the outer wall of the rotating spiral ring 218 is provided with spiral discs at equal intervals, and the through holes opened on the inner side of the rotating spiral ring 218 are arranged in a circumferential array, and the outer wall of the partition filter plate 2111 is rotatably connected to the inner wall of the turbulence generator 217.

[0029] Furthermore, the rotating spiral ring 218 on the outer wall of the turbulence generator 217 rotates relative to the zinc liquid due to the flow resistance. The spiral discs on its outer wall and the through holes in the inner circumferential array cause the zinc liquid to form a strong turbulent motion around the turbulence generator 217, enhancing the fluidity and mixing effect of the zinc liquid. At the same time, the rotating filter cylinder 2110 on the inner wall of the guide ring 219 rotates under the action of the zinc liquid flow, and the partition filter plate 2111 on the rotating filter cylinder 2110 filters impurities in the zinc liquid.

[0030] Example 2

[0031] Based on Embodiment 1, the circulation component 22 includes a flow-guiding folding plate 221, a rotating rod 222 is fixedly connected to the inner wall of the middle section of the tank 1, and a rotating agitator 223 is rotatably connected to the outer wall of the rotating rod 222; the heating component 23 includes a connecting rod 231 rotatably connected to the inner wall of the left end of the tank 1, an agitator blade 232 is fixedly connected to the outer wall of the connecting rod 231, an installation plate 233 is fixedly connected to the inner walls of the front and rear ends of the tank 1, a heating pipe 234 is fixedly installed on the top of the installation plate 233, and a baffle plate 235 is fixedly connected to the top of the inner walls of the front and rear ends of the tank 1.

[0032] In this embodiment, in the circulation component 22, the flow guide baffle 221 is fixedly installed on the inner wall of the bottom right end of the tank 1, and its equidistantly spaced discharge ports can guide the flow direction of the zinc liquid; when the turbulence generated by the turbulence component 21 pushes the zinc liquid to flow, after the zinc liquid passes through the flow guide baffle 221, it drives the rotating agitator 223 on the outer wall of the rotating rod 222 to rotate; the rotating agitator 223 is equidistantly spaced and has discharge ports, and during its rotation, it further stirs the zinc liquid, so that the zinc liquid forms a circulating flow in the middle section of the tank 1, ensuring the uniformity of the zinc liquid composition and temperature, and at the same time transmitting the disturbance generated by the turbulence component 21 to the middle area of ​​the tank 1; in the heating component 23, the connecting rod 231 The mounting plate 233 and the heating pipe 234 are inclined and installed on the inner wall of the left end of the tank 1. When the zinc liquid circulates in the tank 1, it will drive the stirring blade 232 on the connecting rod 231 to rotate. The rotation of the stirring blade 232 promotes the flow of zinc liquid in the heating area, so that the zinc liquid can fully contact the heating pipe 234. The mounting plate 233 and the heating pipe 234 are symmetrically arranged on the inner walls of the front and rear ends of the tank 1, which can heat the zinc liquid evenly. The baffle plate 235 is set on the top of the inner walls of the front and rear ends of the tank 1. It can prevent the zinc liquid from splashing out due to violent flow during the heating process, and guide the flow path of the zinc liquid. Together with the stirring blade 232, the zinc liquid forms a good convection circulation in the heating area, improving heating efficiency and uniformity.

[0033] Furthermore, the flow guide baffle 221 is fixedly installed on the inner wall of the bottom right end of the tank 1, and the flow guide baffle 221 is provided with material discharge ports at equal intervals. The rotating agitator 223 is provided at equal intervals on the outer wall of the rotating rod 222, and the rotating agitator 223 is provided with liquid discharge ports at equal intervals. The connecting rod 231 is inclinedly provided on the inner wall of the left end of the tank 1, and the mounting plate 233 and the heating pipe 234 are symmetrically provided on the inner walls of the front and rear ends of the tank 1.

