A feeding device for paint production

By designing components such as height adjustment components and material feeding control structures, the problems of uneven material feeding and low automation in existing paint production equipment have been solved, achieving precise control and stable conveying of materials, and improving production efficiency and safety.

CN224429478UActive Publication Date: 2026-06-30JIANGXI YANYUCHEN NEW MATERIAL TECHNOLOGY CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
JIANGXI YANYUCHEN NEW MATERIAL TECHNOLOGY CO LTD
Filing Date
2025-07-17
Publication Date
2026-06-30

AI Technical Summary

Technical Problem

Existing feeding devices used in paint production cannot flexibly adjust the opening of the feeding port, resulting in uneven feeding or material leakage. In addition, the low level of automation increases labor costs and affects production efficiency and safety.

Method used

A feeding device comprising a height adjustment component, a feeding control structure, a conveying structure, and a transmission structure is designed. Through components such as a sliding support plate, a telescopic baffle plate, a conveyor belt, and a drive motor, the device achieves precise control over the material flow rate and direction, ensuring uniform material distribution and stable conveying.

Benefits of technology

It improves the flexibility and applicability of the feeding device, enhances the accuracy and safety of material handling, reduces energy consumption and maintenance costs, and improves the automation level and overall quality of coating production.

✦ Generated by Eureka AI based on patent content.

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Abstract

This utility model discloses a feeding device for paint production, including a feeding cylinder, a height adjustment component, a feeding control structure, a conveying structure, and a transmission structure. A sliding support plate is installed on the height adjustment component, a receiving funnel is installed on the upper surface of the sliding support plate, the feeding cylinder is installed at the bottom of the sliding support plate, a conveying structure is installed at the top end of the receiving funnel, and a transmission structure is installed at the bottom end of the conveying structure. This utility model ensures the continuity and stability of paint conveying through the connection between the conveyor belt and the driven wheel on the conveying structure, improving the automation level of paint production. Furthermore, the separator plate installed on the conveyor belt effectively solves the problem of paint mixing or contamination that may occur during conveying. This allows different types of paint to be separated, ensuring that each paint maintains its original properties and characteristics, improving the efficiency and safety of paint conveying, and also contributing to improving the overall quality of paint production.
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Description

Technical Field

[0001] This utility model relates to the field of coating production technology, specifically to a material feeding device for coating production. Background Technology

[0002] Paint, a widely used material applied to the surfaces of protected or decorated objects in fields such as construction, furniture, automobiles, and aerospace, is of paramount importance in terms of performance and quality. It typically consists of resins, oils, emulsions, etc., as its main components, which provide the paint with basic physical and chemical properties such as adhesion, hardness, gloss, and weather resistance. In addition, auxiliary materials such as pigments and fillers are added to impart specific colors, hiding power, and textures to the paint. Meanwhile, additives are also an indispensable part of paint formulations; they can adjust the paint's viscosity, leveling properties, drying speed, and other properties to meet different application requirements. In the paint production process, material feeding is a crucial step. The accuracy and uniformity of feeding directly affect the quality and stability of the paint. Therefore, paint manufacturers typically employ advanced automated equipment and control systems to ensure precise material feeding and mixing. These devices can automatically meter and deliver various main materials, auxiliary materials, and additives according to formulation requirements, achieving precise proportions and efficient mixing, thereby producing paint products with stable quality and excellent performance.

[0003] The existing material feeding devices used in paint production have the following drawbacks:

[0004] 1. Most existing feeding devices used in paint production cannot adjust the opening of the feeding port, which reduces the flexibility of feeding control. Furthermore, uneven feeding or material leakage often occurs due to improper manual operation, which reduces the overall practicality of the feeding device.

[0005] 2. Existing material feeding devices for paint production have poor automation levels and mostly rely on manual operation, which increases labor costs and affects production efficiency. Moreover, most devices cannot solve the problem of paint mixing or contamination that may occur during the transportation process, reducing the efficiency and safety of paint transportation and failing to guarantee the overall quality of paint production. Therefore, we propose a material feeding device for paint production to solve the existing problems. Summary of the Invention

[0006] The purpose of this utility model is to provide a feeding device for paint production, so as to solve the problems mentioned in the background art.

