High-frequency vibration leveling mechanism for flue forming machine
By combining a vibration table and a leveling mechanism in the flue forming machine, high-frequency vibration and leveling are synchronized, solving the problems of complex structure and poor flatness in the existing technology, improving the efficiency and quality of flue forming, simplifying the equipment structure and reducing energy consumption.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Patents(China)
- Current Assignee / Owner
- JIANGSU KENENG BUILDING MATERIALS MASCH CO LTD
- Filing Date
- 2025-12-26
- Publication Date
- 2026-07-03
AI Technical Summary
The existing flue forming machine has separate vibration and leveling processes, which are complex in structure and have high energy consumption. In addition, the poor fluidity of the concrete billet results in poor surface flatness of the formed flue, requiring additional manual grinding, which affects the safety and durability of use.
A high-frequency vibration leveling mechanism for a flue forming machine is designed. Combining a vibration table and a leveling mechanism, the internal compaction and surface leveling of the blank are achieved through high-frequency vibration. A flexible support and elastic buffer structure is adopted to simplify the equipment structure, reduce energy consumption, and improve forming efficiency.
This technology enables the simultaneous completion of internal compaction and surface leveling of flue gas billets, simplifies equipment structure, reduces energy consumption, improves molding quality and efficiency, avoids subsequent manual grinding, and extends equipment lifespan.
Smart Images

Figure CN121468751B_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of building material production technology, specifically to a high-frequency vibration leveling mechanism for a flue forming machine. Background Technology
[0002] As a core component for building smoke exhaust, the quality of flue molding directly determines its safety and durability. Concrete is the mainstream material for flue molding, and vibration compaction is the core process of flue molding. Existing technologies mostly use vibration devices to achieve material compaction, but there are still many technical defects in the process of use.
[0003] Traditional flue gas forming machines often separate vibration and leveling processes, requiring independent power sources. This results in complex structures, high energy consumption, poor adaptability, and difficulty in meeting the operational needs of flue gas forming. Furthermore, some forming machines rely solely on composite vibration to achieve self-leveling of the billet. However, concrete-like billets have weak fluidity, and unevenness easily forms on the surface during vibration, which cannot be self-filled and leveled. This leads to poor surface smoothness of the formed flue gas, requiring additional manual grinding and increasing process costs.
[0004] For example, a vibration device for producing foamed concrete flues, disclosed in CN218083261U, causes the vibration platform to vibrate in both vertical and horizontal planes, effectively preventing uneven flue pouring. However, in practice, this technology relies solely on composite vibration to self-level the material. Since concrete has low fluidity, it cannot fill surface irregularities, resulting in poor flue surface flatness and lack of sizing and compaction, easily leading to surface sanding and peeling. Furthermore, small voids may remain inside the material, affecting the structural strength of the flue. Summary of the Invention
[0005] To solve the above-mentioned technical problems, the present invention provides the following technical solution: a high-frequency vibration leveling mechanism for a flue gas forming machine, comprising:
[0006] The frame and its internally fixed base are provided. The base is located at the bottom of the inner side of the frame. The frame is used to install the main body of the flue forming machine. The upper surface of the base is provided with a limit groove. A vibration table is installed on the top of the base. The vibration table provides high-frequency vibration power to support the mold cavity of the flue forming machine and achieve internal compaction of the blank.
[0007] A support mechanism is installed between the base and the vibration table. The support mechanism is used to flexibly support the vibration table and buffer high-frequency vibration forces. The limiting groove is used to constrain the movement trajectory of the support mechanism.
[0008] The leveling mechanism is installed on the top of the frame and is positioned directly above the vibrating table. The leveling mechanism is pressed and adapted to the vibrating table. The leveling mechanism is used to level the surface of the billet and is coordinated with the vibration rhythm of the vibrating table to ensure that the flattening component always fits the billet, so that the leveling is uniform.
[0009] The vibration table includes a frame and a vibration platform. Vibration motors are fixedly installed on both sides of the bottom of the vibration platform, and ramps are fixedly installed on both sides of the top of the vibration platform. The vibration platform is used to support the mold cavity of the flue forming machine containing the flue blank. After the vibration motor is powered on, it generates high-frequency vibration, which drives the vibration platform to reciprocate, making the flue blank dense and avoiding hollow areas. When the vibration platform vibrates up and down, the inclined surface of the ramps pushes the leveling mechanism to move, realizing the linkage action of the leveling mechanism and providing power to the leveling mechanism.
