A regional coater for a reinforcement sheet forming die

By using the flipping and transmission mechanisms of the area coating machine for reinforcing plate forming molds, the automatic flipping of the mold plate is achieved. Combined with the reverse conveying of the hot air blower and the conveyor roller, the problems of low efficiency of double-sided coating and time-consuming manual flipping in the existing technology are solved, realizing continuous processing of double-sided coating of mold plates and improving production efficiency and quality stability.

CN224486541UActive Publication Date: 2026-07-14HUADA AUTOMOTIVE TECH

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
HUADA AUTOMOTIVE TECH
Filing Date
2025-08-11
Publication Date
2026-07-14

AI Technical Summary

Technical Problem

In the existing coating process for reinforcing plate forming molds, double-sided coating can only be applied after the first layer of coating has completely dried and cured, resulting in low production efficiency. Furthermore, flipping the mold plate requires manual operation, which is time-consuming and labor-intensive, affecting the continuity of the process and the stability of quality.

Method used

A zone coating machine for reinforcing plate forming molds was designed. The mold plate is automatically flipped 180 degrees by a flipping mechanism and a transmission mechanism. Combined with the reverse conveying of hot air and conveying rollers, continuous double-sided coating is achieved, avoiding manual flipping and transfer operations.

Benefits of technology

This technology enables continuous double-sided coating of mold plates, shortens the process cycle, improves production efficiency and quality stability, and avoids the problems of manual flipping and waiting for curing in traditional processes.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model discloses a kind of area coating machines for reinforcing plate forming die, belong to coating machine technical field, the area coating machine for reinforcing plate forming die, including support frame and the coating machine main body of installing in support frame top, the deflector plate side is connected with the turnover mechanism corresponding with die plate, the turnover mechanism is cooperated with baffle and turns over die plate, transmission mechanism is connected outside the support frame, elastic mechanism for supporting baffle is connected between the deflector plate and baffle, the first support side is connected with the pushing mechanism for pushing baffle.The utility model realizes die plate 180 degrees automatic turnover by the cooperation of turnover mechanism and transmission mechanism, solve the problem of low efficiency caused by traditional technology needs manual disassembly turnover;Through the synergistic effect of elastic mechanism and pushing mechanism, baffle is automatically separated from die plate after turning over, and continuous coating is realized by reverse conveying of cooperating conveying cylinder, avoid the cumbersome operation of artificial reloading.
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Description

Technical Field

[0001] This utility model relates to the field of coating machine technology, and in particular to a zone coating machine for reinforcing plate forming mold. Background Technology

[0002] The area coating machine for reinforced plate forming molds is a device specifically designed for mold surface treatment. Through selective coating technology, it deposits high-performance coatings on critical areas of the mold to improve the mold's wear resistance, corrosion resistance, and demolding performance.

[0003] In existing technologies, the coating process for reinforcing plate forming molds typically involves disassembling the entire mold into plate-like structures for coating operations. The core advantage of this approach is that modular disassembly significantly reduces the difficulty of coating, improves the controllability of single-sided coating, and facilitates rapid reassembly after coating. However, this traditional process has certain technical bottlenecks: due to the functional limitations of the coating equipment, only one side of the mold can be coated at a time. When double-sided coating is required, the first layer must be completely dried and cured before the second layer can be coated. This process has several drawbacks: the interval between the two coating operations prolongs the overall process cycle, reducing production efficiency; and the flipped mold plate needs to be manually reinstalled on the conveyor belt, which is time-consuming, labor-intensive, and troublesome. These technical defects directly restrict the continuity and quality stability of the mold coating process, becoming key technical obstacles to improving production efficiency in this field.

[0004] Therefore, there is an urgent need to provide a zone coating machine for reinforcing plate forming molds to solve the above problems. Utility Model Content

[0005] The technical problem to be solved by this utility model is to overcome the shortcomings of the prior art and provide a zone coating machine for reinforcing plate forming molds.

