A feeding device for skin care product production

By setting horizontal impellers with opposite directions in the feeding device, the problems of material accumulation and uneven distribution are solved, and uniform material flow and rapid feeding are achieved, thereby improving production efficiency.

CN224429471UActive Publication Date: 2026-06-30GUANGDONG INTENG BIOTECHNOLOGY CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
GUANGDONG INTENG BIOTECHNOLOGY CO LTD
Filing Date
2025-07-17
Publication Date
2026-06-30

AI Technical Summary

Technical Problem

Existing feeding devices are prone to sludge buildup during the feeding process, resulting in uneven material distribution, slow feeding, and easy blockage, which affects the efficiency of subsequent processing.

Method used

A feeding device for skin care product production was designed, which adopts two pairs of oppositely arranged impellers with horizontal central axes. The impellers are located directly above the feeding port of the feeding cylinder and rotate in opposite directions. The impellers are rotated by a servo motor drive mechanism to realize the flow of materials from top to bottom, prevent sedimentation and increase the mixing degree.

Benefits of technology

It effectively prevents material sedimentation, improves the uniformity of material mixing and feeding speed, avoids clogging, and enhances processing efficiency.

✦ Generated by Eureka AI based on patent content.

Smart Images

  • Figure CN224429471U_ABST
    Figure CN224429471U_ABST
Patent Text Reader

Abstract

This utility model relates to the field of skincare product manufacturing technology, specifically a feeding device for skincare product production. It includes a feeding cylinder with two pairs of opposing impellers inside. The central axis of each impeller is horizontal. A drive mechanism is located at the top of the feeding cylinder to allow the two pairs of impellers to rotate relative to each other. The bottom of the feeding cylinder is funnel-shaped with the opening serving as the feeding port. The feeding cylinder of this utility model has two pairs of opposing impellers at its bottom, both with horizontally aligned central axes. Both impellers are positioned directly above the feeding port of the feeding cylinder. The two opposing impellers rotate in opposite directions, and the entire impeller can rotate around the central axis of the feeding cylinder. This allows the material inside the feeding cylinder to flow from top to bottom, preventing sedimentation. The material rotating on the opposing impellers undergoes compression and release processes, increasing the material's mixing degree. The impellers can push the material towards the feeding port for easy discharge.
Need to check novelty before this filing date? Find Prior Art

Description

Technical Field

[0001] This utility model relates to the field of skin care product manufacturing technology, specifically to a feeding device for skin care product manufacturing. Background Technology

[0002] Skincare products are products that protect the skin. With the continuous progress of society and economy and the enrichment of material life, skincare products are no longer something that only the rich can afford. Nowadays, skincare products have entered ordinary people's homes. They play a great role in improving people's spirit and image.

[0003] Based on existing technology, it has been found that existing feeding devices are prone to sludge accumulation during the feeding process, resulting in uneven material distribution. The material at the bottom is more viscous, which slows down the feeding process and easily causes blockages. At the same time, uneven feeding also affects the efficiency of subsequent processing. Utility Model Content

[0004] In view of the shortcomings of the prior art mentioned in the background, the present invention provides a feeding device for skin care product production.

[0005] This utility model overcomes the above technical problems by adopting the following technical solution:

[0006] A feeding device for skin care product production includes a feeding cylinder, inside which are arranged two pairs of oppositely arranged impellers, the central axis of which is horizontally arranged, and the top of the feeding cylinder is provided with a drive mechanism that enables the two pairs of impellers to rotate relative to each other.

[0007] As a further improvement of this utility model: the bottom of the feeding cylinder is funnel-shaped and the opening is the feeding port, and both pairs of impellers are located directly above the feeding port.

[0008] As a further improvement of this utility model: a discharge port that is connected to and inclined is fixed on the top side of the feeding cylinder.

[0009] As a further embodiment of this utility model: the driving mechanism includes a servo motor, a rotating shaft and a fixed frame. The top of the feeding cylinder is provided with a rotating hole. The rotating shaft is rotatably installed in the rotating hole. One end of the rotating shaft is fixed to the fixed frame. The servo motor is fixed to the feeding cylinder. The output shaft of the servo motor is coaxially fixed with the rotating shaft.