[0007] To achieve the above objectives, this utility model provides the following technical solution: a feeding device for paint production, comprising a feeding cylinder, a height adjustment component, a feeding control structure, a conveying structure, and a transmission structure; a sliding support plate is installed on the height adjustment component, and a receiving funnel is installed on the upper surface of the sliding support plate. The height adjustment component can flexibly adjust the height of the sliding support plate to adapt to different working scenarios or material handling needs. This height adjustability ensures that the receiving funnel can accurately connect to different material sources or conveying equipment, improving the efficiency and accuracy of material transmission; the design of the sliding support plate allows the receiving funnel to move within a certain range in the horizontal direction. This sliding function facilitates adjustment according to actual operational needs. The placement of the material funnel enhances the flexibility and adaptability of the equipment. The installation of the receiving funnel allows materials to be smoothly guided into designated processing areas or containers. The shape and size design of the receiving funnel typically optimizes the material flow path, reducing the risk of blockage or spillage, thereby improving the efficiency and safety of the entire material handling process. A discharge cylinder is installed at the bottom of the sliding support plate. As the main material channel, the discharge cylinder is designed to be not only robust and durable but also has a smooth inner wall to reduce resistance during material descent, further ensuring smooth and unobstructed material flow. A telescopic baffle is installed on one side of the sliding support plate. This telescopic baffle plays a crucial role, allowing adjustment as needed during material discharge. The telescopic baffle plate, with its open or closed state, effectively controls the flow rate and direction of materials. When it's necessary to pause or adjust the material feeding speed, the telescopic baffle plate responds quickly, achieving precise control of material flow through its telescopic function. This design not only improves the flexibility of material handling but also helps avoid material waste and environmental pollution. A conveying structure is installed at the top of the receiving hopper, and a transmission structure is installed at the bottom. The main function of the conveying structure is to efficiently transport materials from the source to the receiving hopper. Its design typically includes conveyor belts or screw conveyors to ensure continuous and stable material flow. The transmission structure serves as the power source for the conveying structure, providing the necessary power through the coordinated action of components such as motors and reducers. The required driving force enables it to run at a predetermined speed and direction. This design not only improves the efficiency and stability of material conveying, but also helps to reduce energy consumption and maintenance costs. The close cooperation between the conveying structure and the transmission structure makes the entire feeding device more efficient and flexible in the material handling process, and can better meet the actual needs in paint production. A material distribution funnel is installed on the top of the conveying structure, and feeding control structures are installed on both sides of the conveying structure. The design of the material distribution funnel is to distribute the material evenly on the conveying structure, avoiding low conveying efficiency caused by material accumulation or uneven distribution. Its structure usually includes a conical or funnel-shaped main body, and the bottom matches the width of the conveying structure to ensure that the material can evenly cover the entire conveying surface.The material feeding control structure is located on both sides of the conveying structure. By adjusting its opening degree, the speed and amount of material falling onto the conveying structure can be precisely controlled. This design further enhances the accuracy and flexibility of material handling, making the entire feeding device more efficient and reliable in the paint production process.

[0008] Preferably, the height adjustment component is provided with a stable fixing base plate. This stable fixing base plate is designed to ensure the stability and accuracy of the height adjustment component. Its material is typically high-strength and corrosion-resistant, such as stainless steel or alloy, to increase its load-bearing capacity and service life. A sliding guide rod slides on the upper surface of the stable fixing base plate, and a support top plate is installed on the top of the stable fixing base plate. The support top plate is fastened to the stable fixing base plate with high-strength bolts, forming a stable support structure that effectively prevents shaking or displacement during use, thereby ensuring the stability and safety of the entire feeding device when adjusting its height. The guide rod moves flexibly along a pre-set slide rail on the stable fixing base plate. This design allows the height adjustment component to adjust its overall height as needed to adapt to paint production equipment of different heights. This flexibility of the height adjustment component not only improves the applicability of the feeding device but also facilitates operation. The installation, commissioning, and maintenance of the equipment by the staff further improved the overall efficiency and operational stability of the paint production line. The supporting top plate is equipped with a lifting electric cylinder mounted on a bracket. The lifting electric cylinder is slidably connected to the sliding support plate via a movable rod. Sliding guide rods are mounted on both sides of the sliding support plate, allowing it to slide smoothly up and down along the guide rods. When the lifting electric cylinder is activated, the movable rod pushes the sliding support plate and the material it carries to move up and down. This design ensures that the material can accurately reach the predetermined conveying height. The precise control and stable performance of the lifting electric cylinder guarantee the uniformity and continuity of the material during the feeding process, avoiding material accumulation or uneven conveying. Furthermore, the tight fit between the sliding support plate and the sliding guide rods further enhances the stability and durability of the feeding device, enabling the entire device to maintain high efficiency and reliable performance even during long-term operation.