[0006] To solve the above technical problems, the present invention provides a regional coating machine for reinforcing plate forming molds, including a support frame and a coating machine body installed on the top of the support frame. Multiple conveying rollers are installed inside the support frame, and two hot air blowers located on both sides of the coating machine body are installed on the top of the support frame.

[0007] The inner walls of the support frame are fixedly connected to two first brackets, and deflection plates are rotatably connected to the two first brackets. A flipping mechanism corresponding to the mold plate is connected to one side of the deflection plate, and a baffle is slidably connected to one side of the two deflection plates.

[0008] The flipping mechanism cooperates with the baffle to flip the mold plate, and the support frame is externally connected to a transmission mechanism, which is used to drive the flipping mechanism;

[0009] An elastic mechanism for supporting the baffle is connected between the deflection plate and the baffle, and a pushing mechanism for pushing the baffle is connected to one side of the first bracket.

[0010] The present invention is further configured such that: the support frame is placed on the ground, the coating machine body is used for coating operations, the conveying roller is used for conveying the mold plate, and the hot air blower is used for dust removal and drying.

[0011] With the above technical solution, the support frame serves as the basic framework, the coating machine body performs the coating operation, the conveyor roller is responsible for the horizontal conveying of the mold plate, and the hot air blowers on both sides have the functions of dust removal before coating and drying after coating. This layout allows the coating, drying, and flipping processes to be completed on the same continuous conveying path. The mold plate can be processed on both sides without transfer or disassembly, which solves the efficiency bottleneck problem caused by modular disassembly in traditional processes.

[0012] The present invention is further configured such that: the flipping mechanism includes two U-shaped blocks respectively fixedly connected to the inward side of the two deflection plates, and they correspond one to one. One side of the two U-shaped blocks is in contact with the baffle, and one side of the other side is inclined. The deflection plates and the U-shaped blocks are both located above the conveying roller. The two U-shaped blocks and the baffle cooperate to form a frame structure, and correspond to one end of the mold plate.

[0013] Through the above technical solution, the function of the flipping mechanism is to flip the mold plate. The frame structure is formed by two U-shaped blocks and a baffle. When the mold plate is transported to the predetermined position, the inclined surface design of the U-shaped blocks guides the mold plate into the U-shaped blocks and into contact with the baffle. With the flipping action of the deflection plate, the mold plate is flipped 180 degrees. This structure ensures the positional stability of the mold plate during the flipping process, avoids the risk of coating misalignment, and the frame structure can adapt to mold plates of different sizes, improving the versatility of the equipment.

[0014] The present invention is further configured such that: the transmission mechanism includes two second brackets fixedly connected to the outer sides of the support frame, and corresponding one to one; a motor is installed in each of the two second brackets, and a helical gear disk is fixedly connected to the output end of each of the two motors; a rotating shaft is rotatably connected to both sides of the support frame, and a helical gear disk is also fixedly connected to the outward side of each of the two rotating shafts; the two helical gear disks on both sides of the support frame mesh with each other and correspond one to one; the inward side of each of the two rotating shafts is rotatably connected to the two first brackets and fixedly connected to the two deflection plates respectively.

[0015] Through the above technical solution, the function of the transmission mechanism is to drive the flipping plate; the motor drives the helical gear disk to rotate the rotating shaft, thereby controlling the flipping angle of the deflection plate; the meshing transmission of the two helical gear disks ensures the synchronicity of the flipping action, so that the mold plate is evenly stressed on both sides and the flipping process is smooth and vibration-free; this transmission method has a self-locking function, which can accurately control the flipping angle and maintain the stability of the position, avoiding the positioning error problem of traditional manual flipping.

[0016] The present invention is further configured such that: the elastic mechanism includes two third brackets fixedly connected to the inward side of the two deflection plates respectively, and corresponding one to one; each of the two third brackets is fixedly connected to a fixed shaft; both ends of the baffle are slidably connected to the two fixed shafts respectively; and springs are sleeved on the outside of the two fixed shafts respectively; both ends of the springs are fixedly connected to the inside of the third bracket and one end of the baffle respectively.