[0010] As a further embodiment of this utility model: the top of the fixing frame has two circular holes I, which are located on both sides of the rotating shaft. The bottom of the fixing frame has two circular holes II, which are coaxially arranged with the circular holes. A rotating rod coaxially arranged with each other is rotatably installed in each of the two circular holes I. A hollow cylinder coaxially arranged with each other is fixed in each of the two circular holes II. The hollow cylinder is sleeved on the corresponding rotating rod. The hollow cylinder and the rotating rod form a rotational engagement. A driven gear coaxially arranged with each of the two rotating rods is fixed on the outer side. The two driven gears mesh with each other. One end of one of the rotating rods is fixed with a driving gear coaxially arranged with it. An internal gear ring coaxially arranged with the rotating shaft is fixed at the top of the feeding cylinder. The driving gear meshes with the internal gear ring.

[0011] As a further embodiment of this utility model: a horizontal cylinder with a central shaft set horizontally and connected to the hollow cylinder is fixed at the bottom end of the hollow cylinder, and a round rod set coaxially with it is rotatably installed inside the horizontal cylinder, and two pairs of impellers are respectively fixed coaxially with the two round rods.

[0012] As a further embodiment of this utility model: one end of the rotating rod is fixed with a bevel gear one coaxially arranged therewith, and the outer side of the round rod is fixed with a bevel gear two coaxially arranged therewith, and the bevel gear one meshes with its corresponding bevel gear two.

[0013] By adopting the above structure, this utility model has the following advantages compared with the prior art:

[0014] The bottom of the feeding cylinder of this utility model is provided with two pairs of impellers arranged opposite each other with their central axes horizontally arranged. Both impellers are located directly above the feeding port of the feeding cylinder. The two impellers arranged oppositely rotate in opposite directions, and the impellers as a whole can rotate around the central axis of the feeding cylinder, so that the material inside the feeding cylinder can flow from top to bottom, preventing sedimentation. Since the material rotating on the two opposite impellers will undergo a compression and release process, the mixing degree of the material will increase. The impellers can push the material towards the feeding port, which is convenient for discharge. Attached Figure Description

[0015] Figure 1 This is a schematic diagram of the overall structure of this utility model.

[0016] Figure 2 This is a schematic diagram of the internal structure of this utility model.

[0017] Figure 3 This is a first-view three-dimensional structural diagram of the drive mechanism of this utility model.

[0018] Figure 4 This is a second-view three-dimensional structural diagram of the drive mechanism of this utility model.

[0019] Figure 5 This is a schematic diagram of the internal structure of the drive mechanism of this utility model.

[0020] Figure 6 For this Figure 5 A schematic diagram of the bottom area structure.

[0021] In the diagram: 1. Feeding cylinder; 2. Feeding port; 3. Discharge port; 4. Servo motor; 5. Internal gear ring; 6. Rotating shaft; 7. Drive gear; 9. Driven gear; 10. Hollow cylinder; 11. Rotating rod; 12. Impeller; 13. Fixed frame; 14. Round rod; 15. Horizontal cylinder; 16. Bevel gear one; 17. Bevel gear two. 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] Please see Figures 1-6 In this embodiment of the present invention, a feeding device for skin care product production includes a feeding cylinder 1. The feeding cylinder 1 has two pairs of oppositely arranged impellers 12 inside. The central axis of the impellers 12 is horizontally arranged. The top of the feeding cylinder 1 is provided with a drive mechanism that enables the two pairs of impellers 12 to rotate relative to each other.

[0024] As can be seen from the above connection relationship, the bottom of the feeding cylinder 1 of this utility model is provided with two pairs of opposite impellers 12 with their central axes horizontally arranged. Both impellers 12 are located directly above the feeding port 2 of the feeding cylinder 1. The two opposite impellers 12 rotate in opposite directions, and the impellers 12 as a whole can rotate around the central axis of the feeding cylinder 1, so that the material inside the feeding cylinder 1 can flow from top to bottom, preventing sedimentation.