[0009] Preferably, the feeding control structure is provided with a telescopic shell. The material selection of the telescopic shell has also been carefully considered. It is made of high-strength and wear-resistant material to ensure stability and durability during long-term use. A sliding groove is provided on the front surface of the telescopic shell, and a pulling block is installed on the sliding groove. The design of the pulling block allows the user to easily manually operate the extension and retraction of the telescopic shell, thereby adjusting the opening of the feeding port. This design not only improves the flexibility of material feeding control but also makes the operation more intuitive and simple. When the feeding amount needs to be adjusted, the user only needs to move the telescopic housing along the sliding groove by pulling the block to achieve quick and accurate adjustment of the feeding port. In addition, the tight fit between the sliding groove and the pulling block ensures the stability and accuracy of the telescopic housing during movement, avoiding problems such as uneven feeding or material leakage caused by improper operation. This design not only improves the practicality of the feeding device but also further enhances its overall reliability and durability. The front surface of the pulling block is equipped with a pulling handle and a locking device. The design of the pulling handle allows the operator to easily adjust the telescopic housing manually to adapt to different feeding height requirements. The locking device ensures that the telescopic housing can be firmly locked after being adjusted to the appropriate position, preventing accidental movement during use, thereby ensuring the stability and safety of the feeding process. This design not only improves the flexibility and applicability of the feeding device but also further enhances the overall structural stability and reliability.

[0010] Preferably, a telescopic rod is installed on the rear surface of the pulling block, a push plate is installed at one end of the telescopic rod, and a baffle plate is installed on the top of the push plate. The baffle plate further enhances the functionality of the material feeding control structure. During the coating feeding process, the baffle plate can be adjusted in a timely manner according to the flow rate and speed of the coating, effectively preventing excessive coating feeding or clogging of the feeding port, and ensuring the uniformity and stability of coating feeding. The telescopic function of the telescopic rod allows the push plate to drive the baffle plate to move back and forth, thereby achieving precise adjustment of the coating feeding port. This design not only improves the accuracy of coating feeding but also makes the feeding process more flexible and efficient. By comprehensively utilizing the telescopic shell, pulling block, telescopic rod, and baffle plate, operators can achieve comprehensive control and adjustment of the coating feeding process, thereby meeting various needs in the coating production process.

[0011] Preferably, the conveying structure is equipped with conveyor frames, and a conveyor belt is installed between the conveyor frames. Removable mounting sleeves are installed on both sides of the conveyor rollers on one side of the conveyor belt. The removable mounting sleeves make the replacement and maintenance of the conveyor rollers more convenient and faster, reducing the labor intensity and time cost for operators. One end of the conveyor roller on the other side of the conveyor belt is connected to a driven wheel. The connection between the conveyor belt and the driven wheel ensures the continuity and stability of paint conveying, further improving the automation level of paint production. A separator plate is installed on the conveyor belt. The separator plate effectively solves the problem of paint mixing or contamination that may occur during the conveying process. By installing the separator plate on the conveyor belt, different types of paint can be separated, ensuring that each paint maintains its original properties and characteristics. This design not only improves the efficiency and safety of paint conveying but also helps to improve the overall quality of paint production.