[0010] The leveling mechanism includes a frame, with rotating rods fixedly installed at the middle of both sides of the frame. The rotating rods are rotatably mounted on the top of the frame. Fixed sleeves are fixedly installed at both ends of the outer surface of the frame. Mounting frames are fixedly installed at the bottom of the fixed sleeves. Push rollers are rotatably mounted on the bottom of the mounting frames via a rotating shaft. The push rollers are pressed and matched with the inclined surface of the ramp block. Flattening components are installed between the fixed sleeves. When the ramp block moves, its inclined surface presses against the push rollers, causing the push rollers to move upward under force. This causes the mounting frames, fixed sleeves, and frame to rotate upward around the rotating rods. The frame causes one side of the flattening component to move upward. The push rollers on both sides reciprocate and press against the ramp block, and the flattening component reciprocates synchronously.
[0011] Preferably, the uprights are fixedly installed on both sides of the top of the base, and rotating connecting rods and connecting springs are respectively installed on both sides of the vibration platform. The rotating connecting rods and connecting springs are respectively installed on the outer surfaces of the two uprights. The rotating connecting rods connect the vibration platform and the uprights, limiting the vibration platform to reciprocating up and down only along the rotation direction of the rotating connecting rods to prevent the platform from tilting. The connecting springs cooperate with the rotating connecting rods to extend and rebound during vibration, buffering the vibration impact force, and at the same time assisting the vibration platform to quickly reset and increase the vibration frequency.
[0012] Preferably, the support mechanism includes an arc-shaped metal plate and a fixed column. The fixed column is fixedly installed on the upper surface of the base. Connecting ropes are fixedly installed at the four corners of the arc-shaped metal plate. The connecting ropes are fixedly installed on the top of the fixed column. The upper curved surface of the arc-shaped metal plate is pressed and adapted to the bottom of the vibration platform. The arc-shaped metal plate directly supports the bottom of the vibration platform and can elastically deform itself to buffer the high-frequency vibration of the vibration motor and avoid hard contact that could cause wear on the components. The connecting ropes are used to fix the arc-shaped metal plate to maintain its concave support posture.
[0013] Preferably, a fixed shaft is fixedly installed at the middle of the concave surface of the arc-shaped metal plate via a bracket. A rotating rod is rotatably installed on the outer surface of the fixed shaft. The rotating rods are oppositely arranged on both sides of the fixed shaft. A rotating shaft is rotatably installed at the other end of the rotating rod. A roller is fixedly installed on the outer surface of the rotating shaft. When the arc-shaped metal plate deforms under force, it drives the rotating rod to rotate around the fixed shaft, transmitting the force to the roller. The roller rolls along the limiting groove, limiting the movement trajectory of the support mechanism, and at the same time converting the deformation of the arc-shaped metal plate into linear motion of the roller, thereby improving the support stability.
[0014] Preferably, there are two limiting grooves, and the two limiting grooves are symmetrically arranged on the top of the base, and the roller is squeezed and adapted to the inner wall of the limiting groove.
[0015] Preferably, a fixing rod is fixedly installed at the middle of the rotating rod, and an arc-shaped metal plate II is rotatably installed on the outer surface of the fixing rod. The fixing rod is located at both ends of the arc-shaped metal plate II, and the arc-shaped metal plate II is located directly below the arc-shaped metal plate I. The arc-shaped metal plate II assists the arc-shaped metal plate I in buffering vibration and improving the buffering effect of the supporting mechanism.
[0016] Preferably, the flattening component includes a push plate and a fixing plate. A flattening roller is rotatably mounted on the bottom of the push plate. The flattening roller is evenly distributed on the bottom of the push plate. The push plate drives the flattening roller to adhere to the surface of the billet. The flattening roller directly contacts the top of the flue billet, rolling and flattening the surface of the billet while avoiding the billet from sticking together, thus ensuring the leveling effect.
[0017] Preferably, rotating plates are rotatably mounted on both sides of the push plate via rotating shafts, and the fixed plate is fixedly mounted on the outer surface of the fixed sleeve. The end of the rotating plate away from the push plate is rotatably mounted on the other side of the fixed plate. The rotating plate connects the push plate and the fixed plate and rotates around the rotating shafts at both ends to adjust the tilt angle of the push plate and ensure that the flattening roller fully fits.