[0017] Through the above technical solution, the function of the elastic mechanism is to support the baffle; the baffle is supported by the spring, and during the flipping process, the baffle abuts against the mold plate; after the mold plate flips, the inclined plate pushes the baffle to separate from the mold plate, at which point the spring is compressed, and then the conveyor roller rotates in the opposite direction, so that the flipped mold plate can be dusted again by the hot air blower, and then the flipped mold plate is coated, without the need for workers to remove the mold plate and reinstall the conveyor roller; it is convenient, fast, simple and practical; when the inclined plate separates from the mold plate, the baffle returns to its original position under the action of the spring.

[0018] The present invention is further configured such that: the pushing mechanism includes two fourth brackets respectively fixedly connected to both sides of the inner wall of the support frame, and corresponding one to one; each of the two fourth brackets is equipped with an electric push rod; the output end of each of the two electric push rods is fixedly connected with a long rod; one side of each of the two first brackets is fixedly connected with a T-shaped block; the two long rods are slidably connected to the two T-shaped blocks respectively; and the inward side of each of the two long rods is fixedly connected with an inclined plate, the inclined plate corresponding to the baffle.

[0019] Through the above technical solution, the function of the pushing mechanism is to push the baffle; after the deflection plate drives the mold plate to rotate 180 degrees, the electric push rod drives the inclined plate on the long rod to push the baffle to slide along the fixed axis, so that the baffle is separated from the mold plate. The baffle and the inclined plate are located above the moving path of the mold plate. At this time, the mold plate can pass through the two U-shaped blocks; then the conveying roller rotates in the opposite direction, so that the rotated mold plate passes through the hot air gun for dust removal in the opposite direction, and then passes through the coating machine body for coating. There is no need to add another coating machine body, and there is no need for workers to put the rotated mold plate back on the conveying roller, which reduces costs and saves time and labor.

[0020] The beneficial effects of this utility model are as follows:

[0021] 1. This utility model achieves automatic 180-degree rotation of the mold plate through the cooperation of the flipping mechanism and the transmission mechanism, solving the problem of low efficiency caused by the need for manual disassembly and rotation in traditional processes; through the coordinated action of the elastic mechanism and the pushing mechanism, the baffle automatically detaches from the mold plate after rotation, and is continuously coated by the reverse conveying roller, avoiding the tedious operation of manual reloading.

[0022] 2. This utility model combines hot air blower and conveyor roller reverse conveying to complete bidirectional dust removal and drying of double-sided coating, shortening the interval between two coating operations, improving process continuity and quality stability, thereby effectively solving the technical bottlenecks of long production cycle, excessive manual intervention and unstable quality in traditional processes. Attached Figure Description

[0023] Figure 1 This is a first-view structural diagram of the present invention;

[0024] Figure 2 This is a second-view sectional view of the present invention;

[0025] Figure 3 This is a third-view sectional view of the present invention;

[0026] Figure 4 for Figure 3 A magnified view of a section at point A in the middle;

[0027] Figure 5 for Figure 3 A magnified view of a section at point B in the middle;

[0028] Figure 6 This is a fourth-angle sectional view of the present invention;

[0029] Figure 7 for Figure 6 A magnified view of a section at point C.

[0030] In the diagram: 1. Support frame; 2. Coating machine body; 3. Conveyor roller; 4. Hot air blower; 5. First support; 6. Deflector plate; 7. Tilting mechanism; 701. U-shaped block; 8. Baffle; 9. Transmission mechanism; 901. Second support; 902. Motor; 903. Helical gear plate; 904. Rotating shaft; 10. Elastic mechanism; 1001. Third support; 1002. Fixed shaft; 1003. Spring; 11. Pushing mechanism; 1101. Fourth support; 1102. Electric push rod; 1103. Long rod; 1104. T-shaped block; 1105. Inclined plate. Detailed Implementation

[0031] The preferred embodiments of the present invention will now be described in detail with reference to the accompanying drawings, so that the advantages and features of the present invention can be more easily understood by those skilled in the art, thereby making a clearer and more definite definition of the scope of protection of the present invention.