[0012] Preferably, the transmission structure is equipped with a drive motor, and a gearbox is installed on the output end of the drive motor. The drive motor serves as the power source for the transmission structure, and its stable output provides reliable power for the entire paint conveying process. The addition of the gearbox allows the transmission structure to adjust its speed according to actual needs, thereby better adapting to the conveying requirements of different paints and improving the flexibility and adaptability of paint production. The drive pulley on the gearbox is connected to the driven pulley via a drive belt. The close connection between the drive pulley and the driven pulley via the drive belt ensures the continuity and stability of paint conveying, further improving the automation level and production efficiency of paint production. Furthermore, a protective plate is installed on one side of the conveyor frame, located above the drive pulley, drive belt, and driven pulley. This protective plate effectively prevents paint or other debris from splashing into the transmission structure, avoiding damage to the transmission structure or affecting its normal operation. It also protects operators from accidental injury caused by the transmission structure. This design not only improves the reliability and durability of the transmission structure but also ensures the continuity and stability of the paint conveying process, providing a strong guarantee for the high efficiency and automation of paint production.

[0013] Compared with the prior art, the beneficial effects of this utility model are:

[0014] 1. This utility model improves the flexibility and applicability of the feeding device by using the overall components of the feeding control structure in coordination, and further enhances the stability and reliability of its overall structure. The design of the pull block allows users to easily and manually operate the extension and retraction of the telescopic shell, thereby adjusting the opening of the feeding port, improving the flexibility of feeding control, and making the operation process more intuitive and simple. Moreover, the tight cooperation between the sliding groove and the pull block ensures the stability and accuracy of the telescopic shell during movement, avoiding problems such as uneven feeding or material leakage caused by improper operation, improving the practicality of the feeding device, and further enhancing its overall reliability and durability.

[0015] 2. This utility model ensures the continuity and stability of paint conveying by connecting the conveyor belt and the driven wheel on the conveying structure, thereby improving the automation level of paint production. Furthermore, the separator installed on the conveyor belt effectively solves the problem of paint mixing or contamination that may occur during the conveying process. This allows different types of paint to be separated, ensuring that each paint retains its original properties and characteristics, improving the efficiency and safety of paint conveying, and also helping to improve the overall quality of paint production. Attached Figure Description

[0016] Figure 1 This is a schematic diagram of the overall structure of this utility model;

[0017] Figure 2 This is a schematic diagram on the right side of the present invention;

[0018] Figure 3 This is a schematic diagram of the height adjustment component of this utility model;

[0019] Figure 4 This is a schematic diagram of the material feeding control structure of this utility model;

[0020] Figure 5 This is a schematic diagram showing the cooperation between the conveying structure and the transmission structure of this utility model;

[0021] In the diagram: 1. Feeding cylinder; 2. Sliding support plate; 3. Receiving funnel; 4. Telescopic baffle plate; 5. Height adjustment component; 51. Lifting electric cylinder; 52. Support top plate; 53. Sliding guide rod; 54. Stable fixed base plate; 6. Feeding control structure; 61. Telescopic housing; 62. Sliding groove; 63. Pulling block; 64. Pulling handle; 65. Locking component; 66. Telescopic rod; 67. Push plate; 68. Baffle plate; 7. Distributing funnel; 8. Conveying structure; 81. Conveying frame; 82. Conveying belt; 83. Separator plate; 84. Removable mounting sleeve; 85. Conveying roller; 9. Transmission structure; 91. Drive motor; 92. Gearbox; 93. Driven wheel; 94. Protective plate. Detailed Implementation

[0022] 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.