[0018] Preferably, the fixing plate is horizontally arranged on the outer surface of the fixing sleeve, and an arc spring is fixedly connected between the bottom of the fixing plate and the outer surface of the rotating plate. The arc spring provides elastic clamping force, drives the rotating plate to reset, so that the flattening roller always fits the surface of the blank, and at the same time buffers the impact force during the flattening process to avoid damage to the blank.
[0019] Preferably, the bottom of the frame is fixedly equipped with support legs, which are evenly distributed at the bottom of the frame. The support legs are used to support the frame, isolate the vibration of the whole machine from being transmitted to the ground, prevent the equipment from shifting, and improve the stability of operation.
[0020] This invention provides a high-frequency vibration leveling mechanism for a flue gas forming machine. It has the following beneficial effects:
[0021] (I) The flue forming machine uses a high-frequency vibration leveling mechanism. Through the coordinated setup of the vibration table and the leveling mechanism, the vibration motor drives the vibration platform to perform high-frequency reciprocating vibration. The vibration platform synchronously drives the inclined blocks on both sides to move up and down. The inclined surfaces of the inclined blocks continuously squeeze the push rollers of the leveling mechanism, pushing the frame to rotate around the rotating rod, thereby driving the flattening parts to move up and down synchronously with the vibration rhythm, realizing the linkage operation of vibration and leveling. The vibration table and the leveling mechanism rely on a single vibration motor as the power source to simultaneously complete the two core processes of internal compaction and surface leveling of the flue blank. This greatly simplifies the equipment structure, reduces equipment energy consumption and manufacturing costs, and improves the efficiency of flue forming operations. At the same time, the flattening parts adhere to the blank and compact and level it with the vibration rhythm, avoiding surface defects caused by the disconnect between leveling and vibration, and improving the consistency of forming.
[0022] (II) The flue forming machine uses a high-frequency vibration leveling mechanism. Through the setting of the leveling mechanism, when the frame is flipped, it drives the flattening parts to fit the blank. The arc spring provides elastic clamping force for the rotating plate, so that the flattening roller always fits tightly in contact with the surface of the blank. The rotating plate can rotate flexibly around the two ends of the rotating shaft, and the tilt angle of the push plate can be adjusted. The flattening roller rolls along the surface of the blank to level it, which effectively solves the problem of uneven surface of blank and easy sanding in the existing technology. No subsequent manual grinding is required, which ensures the surface forming quality of the flue.
[0023] (III) The flue forming machine uses a high-frequency vibration leveling mechanism. Through the setting of the support mechanism, when the vibration platform vibrates, it presses the arc-shaped metal plate one downward, causing it to undergo elastic deformation. This drives the fixed shaft to move downward and the rotating rods on both sides to rotate around the fixed shaft. The rotating rods drive the rollers to roll back and forth along the base limiting groove. At the same time, the rotating rods drive the arc-shaped metal plate two to undergo synchronous elastic deformation. The double-layer arc-shaped metal plates achieve flexible support, buffering the high-frequency impact force generated by the vibration motor, avoiding the vibration impact force from being directly transmitted to the base and frame, reducing the wear of equipment parts, and extending the service life of the equipment. The rollers and limiting grooves are adapted to constrain the movement trajectory of the support mechanism and the vibration table, preventing lateral tilting and avoiding uneven distribution of flue billet caused by vibration tilting, thus improving the consistency of the internal density of the billet.
[0024] (iv) The flue forming machine uses a high-frequency vibration leveling mechanism. With the setting of the vibration table, when the vibration motor drives the vibration platform to vibrate, the rotating connecting rod limits the vibration platform to only move up and down in the direction of the connecting rod rotation. The connecting spring moves with the vibration to extend and rebound, assisting the vibration platform to quickly reset. The rotating connecting rod constrains the vibration trajectory of the vibration platform, increases the vibration frequency, and at the same time buffers the lateral impact force during the vibration process to avoid platform deviation and ensure continuous and stable operation. Attached Figure Description
[0025] Figure 1 This is a schematic diagram of the overall structure of the present invention;
[0026] Figure 2 This is a schematic diagram of the appearance of the present invention;
[0027] Figure 3 This is a diagram showing the positional relationship between the leveling mechanism and the frame of the present invention;
[0028] Figure 4 This is a diagram showing the positional relationship between the vibration table and the support mechanism of this invention;
[0029] Figure 5 This is a schematic diagram of the vibration table structure of the present invention;
[0030] Figure 6 This is a schematic diagram of the support mechanism structure of the present invention;
[0031] Figure 7 This is a schematic diagram of the leveling mechanism of the present invention;
[0032] Figure 8 This is a schematic diagram of the flattening component structure of the present invention.