[0034] Furthermore, the rotating agitator 223 is equidistantly arranged and has liquid outlets. During its rotation, it further agitates the zinc liquid, causing it to circulate in the middle section of the tank 1, ensuring the uniformity of the zinc liquid composition and temperature. At the same time, it transmits the disturbance generated by the turbulence component 21 to the middle area of ​​the tank 1. In the heating component 23, the connecting rod 231 is inclinedly arranged on the inner wall of the left end of the tank 1. When the zinc liquid circulates in the tank 1, it will drive the agitator blade 232 on the connecting rod 231 to rotate. The rotation of the agitator blade 232 promotes the flow of the zinc liquid in the heating area, so that the zinc liquid can fully contact the heating tube 234.

[0035] Working principle: In the turbulence assembly 21, the drive motor 212 is mounted on the top of the mounting bracket 211, and its inner output end drives the rotating shaft 213 to rotate; when the rotating shaft 213 rotates, the rotating plate 214 fixed on its inner outer wall rotates accordingly. The rotating plate 214 drives the fixed ring 216 and the turbulence generator 217 inside the fixed ring 216 to perform circular motion at the right end of the tank 1 through the connecting rod 215; the rotating spiral ring 218 on the outer wall of the turbulence generator 217 rotates relative to the zinc liquid due to the flow resistance, and the spiral ring 218 on its outer wall rotates. The rotating discs and the through holes in the inner circumferential array cause the zinc liquid to form strong turbulent motion around the turbulence generator 217, enhancing the fluidity and mixing effect of the zinc liquid. At the same time, the rotating filter cylinder 2110 on the inner wall of the guide ring 219 rotates under the action of the zinc liquid flow. The partition filter plate 2111 on the rotating filter cylinder 2110 filters impurities in the zinc liquid. The cooperation between the annular rail 2112 and the trumpet-shaped guide frame 2113 further optimizes the flow direction and flow rate of the zinc liquid, so that the zinc liquid can impact the surface of the workpiece to be galvanized more evenly.

[0036] In the circulation component 22, the flow guide baffle 221 is fixedly installed on the inner wall of the bottom right end of the tank 1. Its equidistant discharge ports can guide the flow direction of the zinc liquid. When the turbulence generated by the turbulence component 21 drives the zinc liquid to flow, the zinc liquid passes through the flow guide baffle 221 and drives the rotating agitator 223 on the outer wall of the rotating rod 222 to rotate. The rotating agitator 223 is equidistantly arranged and has liquid outlets. During its rotation, it further stirs the zinc liquid, so that the zinc liquid forms a circulation flow in the middle section of the tank 1, ensuring the uniformity of the zinc liquid composition and temperature, and at the same time transmitting the disturbance generated by the turbulence component 21 to the middle area of ​​the tank 1.

[0037] In the heating assembly 23, the connecting rod 231 is inclinedly set on the inner wall of the left end of the tank 1. When the zinc liquid circulates in the tank 1, it will drive the stirring blade 232 on the connecting rod 231 to rotate. The rotation of the stirring blade 232 promotes the flow of the zinc liquid in the heating area, so that the zinc liquid can fully contact the heating tube 234. The mounting plate 233 and the heating tube 234 are symmetrically set on the inner walls of the front and rear ends of the tank 1, which can heat the zinc liquid evenly. The baffle plate 235 is set on the top of the inner walls of the front and rear ends of the tank 1, which can prevent the zinc liquid from splashing out due to violent flow during the heating process, and guide the flow path of the zinc liquid. Together with the stirring blade 232, the zinc liquid forms a good convection circulation in the heating area, improving heating efficiency and uniformity.

[0038] Throughout the process, the turbulence generated by the turbulence component 21 causes the molten zinc to move violently at the right end of the tank 1. The circulation component 22 transmits and diffuses this movement to the middle section of the tank 1, while the heating component 23 heats the molten zinc evenly at the left end of the tank 1 and maintains its good flow state. The three components work together to form a continuous, uniform and efficient circulation of the molten zinc in the tank 1. This not only improves energy utilization efficiency and reduces heat loss and energy waste, but also ensures that the surface of the workpiece to be galvanized can be uniformly coated with molten zinc, improving the quality and consistency of the galvanized layer and reducing maintenance costs and the defect rate.