[0025] Specifically, the bottom of the feeding cylinder 1 is funnel-shaped and the opening is the feeding port 2 for feeding materials, and the two pairs of impellers 12 are located directly above the feeding port 2.

[0026] Specifically, a discharge port 3 is fixed on one side of the top of the feeding cylinder 1 and is connected to it and is inclined. The material is put into the feeding cylinder 1 through the discharge port 3.

[0027] Specifically, the drive mechanism includes a servo motor 4, a rotating shaft 6, and a fixed frame 13. The top of the feeding cylinder 1 has a rotating hole, and the rotating shaft 6 is rotatably installed in the rotating hole. One end of the rotating shaft 6 is fixed to the fixed frame 13. The servo motor 4 is fixed to the feeding cylinder 1, and the output shaft of the servo motor 4 is coaxially fixed with the rotating shaft 6. The servo motor 4 causes the rotating shaft 6 to rotate through the output shaft, and the rotating shaft 6 drives the fixed frame 13 to rotate.

[0028] Specifically, the top of the fixing frame 13 has two circular holes, one on each side of the rotating shaft 6. The bottom of the fixing frame 13 has two circular holes, the other two coaxially aligned with the first two holes. Rotating rods 11, coaxially aligned with each other, are rotatably mounted in each of the first two holes. Hollow cylinders 10, coaxially aligned with each other, are fixed inside each of the second two holes. The hollow cylinders 10 are fitted onto their corresponding rotating rods 11, forming a rotational fit. Driven gears 9, coaxially aligned with each of the two rotating rods 11, are fixed to their outer sides. Gears 9 mesh with each other. One end of one of the rotating rods 11 is fixed with a drive gear 7 coaxially arranged with it. The top of the feeding cylinder 1 is fixed with an inner gear ring 5 coaxially arranged with the rotating shaft 6. The drive gear 7 meshes with the inner gear ring 5. When the fixed frame 13 rotates, the drive gear 7 on the fixed frame 13 rotates relative to the inner gear ring 5. The drive gear 7 is pushed by the inner gear ring 5. The drive gear 7 drives the rotating rod 11 to rotate. The two rotating rods 11 rotate through two meshing driven gears 9, and the rotation directions of the two rotating rods 11 are opposite.

[0029] Specifically, a horizontal cylinder 15 with a horizontally arranged central shaft and connected to the hollow cylinder 10 is fixed at the bottom end of the hollow cylinder 10. A round rod 14 coaxially arranged with the round rod 14 is rotatably installed inside the horizontal cylinder 15. Two pairs of impellers 12 are respectively fixed coaxially with the two round rods 14. A bevel gear 16 coaxially arranged with the rotating rod 11 is fixed at one end. A bevel gear 17 coaxially arranged with the round rod 14 is fixed on the outside of the round rod 14. The bevel gear 16 meshes with its corresponding bevel gear 17. The bevel gear 16 at the bottom end of the rotating rod 11 rotates synchronously with the rotating rod 11. The bevel gear 16 pushes its corresponding bevel gear 17. The bevel gear 17 drives the round rod 14 to rotate. The round rod 14 drives the impellers 12 to rotate. Since the rotation directions of the two rotating rods 11 are opposite, the rotation directions of the two impellers 12 are opposite.