[0033] In the diagram: 1. Frame; 2. Base; 3. Vibration table; 31. Upright; 32. Vibration platform; 33. Vibration motor; 34. Rotating connecting rod; 35. Connecting spring; 36. Inclined block; 4. Limiting groove; 5. Supporting mechanism; 51. Arc-shaped metal plate one; 52. Fixed shaft; 53. Rotating rod; 54. Rotating shaft; 55. Roller; 56. Fixed column; 57. Connecting rope; 58. Fixed rod; 59. Arc-shaped metal plate two; 6. Leveling mechanism; 61. Frame; 62. Rotating rod; 63. Fixed sleeve; 64. Mounting bracket; 65. Push wheel; 66. Flattening component; 661. Push plate; 662. Rotating plate; 663. Fixed plate; 664. Arc-shaped spring; 665. Flattening roller; 7. Support leg. Detailed Implementation
[0034] The technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of the present invention.
[0035] For the first embodiment, please refer to... Figure 1-5 This invention provides a technical solution: a high-frequency vibration leveling mechanism for a flue gas forming machine, comprising:
[0036] The frame 1 and the base 2 fixedly installed inside it are provided. The base 2 is located at the bottom of the inner side of the frame 1. The frame 1 is used to install the main body of the flue forming machine. The upper surface of the base 2 is provided with a limit groove 4. The top of the base 2 is equipped with a vibration table 3. The vibration table 3 provides high-frequency vibration power to support the mold cavity of the flue forming machine and achieve internal compaction of the blank.
[0037] The bottom of the frame 1 is fixedly equipped with support legs 7. The support legs 7 are evenly distributed at the bottom of the frame 1. The support legs 7 are used to support the frame 1, isolate the vibration of the whole machine from being transmitted to the ground, prevent the equipment from shifting, and improve the stability of operation.
[0038] The vibration table 3 includes a frame 31 and a vibration platform 32. Vibration motors 33 are fixedly installed on both sides of the bottom of the vibration platform 32, and ramp blocks 36 are fixedly installed on both sides of the top of the vibration platform 32. The vibration platform 32 is used to support the mold cavity of the flue forming machine containing the flue blank. After the vibration motors 33 are powered on, they generate high-frequency vibration, which drives the vibration platform 32 to reciprocate, making the flue blank dense inside and avoiding hollow areas. When the vibration platform 32 vibrates up and down, it pushes the leveling mechanism 6 to move through the inclined surface of the ramp block 36, realizing the linkage action of the leveling mechanism 6 and providing power for the leveling mechanism 6.
[0039] The uprights 31 are fixedly installed on both sides of the top of the base 2. The two sides of the vibration platform 32 are respectively equipped with rotating connecting rods 34 and connecting springs 35. The rotating connecting rods 34 and connecting springs 35 are respectively installed on the outer surfaces of the two uprights 31. The rotating connecting rods 34 connect the vibration platform 32 and the uprights 31, limiting the vibration platform 32 to reciprocating up and down along the rotation direction of the rotating connecting rods 34, preventing the platform from tilting. The connecting springs 35 cooperate with the rotating connecting rods 34 to extend and rebound during vibration, buffering the vibration impact force, and at the same time assisting the vibration platform 32 to quickly reset and increase the vibration frequency.
[0040] Support mechanism 5 is installed between base 2 and vibration table 3. Support mechanism 5 is used to flexibly support vibration table 3 and buffer high-frequency vibration force. Limiting groove 4 is used to constrain the movement trajectory of support mechanism 5.