[0023] Example 1

[0024] like Figure 1-5As shown, one embodiment of this utility model is a feeding device for paint production, comprising a feeding cylinder 1, a height adjustment component 5, a feeding control structure 6, a conveying structure 8, and a transmission structure 9. A sliding support plate 2 is mounted on the height adjustment component 5, and a receiving funnel 3 is mounted on the upper surface of the sliding support plate 2. The height adjustment component 5 can flexibly adjust the height of the sliding support plate 2 to adapt to different working scenarios or material handling needs. This height adjustability ensures that the receiving funnel 3 can accurately connect to different material sources or conveying equipment, improving the efficiency and accuracy of material transmission. The design of the sliding support plate 2 allows the receiving funnel 3 to move within a certain range in the horizontal direction. This sliding function facilitates adjusting the position of the receiving funnel 3 according to actual operational needs, enhancing the flexibility and adaptability of the equipment. The installation of the receiving funnel 3 allows materials to be smoothly introduced into designated processing areas or containers. The shape and size design of the receiving funnel 3 can usually optimize the material flow path, reduce the risk of material blockage or overflow, thereby improving the overall material handling efficiency. To ensure the efficiency and safety of the material handling process, a feeding cylinder 1 is installed at the bottom of the sliding support plate 2. As the main channel for materials, the feeding cylinder 1 is designed to be not only sturdy and durable, but also has a smooth inner wall to reduce the resistance of materials during the falling process, further ensuring that the materials can flow smoothly and without obstruction. A telescopic baffle plate 4 is installed on one side of the sliding support plate 2. The setting of the telescopic baffle plate 4 plays a key role. It can adjust the opening or closing state according to actual needs during the material feeding process, thereby effectively controlling the flow rate and direction of materials. When it is necessary to pause or adjust the material feeding speed, the telescopic baffle plate 4 can respond quickly. Through its telescopic function, it can achieve precise control of the material flow. This design not only improves the flexibility of material handling, but also helps to avoid material waste and environmental pollution. A conveying structure 8 is installed at the top end of the receiving funnel 3, and a transmission structure 9 is installed at the bottom end of the conveying structure 8. The main function of the conveying structure 8 is to efficiently transport materials from the source to the receiving funnel 3. Its design usually includes a conveyor belt or screw conveyor, etc., to ensure that the materials can flow continuously and stably.The transmission structure 9 serves as the power source for the conveying structure 8. Through the coordinated action of components such as the motor and reducer, it provides the necessary driving force to the conveying structure 8, enabling it to run at a predetermined speed and direction. This design not only improves the efficiency and stability of material conveying but also helps reduce energy consumption and maintenance costs. The close cooperation between the conveying structure 8 and the transmission structure 9 makes the entire feeding device more efficient and flexible in the material handling process, better meeting the actual needs of paint production. A material distribution funnel 7 is installed on the top of the conveying structure 8, and feeding control structures 6 are installed on both sides of the conveying structure 8. The design of the material distribution funnel 7 is intended to evenly distribute the material onto the conveying structure 8, avoiding low conveying efficiency caused by material accumulation or uneven distribution. Its structure typically includes a conical or funnel-shaped main body, with the bottom matching the width of the conveying structure 8 to ensure that the material can evenly cover the entire conveying surface. The feeding control structures 6 are located on both sides of the conveying structure 8. By adjusting their opening degree, the speed and amount of material falling onto the conveying structure 8 can be precisely controlled. This design further enhances the accuracy and flexibility of material handling, making the entire feeding device more efficient and reliable in the paint production process. ;

[0025] Example 2

[0026] like Figure 3As shown, the present invention proposes a feeding device for paint production. Compared with Embodiment 1, this embodiment further includes: a stable fixing base plate 54 provided on the height adjustment component 5. The stable fixing base plate 54 is designed to ensure the stability and accuracy of the height adjustment component 5. Its material is usually high-strength and corrosion-resistant, such as stainless steel or alloy, to increase its load-bearing capacity and service life. A sliding guide rod 53 slides on the upper surface of the stable fixing base plate 54. A support top plate 52 is installed on the top of the stable fixing base plate 54. The support top plate 52 is fastened to the stable fixing base plate 54 by high-strength bolts to form a stable support structure, which can effectively prevent shaking or displacement during use, thereby ensuring the stability and safety of the entire feeding device when adjusting the height. The sliding guide rod 53 moves flexibly along the preset slide rail on the stable fixing base plate 54. This design allows the height adjustment component 5 to adjust its overall height as needed to adapt to paint production equipment of different heights. This flexibility of the height adjustment component 5... This design not only improves the applicability of the feeding device but also facilitates the installation, debugging, and maintenance of the equipment by operators, further enhancing the overall efficiency and operational stability of the paint production line. The supporting top plate 52 is equipped with a lifting electric cylinder 51 mounted on a bracket. The lifting electric cylinder 51 is slidably connected to the sliding support plate 2 via a movable rod. Sliding guide rods 53 are mounted on both sides of the sliding support plate 2, allowing it to slide smoothly up and down along the sliding guide rods 53. When the lifting electric cylinder 51 is activated, the movable rod pushes the sliding support plate 2 and the material it carries to move up and down. This design ensures that the material can accurately reach the predetermined conveying height. The precise control and stable performance of the lifting electric cylinder 51 guarantee the uniformity and continuity of the material during the feeding process, avoiding material accumulation or uneven conveying. Furthermore, the close cooperation between the sliding support plate 2 and the sliding guide rods 53 further enhances the stability and durability of the feeding device, enabling the entire device to maintain high efficiency and reliable performance even during long-term operation.