[0039] It should be noted that, in this document, the terms “comprising,” “including,” or any other variations thereof are intended to cover non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements includes not only those elements but also other elements not expressly listed, or elements inherent to such process, method, article, or apparatus.

[0040] Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the present invention, the scope of which is defined by the appended claims and their equivalents.

Claims

1. An energy-saving hot-dip galvanizing tank structure with a turbulence generator, comprising a tank (1), characterized in that: The tank (1) is provided with a connecting mechanism (2), the connecting mechanism (2) includes a turbulence component (21) provided in the right section of the tank (1), a circulation component (22) provided in the middle section of the tank (1), and a heating component (23) provided in the left section of the tank (1). The turbulence assembly (21) includes a mounting bracket (211) fixedly installed on the outer wall of the right end of the tank (1). A drive motor (212) is fixedly installed on the top of the mounting bracket (211). A rotating shaft (213) is fixedly connected to the inner output end of the drive motor (212). A rotating plate (214) is fixedly connected to the outer wall of the inner side of the rotating shaft (213). A connecting rod (215) is fixedly connected to the outer wall of the rotating plate (214). A fixing ring (216) is fixedly connected to the outer end of the connecting rod (215). A turbulence generator is fixedly connected to the inner side of the fixing ring (216). The device (217) has a rotating spiral ring (218) rotatably connected to the outer wall of the turbulence generator (217), a flow guide ring (219) fixedly connected to the inner wall of the right end of the turbulence generator (217), a rotating filter cylinder (2110) rotatably connected to the inner wall of the flow guide ring (219), a partition filter plate (2111) fixedly connected to the outer wall of the rotating filter cylinder (2110), an annular rail (2112) fixedly connected to the outer wall of the left end of the rotating filter cylinder (2110), and a trumpet-shaped flow guide frame (2113) rotatably connected to the arc groove opened on the outer wall of the annular rail (2112).

2. The energy-saving hot-dip galvanizing tank structure with a turbulence generator according to claim 1, characterized in that: The circulation component (22) includes a flow guide folding plate (221), a rotating rod (222) is fixedly connected to the inner wall of the middle section of the tank (1), and a rotating agitator plate (223) is rotatably connected to the outer wall of the rotating rod (222).

3. The energy-saving hot-dip galvanizing tank structure with a turbulence generator according to claim 1, characterized in that: The heating assembly (23) includes a connecting rod (231) rotatably connected to the inner wall of the left end of the tank (1). An agitator blade (232) is fixedly connected to the outer wall of the connecting rod (231). An installation plate (233) is fixedly connected to the inner wall of the front and rear ends of the tank (1). A heating tube (234) is fixedly installed on the top of the installation plate (233). A baffle plate (235) is fixedly connected to the top of the inner wall of the front and rear ends of the tank (1).

4. The energy-saving hot-dip galvanizing tank structure with a turbulence generator according to claim 1, characterized in that: The rotating shaft (213) is rotatably connected to the inner wall of the right end of the tank (1), and the turbulence generator (217) has a transverse through hole, and the through hole is circumferentially arranged.

5. The energy-saving hot-dip galvanizing tank structure with a turbulence generator according to claim 2, characterized in that: The flow guide folding plate (221) is fixedly installed on the inner wall of the bottom right end of the tank (1), and the flow guide folding plate (221) is provided with material discharge ports at equal intervals. The rotating agitator plate (223) is provided at equal intervals on the outer wall of the rotating rod (222), and the rotating agitator plate (223) is provided with liquid discharge ports at equal intervals.

6. The energy-saving hot-dip galvanizing tank structure with a turbulence generator according to claim 3, characterized in that: The connecting rod (231) is inclinedly arranged on the inner wall of the left end of the tank (1), and the mounting plate (233) and the heating pipe (234) are symmetrically arranged on the inner walls of the front and rear ends of the tank (1).

7. The energy-saving hot-dip galvanizing tank structure with a turbulence generator according to claim 1, characterized in that: The outer wall of the rotating spiral ring (218) is provided with spiral discs at equal intervals, and the inner side of the rotating spiral ring (218) is provided with a circumferential array of through holes. The outer wall of the partition filter plate (2111) is rotatably connected to the inner wall of the turbulence generator (217).