[0041] The leveling mechanism 6 is installed on the top of the frame 1 and is positioned directly above the vibrating table 3. The leveling mechanism 6 is pressed and adapted to the vibrating table 3. The leveling mechanism 6 is used to level the surface of the billet and is coordinated with the vibration rhythm of the vibrating table 3 to ensure that the flattening component always fits the billet, so that the leveling is uniform.
[0042] The second embodiment is based on the first embodiment; please refer to [link / reference]. Figure 4-6 As shown, the support mechanism 5 includes an arc-shaped metal plate 51 and a fixed column 56. The fixed column 56 is fixedly installed on the upper surface of the base 2. Connecting ropes 57 are fixedly installed at the four corners of the arc-shaped metal plate 51. The connecting ropes 57 are fixedly installed on the top of the fixed column 56. The upper curved surface of the arc-shaped metal plate 51 is pressed and adapted to the bottom of the vibration platform 32. The arc-shaped metal plate 51 is used to directly support the bottom of the vibration platform 32. It can elastically deform itself to buffer the high-frequency vibration of the vibration motor 33 and avoid hard contact that causes wear on the parts. The connecting ropes 57 are used to fix the arc-shaped metal plate 51 so that it maintains a concave support posture.
[0043] A fixed shaft 52 is fixedly installed in the middle of the concave surface of the arc-shaped metal plate 51 by a bracket. A rotating rod 53 is rotatably installed on the outer surface of the fixed shaft 52. The rotating rod 53 is arranged opposite to the fixed shaft 52. A rotating shaft 54 is rotatably installed at the other end of the rotating rod 53. A roller 55 is fixedly installed on the outer surface of the rotating shaft 54. When the arc-shaped metal plate 51 is deformed by force, it drives the rotating rod 53 to rotate around the fixed shaft 52, and transmits the force to the roller 55. The roller 55 rolls along the limiting groove 4, which limits the movement trajectory of the support mechanism 5. At the same time, it converts the deformation of the arc-shaped metal plate 51 into the linear motion of the roller 55, thereby improving the support stability.
[0044] There are two limiting grooves 4, and the two limiting grooves 4 are symmetrically arranged on the top of the base 2. The roller 55 is squeezed and adapted to the inner wall of the limiting groove 4.
[0045] A fixing rod 58 is fixedly installed in the middle of the rotating rod 53. An arc-shaped metal plate 59 is rotatably installed on the outer surface of the fixing rod 58. The fixing rod 58 is located at both ends of the arc-shaped metal plate 59. The arc-shaped metal plate 59 is located directly below the arc-shaped metal plate 51. The arc-shaped metal plate 59 assists the arc-shaped metal plate 51 in buffering vibration and improving the buffering effect of the support mechanism 5.
[0046] The third embodiment is based on embodiments one and two; please refer to [link / reference]. Figure 7-8 As shown, the leveling mechanism 6 includes a frame 61. A rotating rod 62 is fixedly installed at the middle of both sides of the frame 61. The rotating rod 62 is rotatably installed on the top of the frame 1. Fixed sleeves 63 are fixedly installed at both ends of the outer surface of the frame 61. A mounting frame 64 is fixedly installed at the bottom of the fixed sleeves 63. A push wheel 65 is rotatably installed at the bottom of the mounting frame 64 via a rotating shaft. The push wheel 65 is pressed and matched with the inclined surface of the ramp block 36. A flattening component 66 is installed between the fixed sleeves 63. When the ramp block 36 moves, its inclined surface presses the push wheel 65. The push wheel 65 moves upward under force, causing the mounting frame 64, fixed sleeves 63 and frame 61 to rotate upward around the rotating rod 62. The frame 61 drives one side of the flattening component 66 to move upward. The push wheel 65 on both sides presses the ramp block 36 back and forth, and the flattening component 66 moves back and forth synchronously.
[0047] The flattening component 66 includes a push plate 661 and a fixed plate 663. A flattening roller 665 is rotatably mounted on the bottom of the push plate 661. The flattening roller 665 is evenly distributed on the bottom of the push plate 661. The push plate 661 drives the flattening roller 665 to fit against the surface of the billet. The flattening roller 665 directly contacts the top of the flue billet, rolls and flattens the surface of the billet, and at the same time avoids the billet from sticking together, ensuring the leveling effect.