[0030] Working principle: Servo motor 4 drives rotating shaft 6 to rotate via output shaft, rotating shaft 6 drives fixed frame 13 to rotate; when fixed frame 13 rotates, drive gear 7 on fixed frame 13 rotates relative to internal gear ring 5, drive gear 7 is driven by internal gear ring 5, drive gear 7 drives rotating rod 11 to rotate, two rotating rods 11 rotate through two meshing driven gears 9, and the rotation directions of the two rotating rods 11 are opposite, bevel gear 16 at the bottom of rotating rod 11 rotates synchronously with rotating rod 11, bevel gear 16 drives its corresponding bevel gear 17, bevel gear 17 drives round rod 14 to rotate, round rod 14 drives impeller 12 to rotate, since the rotation directions of the two rotating rods 11 are opposite, the rotation directions of the two impellers 12 are opposite;

[0031] Rotate the impeller 12 on the left side clockwise so that the impeller 12 can push the material towards the feed port 2 for easy discharge;

[0032] In summary, the bottom of the feeding cylinder 1 is provided with two pairs of impellers 12 that are arranged opposite each other and whose central axes are both horizontal. Both impellers 12 are located directly above the feeding port 2 of the feeding cylinder 1. The two impellers 12 that are arranged oppositely rotate in opposite directions, and the impellers 12 as a whole can rotate around the central axis of the feeding cylinder 1, so that the material inside the feeding cylinder 1 can flow from top to bottom, preventing sedimentation. Since the material rotating on the two impellers 12 that are arranged oppositely undergoes a compression and release process, the mixing degree of the material increases.

[0033] 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.

Claims

1. A feeding device for skincare product production, comprising a feeding cylinder (1), characterized in that, The feeding cylinder (1) is equipped with two pairs of oppositely arranged impellers (12), the central axis of the impellers (12) is horizontally arranged, and the top of the feeding cylinder (1) is equipped with a drive mechanism that enables the two pairs of impellers (12) to rotate relative to each other.

2. The feeding device for skincare product production according to claim 1, characterized in that, The bottom of the feeding cylinder (1) is funnel-shaped and the opening is the feeding port (2). Both pairs of impellers (12) are located directly above the feeding port (2).

3. The feeding device for skincare product production according to claim 1, characterized in that, The top of one side of the feeding cylinder (1) is fixed with a discharge port (3) that is connected to it and is inclined.

4. The feeding device for skincare product production according to claim 3, characterized in that, The drive mechanism includes a servo motor (4), a rotating shaft (6), and a fixed frame (13). The top of the feeding cylinder (1) is provided with a rotating hole. The rotating shaft (6) is rotatably installed in the rotating hole. One end of the rotating shaft (6) is fixed to the fixed frame (13). The servo motor (4) is fixed to the feeding cylinder (1). The output shaft of the servo motor (4) is coaxially fixed with the rotating shaft (6).

5. The feeding device for skincare product production according to claim 4, characterized in that, The top of the fixed frame (13) has two circular holes, which are located on both sides of the rotating shaft (6). The bottom of the fixed frame (13) has two circular holes, which are coaxial with the circular holes. Rotating rods (11) coaxial with each other are rotatably installed in both circular holes. Hollow cylinders (10) coaxial with each other are fixed in the two circular holes. The hollow cylinders (10) are sleeved on the corresponding rotating rods (11). The hollow cylinders (10) and rotating rods (11) form a rotational fit. Driven gears (9) coaxial with each of the two rotating rods (11) are fixed on the outside of each of the two rotating rods (11). The two driven gears (9) mesh with each other. One end of one of the rotating rods (11) is fixed with a driving gear (7) coaxial with it. An internal gear ring (5) coaxial with the rotating shaft (6) is fixed at the top of the feeding cylinder (1). The driving gear (7) meshes with the internal gear ring (5).

6. The feeding device for skincare product production according to claim 5, characterized in that, The bottom end of the hollow cylinder (10) is fixed with a horizontal cylinder (15) whose central axis is set horizontally and connected to the hollow cylinder (10). Inside the horizontal cylinder (15), a round rod (14) is rotatably installed and coaxially arranged with it. Two pairs of impellers (12) are respectively fixed coaxially with the two round rods (14).

7. The feeding device for skincare product production according to claim 6, characterized in that, One end of the rotating rod (11) is fixed with a bevel gear one (16) coaxially arranged with it, and the outer side of the round rod (14) is fixed with a bevel gear two (17) coaxially arranged with it. The bevel gear one (16) meshes with its corresponding bevel gear two (17).