[0027] In this embodiment, as Figure 4As shown, the feeding control structure 6 is equipped with a telescopic housing 61. The material selection of the telescopic housing 61 has also been carefully considered. It is made of high-strength, wear-resistant material to ensure stability and durability during long-term use. A sliding groove 62 is provided on the front surface of the telescopic housing 61, and a pulling block 63 is installed on the sliding groove 62. The design of the pulling block 63 allows users to easily and manually operate the extension and retraction of the telescopic housing 61 to adjust the opening of the feeding port. This design not only improves the flexibility of feeding control but also makes the operation process more intuitive and simple. When it is necessary to adjust the feeding amount, the user only needs to move the telescopic housing 61 along the sliding groove 62 by pulling the block 63 to achieve quick and accurate adjustment of the feeding port. In addition, the tight fit between the sliding groove 62 and the pulling block 63... This design ensures the stability and accuracy of the telescopic housing 61 during movement, avoiding uneven material feeding or leakage caused by improper operation. This design not only improves the practicality of the feeding device but also further enhances its overall reliability and durability. The front surface of the pulling block 63 is equipped with a pulling handle 64 and a locking element 65. The design of the pulling handle 64 allows operators to easily adjust the telescopic housing 61 manually to adapt to different feeding height requirements. The locking element 65 ensures that the telescopic housing 61 can be firmly locked after being adjusted to the appropriate position, preventing accidental movement during use, thereby ensuring the stability and safety of the feeding process. This design not only improves the flexibility and applicability of the feeding device but also further enhances the stability and reliability of its overall structure.

[0028] In this embodiment, as Figure 4 As shown, a telescopic rod 66 is installed on the rear surface of the pull block 63. A push plate 67 is installed at one end of the telescopic rod 66, and a baffle plate 68 is installed on the top of the push plate 67. The baffle plate 68 further enhances the functionality of the feeding control structure 6. During the coating feeding process, the baffle plate 68 can be adjusted in a timely manner according to the flow rate and speed of the coating, effectively preventing excessive coating feeding or clogging of the feeding port, and ensuring the uniformity and stability of coating feeding. The telescopic function of the telescopic rod 66 allows the push plate 67 to drive the baffle plate 68 to move back and forth, thereby achieving precise adjustment of the coating feeding port. This design not only improves the accuracy of coating feeding but also makes the feeding process more flexible and efficient. By comprehensively utilizing the telescopic shell 61, the pull block 63, the telescopic rod 66, and the baffle plate 68, operators can achieve comprehensive control and adjustment of the coating feeding process, thereby meeting various needs in the coating production process.

[0029] In this embodiment, as Figure 5As shown, the conveying structure 8 is equipped with a conveyor frame 81, and a conveyor belt 82 is installed between the conveyor frames 81. Removable mounting sleeves 84 are installed on both sides of the conveyor roller 85 on one side of the conveyor belt 82. The removable mounting sleeves 84 make the replacement and maintenance of the conveyor roller 85 more convenient and faster, reducing the labor intensity and time cost of operators. One end of the conveyor roller 85 on the other side of the conveyor belt 82 is connected to the driven wheel 93. The connection between the conveyor belt 82 and the driven wheel 93 ensures the continuity and stability of paint conveying, further improving the automation level of paint production. A separator plate 83 is installed on the conveyor belt 82. The separator plate 83 effectively solves the problem of paint mixing or contamination that may occur during the conveying process. By installing the separator plate 83 on the conveyor belt 82, different types of paint can be separated, ensuring that each paint can maintain its original properties and characteristics. This design not only improves the efficiency and safety of paint conveying but also helps to improve the overall quality of paint production.