[0048] Rotating plates 662 are rotatably mounted on both sides of the push plate 661 via rotating shafts. Fixed plate 663 is fixedly mounted on the outer surface of fixed sleeve 63. The end of rotating plate 662 away from push plate 661 is rotatably mounted on the other side of fixed plate 663. Rotating plate 662 connects push plate 661 and fixed plate 663, and rotates around the rotating shafts at both ends to adjust the tilt angle of push plate 661, ensuring that the flattening roller 665 fully fits.
[0049] The fixing plate 663 is horizontally set on the outer surface of the fixing sleeve 63. An arc spring 664 is fixedly connected between the bottom of the fixing plate 663 and the outer surface of the rotating plate 662. The arc spring 664 provides elastic clamping force, drives the rotating plate 662 to reset, so that the flattening roller 665 always fits against the surface of the blank, and at the same time buffers the impact force during the flattening process to avoid damage to the blank.
[0050] During use, the operator places the molding machine cavity containing the flue blank to be molded on top of the vibration platform 32, starts the vibration motor 33, and the vibration motor 33 generates high-frequency vibration, which drives the vibration platform 32 to vibrate. The vibration platform 32 vibrates up and down along the upright frame 31 through the rotating connecting rods 34 on both sides and the connecting spring 35, which drives the top blank to vibrate synchronously, making the aggregate and slurry inside the blank dense and avoiding hollowness and cracking after molding.
[0051] When the vibration platform 32 vibrates, it presses down on the arc-shaped metal plate 51, causing it to undergo elastic deformation. The arc-shaped metal plate 51 drives the fixed shaft 52 to move downward, driving the rotating rods 53 on both sides to rotate around the fixed shaft 52. The rotating rods 53 drive the rotating shaft 54 and the rollers 55 to reciprocate along the limiting groove 4. At the same time, the rotating rods 53 drive the fixed rods 58 to move synchronously, causing the arc-shaped metal plate 59 to deform synchronously. The arc-shaped metal plate 51 and the arc-shaped metal plate 59 buffer the vibration impact force and prevent the vibration from being transmitted to the base 2 and the frame 1. The rollers 55 and the limiting groove 4 prevent the vibration platform 32 from shifting laterally and ensure vibration stability.
[0052] When the vibration platform 32 vibrates up and down, it drives the inclined blocks 36 on both sides of the top to move up and down synchronously. When the inclined blocks 36 move upward, their inclined surfaces press the pusher 65 upward. The pusher 65 moves upward under force, which drives the mounting frame 64, the fixing sleeve 63 and the frame 61 to rotate upward around the rotating rod 62. The frame 61 drives one side of the flattening part 66 to move upward. The arc spring 664 provides elastic force to make the flattening roller 665 fit tightly against the top of the blank and roll flatten it.
[0053] The vibrating platform 32 vibrates back and forth, driving the ramp block 36 to continuously squeeze the pusher 65, causing the leveling mechanism 6 to rotate up and down in linkage. The flattening roller 665 rolls synchronously to flatten the surface of the billet, compacting and leveling any protrusions or uneven areas on the surface of the billet during the vibration process. After the billet is vibrated and compacted and the surface is leveled to the required standard, the vibrating motor 33 is turned off, the vibrating platform 32 stops vibrating, the leveling mechanism 6 resets, and the formed flue billet can be taken out, completing all operations.
[0054] It should be noted that, in this document, relational terms such as "first" and "second" are used only to distinguish one entity or operation from another, and do not necessarily require or imply any such actual relationship or order between these entities or operations. Furthermore, 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 a process, method, article, or apparatus. Without further limitations, an element defined by the phrase "comprising one..." does not exclude the presence of other identical elements in the process, method, article, or apparatus that includes said element.
[0055] Although embodiments of the 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 invention, the scope of which is defined by the appended claims and their equivalents.