[0032] Please see Figures 1-7 This embodiment of a coating machine for a reinforcing plate forming mold includes a support frame 1 and a coating machine body 2 mounted on top of the support frame 1. Multiple conveying rollers 3 are installed inside the support frame 1. Two hot air blowers 4 are mounted on the top of the support frame 1 on both sides of the coating machine body 2. First brackets 5 are fixedly connected to both sides of the inner wall of the support frame 1. Deflecting plates 6 are rotatably connected to both first brackets 5. A flipping mechanism 7 corresponding to the mold plate is connected to one side of each deflecting plate 6. A baffle 8 is slidably connected to one side of each deflecting plate 6. The flipping mechanism 7 cooperates with the baffle 8 to flip the mold plate. The flipping mechanism 7 includes two U-shaped blocks 701 fixedly connected to the inward-facing side of each of the two deflecting plates 6, and they correspond one-to-one. One side of each U-shaped block 701 is connected to... The baffles 8 are in contact with each other, and one side of the other side is inclined. The deflecting plate 6 and the U-shaped block 701 are both located above the conveying roller 3. The two U-shaped blocks 701 cooperate with the baffles 8 to form a frame structure, which corresponds to one end of the mold plate. The function of the flipping mechanism 7 is to flip the mold plate. By forming a frame structure with the two U-shaped blocks 701 and the baffles 8, when the mold plate is conveyed to the predetermined position, the inclined design of the U-shaped blocks 701 guides the mold plate into the U-shaped blocks 701 and into contact with the baffles 8. With the flipping action of the deflecting plate 6, the mold plate is flipped 180 degrees. This structure ensures the positional stability of the mold plate during the flipping process, avoids the risk of coating misalignment, and the frame structure can adapt to mold plates of different sizes, improving the versatility of the equipment.

[0033] like Figures 3-5As shown, a transmission mechanism 9 is externally connected to the support frame 1. The transmission mechanism 9 drives the tilting mechanism 7. The transmission mechanism 9 includes two second brackets 901 fixedly connected to both sides of the support frame 1, and they correspond one-to-one. A motor 902 is installed in each of the two second brackets 901, and a helical gear disk 903 is fixedly connected to the output end of each of the two motors 902. Rotating shafts 904 are rotatably connected to both sides of the support frame 1. The helical gear disks 903 are also fixedly connected to the outward side of each of the two rotating shafts 904. The two helical gear disks 903 on both sides of the support frame 1 mesh with each other, and they correspond one-to-one. Two rotating shafts 904 are rotatably connected to two first supports 5 on their inward sides, and are fixedly connected to two deflection plates 6 respectively. The function of the transmission mechanism 9 is to drive the flipping plate 6. The motor 902 drives the helical gear disk 903 to drive the rotating shaft 904 to rotate, thereby controlling the flipping angle of the deflection plate 6. The meshing transmission of the helical gear disks 903 on both sides ensures the synchronicity of the flipping action, so that the force on both sides of the mold plate is uniform and the flipping process is smooth and vibration-free. This transmission method has a self-locking function, which can accurately control the flipping angle and maintain the stability of the position, avoiding the positioning error problem of traditional manual flipping.

[0034] like Figures 3-4 As shown, an elastic mechanism 10 for supporting the baffle 8 is connected between the deflection plate 6 and the baffle 8. The elastic mechanism 10 includes two third supports 1001 fixedly connected to the inward side of the two deflection plates 6, and they correspond one-to-one. A fixed shaft 1002 is fixedly connected inside each of the two third supports 1001. The two ends of the baffle 8 are slidably connected to the two fixed shafts 1002 respectively. A spring 1003 is sleeved on the outside of each of the two fixed shafts 1002. The two ends of the spring 1003 are fixedly connected to the inside of the third support 1001 and one end of the baffle 8 respectively. The elastic mechanism 10 operates... The baffle 8 is supported by a spring 1003, which holds the mold plate against it during the flipping process. After the mold plate flips, the baffle 8 is pushed away from the mold plate by the inclined plate 1105. At this time, the spring 1003 is compressed, and then the conveyor roller 3 rotates in the opposite direction, so that the flipped mold plate can be dusted again by the hot air blower 4. Then the coating is applied to the flipped mold plate without the need for workers to remove the mold plate and reinstall the conveyor roller 3. It is convenient, quick, simple and practical. When the inclined plate 1105 is separated from the mold plate, the baffle 8 returns to its original position under the action of the spring 1003.