[0030] In this embodiment, as Figure 5 As shown, the transmission structure 9 is equipped with a transmission motor 91, and a gearbox 92 is installed on the output end of the transmission motor 91. The transmission motor 91 serves as the power source for the transmission structure 9, and its stable output provides reliable power for the entire paint conveying process. The addition of the gearbox 92 allows the transmission structure 9 to adjust its speed according to actual needs, thereby better adapting to the conveying requirements of different paints and improving the flexibility and adaptability of paint production. The driving pulley on the gearbox 92 is connected to the driven pulley 93 via a transmission belt. The tight connection between the driving pulley and the driven pulley 93 ensures the continuity and stability of paint conveying. This design significantly improves the automation level and production efficiency of paint production. A protective plate 94 is installed on one side of the conveyor frame 81, positioned above the drive wheel, transmission belt, and driven wheel 93. This effectively prevents paint or other debris from splashing into the transmission structure 9, avoiding damage or disruption to its normal operation. It also protects operators from accidental injury to the transmission structure 9. This design not only enhances the reliability and durability of the transmission structure 9 but also ensures the continuity and stability of the paint conveying process, providing a strong guarantee for the high efficiency and automation of paint production.

[0031] It will be apparent to those skilled in the art that this invention is not limited to the details of the exemplary embodiments described above, and that it can be implemented in other specific forms without departing from the spirit or essential characteristics of this invention. Therefore, the embodiments should be considered illustrative and non-limiting in all respects, and the scope of this invention is defined by the appended claims rather than the foregoing description. Thus, it is intended that all variations falling within the meaning and scope of equivalents of the claims be included within this invention. No reference numerals in the claims should be construed as limiting the scope of the claims.

Claims

1. A feeding device for paint production, comprising a feeding cylinder (1), a height adjustment component (5), a feeding control structure (6), a conveying structure (8), and a transmission structure (9); characterized in that: The height adjustment component (5) is equipped with a sliding support plate (2), a receiving funnel (3) is installed on the upper surface of the sliding support plate (2), a discharge cylinder (1) is installed at the bottom of the sliding support plate (2), a telescopic baffle plate (4) is installed on one side of the sliding support plate (2), a conveying structure (8) is installed at the top end of the receiving funnel (3), a transmission structure (9) is installed at the bottom end of the conveying structure (8), a distributing funnel (7) is installed at the top of the conveying structure (8), and a discharge control structure (6) is installed on both sides of the conveying structure (8).

2. The feeding device for paint production according to claim 1, characterized in that: The height adjustment component (5) is provided with a stable fixing base plate (54), the upper surface of the stable fixing base plate (54) is slidable guide rod (53), the top of the stable fixing base plate (54) is installed with a support top plate (52), the support top plate (52) is installed with a lifting electric cylinder (51) through a bracket, the lifting electric cylinder (51) is slidably connected to the sliding support plate (2) through a movable rod, and the two sides of the sliding support plate (2) are installed on the sliding guide rod (53).

3. The feeding device for paint production according to claim 1, characterized in that: The feeding control structure (6) is provided with a telescopic housing (61), and a sliding groove (62) is provided on the front surface of the telescopic housing (61). A pulling block (63) is installed on the sliding groove (62), and a pulling handle (64) and a locking member (65) are installed on the front surface of the pulling block (63).

4. The feeding device for paint production according to claim 3, characterized in that: A telescopic rod (66) is installed on the rear surface of the pull block (63), a push plate (67) is installed at one end of the telescopic rod (66), and a baffle plate (68) is installed on the top of the push plate (67).

5. The feeding device for paint production according to claim 4, characterized in that: The conveying structure (8) is provided with a conveying frame (81), and a conveying belt (82) is installed between the conveying frames (81). A detachable mounting sleeve (84) is installed on both sides of the conveying roller (85) on one side of the conveying belt (82). One end of the conveying roller (85) on the other side of the conveying belt (82) is connected to the driven wheel (93). A partition plate (83) is installed on the conveying belt (82).

6. The feeding device for paint production according to claim 1, characterized in that: The transmission structure (9) is equipped with a transmission motor (91), and a gearbox (92) is installed on the output end of the transmission motor (91). The drive wheel on the gearbox (92) is connected to the driven wheel (93) via a transmission belt, and a protective plate (94) is installed on one side of the conveyor frame (81). The protective plate (94) is located above the drive wheel, the transmission belt and the driven wheel (93).