Claims
1. A high frequency vibration leveling mechanism for a flue forming machine, characterized by, include: The frame (1) and the base (2) fixedly installed inside it are provided. The base (2) is located at the bottom of the inner side of the frame (1). A limit groove (4) is opened on the upper surface of the base (2). A vibration table (3) is installed on the top of the base (2). Support mechanism (5), which is installed between base (2) and vibration table (3); The leveling mechanism (6) is installed on the top of the frame (1) and is located directly above the vibration table (3). The leveling mechanism (6) is pressed and adapted to the vibration table (3). The vibration table (3) includes a frame (31) and a vibration platform (32). Vibration motors (33) are fixedly installed on both sides of the bottom of the vibration platform (32), and ramp blocks (36) are fixedly installed on both sides of the top of the vibration platform (32). The leveling mechanism (6) includes a frame (61), a rotating rod (62) is fixedly installed at the middle of both sides of the frame (61), the rotating rod (62) is rotatably installed on the top of the frame (1), a fixing sleeve (63) is fixedly installed at both ends of the outer surface of the frame (61), a mounting frame (64) is fixedly installed at the bottom of the fixing sleeve (63), a push wheel (65) is rotatably installed at the bottom of the mounting frame (64) through a rotating shaft, the push wheel (65) is pressed and adapted to the inclined surface of the ramp block (36), and a flattening component (66) is installed between the fixing sleeves (63).
2. The high-frequency vibration leveling mechanism for a flue forming machine according to claim 1, characterized in that: The uprights (31) are fixedly installed on both sides of the top of the base (2). Rotating connecting rods (34) and connecting springs (35) are respectively installed on both sides of the vibration platform (32). The rotating connecting rods (34) and connecting springs (35) are respectively installed on the outer surfaces of the two uprights (31).
3. The high-frequency vibration leveling mechanism for a flue gas forming machine according to claim 1, characterized in that: The supporting mechanism (5) includes an arc-shaped metal plate (51) and a fixed column (56). The fixed column (56) is fixedly installed on the upper surface of the base (2). Connecting ropes (57) are fixedly installed at the four corners of the arc-shaped metal plate (51). The connecting ropes (57) are fixedly installed on the top of the fixed column (56). The upper curved surface of the arc-shaped metal plate (51) is pressed and adapted to the bottom of the vibration platform (32).
4. The high-frequency vibration leveling mechanism for a flue forming machine according to claim 3, characterized in that: A fixed shaft (52) is fixedly installed in the middle of the concave surface of the arc-shaped metal plate (51) by a bracket. A rotating rod (53) is rotatably installed on the outer surface of the fixed shaft (52). The rotating rod (53) is arranged opposite to each other on both sides of the fixed shaft (52). A rotating shaft (54) is rotatably installed at the other end of the rotating rod (53). A roller (55) is fixedly installed on the outer surface of the rotating shaft (54).
5. The high-frequency vibration leveling mechanism for a flue forming machine according to claim 4, characterized in that: The number of the limiting grooves (4) is two, and the two limiting grooves (4) are symmetrically arranged on the top of the base (2). The roller (55) is squeezed and adapted to the inner wall of the limiting groove (4).
6. The high-frequency vibration leveling mechanism for a flue gas forming machine according to claim 4, characterized in that: A fixing rod (58) is fixedly installed in the middle of the rotating rod (53). An arc-shaped metal plate two (59) is rotatably installed on the outer surface of the fixing rod (58). The fixing rod (58) is set at both ends of the arc-shaped metal plate two (59). The arc-shaped metal plate two (59) is set directly below the arc-shaped metal plate one (51).
7. The high-frequency vibration leveling mechanism for a flue forming machine according to claim 1, characterized in that: The flattening component (66) includes a push plate (661) and a fixing plate (663). A flattening roller (665) is rotatably mounted on the bottom of the push plate (661). The flattening roller (665) is evenly distributed on the bottom of the push plate (661).
8. The high-frequency vibration leveling mechanism for a flue gas forming machine according to claim 7, characterized in that: The push plate (661) has a rotating plate (662) mounted on both sides via a rotating shaft. The fixed plate (663) is fixedly mounted on the outer surface of the fixed sleeve (63). The end of the rotating plate (662) away from the push plate (661) is rotatably mounted on the other side of the fixed plate (663).
9. A high-frequency vibration leveling mechanism for a flue gas forming machine according to claim 8, characterized in that: The fixing plate (663) is horizontally arranged on the outer surface of the fixing sleeve (63), and an arc spring (664) is fixedly connected between the bottom of the fixing plate (663) and the outer surface of the rotating plate (662).
10. A high-frequency vibration leveling mechanism for a flue gas forming machine according to claim 1, characterized in that: The bottom of the frame (1) is fixedly equipped with support legs (7), which are evenly distributed at the bottom of the frame (1).