[0035] like Figures 6-7As shown, a pushing mechanism 11 for pushing the baffle 8 is connected to one side of the first bracket 5. The pushing mechanism 11 includes two fourth brackets 1101 that are fixedly connected to both sides of the inner wall of the support frame 1, and they correspond one-to-one. An electric push rod 1102 is installed in each of the two fourth brackets 1101. A long rod 1103 is fixedly connected to the output end of each of the two electric push rods 1102. A T-block 1104 is fixedly connected to one side of each of the two first brackets 5. The two long rods 1103 are slidably connected to the two T-blocks 1104 respectively. An inclined plate 1105 is fixedly connected to the inward side of each of the two long rods 1103. The inclined plate 1105 corresponds to the baffle 8. The pushing mechanism 11 operates... The baffle 8 is pushed; after the deflection plate 6 drives the mold plate to rotate 180 degrees, the electric push rod 1102 drives the inclined plate 1105 on the long rod 1103 to push the baffle 8 to slide along the fixed shaft 1002, so that the baffle 8 is separated from the mold plate. The baffle 8 and the inclined plate 1105 are located above the moving path of the mold plate. At this time, the mold plate can pass through the two U-shaped blocks 701; then the conveyor roller 3 is rotated in the opposite direction, so that the rotated mold plate passes through the hot air gun 4 for dust removal in the opposite direction, and then passes through the coating machine body 2 for coating. There is no need to add another coating machine body 2, and there is no need for the staff to put the rotated mold plate back onto the conveyor roller 3, which reduces costs and saves time and labor.

[0036] like Figures 1-7 As shown, the support frame 1 is placed on the ground, the coating machine body 2 is used for coating operations, the conveyor roller 3 is used for conveying the mold plate, and the hot air fan 4 is used for dust removal and drying. The support frame 1 serves as the basic frame, the coating machine body 2 performs the coating operation, the conveyor roller 3 is responsible for the horizontal conveying of the mold plate, and the hot air fans 4 on both sides have the functions of dust removal before coating and drying after coating. This layout allows the coating, drying, and flipping processes to be completed on the same continuous conveying path. The mold plate can be double-sided without transfer or disassembly, which solves the efficiency bottleneck problem caused by modular disassembly in traditional processes.

[0037] In use, this invention uses a conveyor roller 3 to transport the mold plate, and a hot air gun 4 to remove dust before coating and dry after coating. When the mold plate, after coating and drying on one side, is transported to a predetermined position, a U-shaped block 701 and a baffle 8 cooperate to form a frame structure to fix the mold plate. A motor 902 drives a helical gear disc 903, which in turn drives a rotating shaft 904 to rotate. A deflection plate 6 drives the frame and mold plate to rotate 180 degrees synchronously to achieve double-sided switching. After rotation, an electric push rod 1102 drives a helical plate 1105 to push a baffle 8 along a fixed axis 100. 2. Sliding causes the baffle 8 to detach from the mold plate. At this time, the conveyor roller 3 rotates in the opposite direction, and the mold plate moves in the opposite direction and is cleaned of dust again by the hot air blower 4. Then it enters the coating machine body 2 to complete the coating on the other side. The entire process completes the double coating on the continuous conveying path without waiting for the first layer to cure or manually disassembling and flipping. Automatic detachment is achieved by pushing the elastically supported baffle 8 and inclined plate 1105. Combined with the bidirectional dust removal function of the hot air blower 4, the problem of long interval between two coatings and time-consuming manual flipping in the traditional process is solved, which improves production efficiency and quality stability.

[0038] The above description is merely an embodiment of this utility model and does not limit the patent scope of this utility model. Any equivalent structural or procedural transformations made based on the description and drawings of this utility model, or direct or indirect applications in other related technical fields, are similarly included within the patent protection scope of this utility model.

Claims

1. A regional coating machine for a reinforced plate forming die, comprising a support frame (1) and a coating machine body (2) installed on the top of the support frame (1), a plurality of conveying rollers (3) are installed in the support frame (1), characterized in that: The support frame (1) top is provided with two hot air machines (4) on both sides of the coating machine body (2); The support frame (1) is internally and fixedly connected with first supports (5) on both sides, both the first supports (5) are internally and rotatably connected with deflection plates (6), the deflection plates (6) are connected with turnover mechanisms (7) corresponding to the mold plates on one side, both the deflection plates (6) are slidably connected with baffles (8) on one side; The turnover mechanism (7) is matched with the baffle (8) to turn over the mold plate, the support frame (1) is externally connected with a transmission mechanism (9), and the transmission mechanism (9) is used for driving the turnover mechanism (7); The deflection plate (6) is connected with the baffle (8) and is connected with an elastic mechanism (10) for supporting the baffle (8), and the first support (5) is connected with a pushing mechanism (11) for pushing the baffle (8) on one side.

2. The area coater for a reinforced plate forming die according to claim 1, characterized by: The support frame (1) is placed on the ground, the coating machine body (2) is used for coating operation, the conveying roller (3) is used for conveying the mold plate, and the hot air machine (4) is used for dust removal and drying.

3. The area coater for a reinforced plate forming die according to claim 1, characterized by: The turnover mechanism (7) comprises two U-shaped blocks (701) fixedly connected on the inward sides of the two deflection plates (6) respectively, and one-to-one correspondence, one side of the two U-shaped blocks (701) is in contact with the baffle (8), the other side is beveled, the deflection plate (6) and the U-shaped block (701) are located above the conveying roller (3), the two U-shaped blocks (701) and the baffle (8) form a frame structure in cooperation, and correspond to one end of the mold plate.

4. The area coater for a reinforced panel forming mold according to claim 1, characterized by: The transmission mechanism (9) comprises two second supports (901) fixedly connected on the outer sides of the support frame (1) respectively, and one-to-one correspondence, motors (902) are mounted in the two second supports (901) respectively, and output ends of the two motors (902) are fixedly connected with bevel gears (903); Both sides of the support frame (1) are rotatably connected with rotating shafts (904), both outward sides of the two rotating shafts (904) are also fixedly connected with bevel gears (903), the two bevel gears (903) on both sides of the support frame (1) are meshed with each other respectively and one-to-one correspondence, both inward sides of the two rotating shafts (904) are rotatably connected with the two first supports (5) respectively and fixedly connected with the two deflection plates (6) respectively.

5. The area coater for a reinforced panel forming mold according to claim 1, characterized by: The elastic mechanism (10) comprises two third supports (1001) fixedly connected on the inward sides of the two deflection plates (6) respectively, and one-to-one correspondence, fixed shafts (1002) are fixedly connected in the two third supports (1001) respectively, both ends of the baffle (8) are slidably connected with the two fixed shafts (1002) respectively, springs (1003) are sleeved on the outer sides of the two fixed shafts (1002) respectively, and both ends of the spring (1003) are fixedly connected with the third support (1001) inside and one end of the baffle (8).

6. The area coater for a reinforced panel forming mold according to claim 1, characterized by: The pushing mechanism (11) comprises two fourth supports (1101) fixedly connected on the inner walls of the support frame (1) respectively and correspondingly, an electric push rod (1102) is installed in each of the fourth supports (1101), a long rod (1103) is fixedly connected to the output end of each of the electric push rods (1102), a T-shaped block (1104) is fixedly connected to one side of each of the first supports (5), the long rods (1103) are slidably connected with the T-shaped blocks (1104) respectively, an inclined plate (1105) is fixedly connected to the inward side of each of the long rods (1103), and the inclined plates (1105) correspond to the baffles (8).