Improved structure of a micro-bead exfoliating cream

Abstract

This utility model discloses an improved structure for a microbead grinding machine for removing dead skin emulsions, including a base, a grinding cylinder fixedly connected to the base, a grinding motor installed at the bottom of the grinding cylinder, an emulsion distribution mechanism installed inside the grinding cylinder, and an adjustment mechanism installed on the grinding cylinder. The emulsion distribution mechanism includes a fixed grinding disc and a rotating grinding disc, with two support plates fixedly connected to the fixed grinding disc, and connecting pipes fixedly connected to the bottom ends of the two support plates. This belongs to the technical field of grinding machines. In this improved structure, the emulsion is delivered into the guide cavity of the distribution seat by a delivery pump, and the drive motor rotates the outlet seat. The emulsion flows out through the opening on the outlet seat, allowing it to flow evenly between the fixed grinding disc and the rotating grinding disc. The grinding motor drives the rotating grinding disc to rotate, and the microbeads are thoroughly ground using both the rotating and fixed grinding discs, effectively improving the grinding effect.

Description

Technical Field

[0001] This utility model relates to the field of grinding machine technology, specifically to an improved structure of a microbead grinding machine for removing dead skin emulsion. Background Technology

[0002] Exfoliating lotions are mainly used to remove the aged stratum corneum on the skin surface, helping to improve problems such as rough and dull skin. During the production process of exfoliating lotions, a grinding machine is used to grind the microbeads inside the lotion. In the existing technology, after the lotion is passed into the grinding machine, the lotion is unevenly distributed, making it difficult for the lotion to be fully ground by the grinding disc, resulting in an unsatisfactory grinding effect.

[0003] For example, patent publication number CN222155146U describes a fine grinding machine, including a shell. A motor is fixedly connected inside the shell, and a threaded rod is fixedly connected to the output end of the motor. A moving block is threadedly connected to the outer side of the threaded rod. A base is fixedly connected to the front of the moving block, and a soft brush is fixedly connected to the bottom of the base. A first slider is fixedly connected to the front of the base. The same support block is fixedly connected to the front and rear sides of the inner wall of the shell. This fine grinding machine has advantages such as a collection function. It solves the problem that during use, the friction between the grinding disc and the material generates significant heat, requiring cooling with grinding fluid. However, most existing grinding machines lack a grinding fluid collection function, resulting in grinding fluid remaining inside the machine after cooling, requiring manual cleaning and reducing the grinding efficiency. Furthermore, the uneven distribution of the emulsion after it enters the grinding machine makes it difficult for the emulsion to be fully ground by the grinding disc, resulting in an unsatisfactory grinding effect. Utility Model Content

[0004] To address the shortcomings of existing technologies, this utility model provides an improved structure for a microbead grinding machine for removing dead skin emulsions. This solves the problem that uneven distribution of the emulsion after it enters the grinding machine makes it difficult for the emulsion to be fully ground by the grinding disc, resulting in an unsatisfactory grinding effect.

[0005] To achieve the above objectives, this utility model is implemented through the following technical solution: an improved structure for a microbead grinding machine for removing dead skin emulsion, including a base, a grinding cylinder fixedly connected to the base, a grinding motor installed at the bottom of the grinding cylinder, an emulsion distribution mechanism installed inside the grinding cylinder, and an adjustment mechanism installed on the grinding cylinder;

[0006] The emulsion distribution mechanism includes a fixed grinding disc and a rotating grinding disc. Two support plates are fixedly connected to the fixed grinding disc. Connecting pipes are fixedly connected to the bottom ends of the two support plates. Guide seats are fixedly connected to the bottom ends of the two connecting pipes. A distribution seat is rotatably connected to the bottom of the guide seat. A flow guiding cavity is opened on the inner side of the distribution seat. A bearing is provided between the distribution seat and the guide seat. Outflow seats are fixedly connected to both sides of the bottom of the flow guiding cavity. Multiple openings are provided on the outflow seats. Multiple driven teeth are fixedly connected to the inner surface of the distribution seat. A support frame is provided on the inner side of the distribution seat. A drive motor is fixedly connected to the support frame. A drive gear is fixedly connected to the end of the output shaft of the drive motor.

[0007] Preferably, the fixed grinding disc is disposed on top of the rotating grinding disc, and the rotating grinding disc is connected to the output shaft of the grinding motor. The grinding motor can drive the rotating grinding disc to rotate, thereby cooperating with the fixed grinding disc to grind the microspheres in the emulsion.

[0008] Preferably, the top ends of the two connecting pipes penetrate the support plate and extend to the outside of the grinding cylinder, and the connecting pipes are connected to the delivery pump so that the emulsion can be introduced into the grinding cylinder.

[0009] Preferably, the distribution seat is rotatably connected to the guide seat via a bearing, and the connecting pipe is connected to the guide seat, so that the emulsion can enter the interior of the guide seat through the connecting pipe.

[0010] Preferably, the two outlet seats are symmetrically arranged on both sides of the bottom of the distribution seat, and both outlet seats are connected to the guide cavity, so that the emulsion inside the guide cavity can enter the outlet seat.

[0011] Preferably, the support frame is fixedly connected to the inner surface of the guide seat, and the driving gear meshes with the distribution seat through multiple driven teeth, so that the driving gear can drive the distribution seat to rotate.

[0012] Preferably, the adjustment mechanism includes multiple guide columns, the bottom ends of which are fixedly connected to a support plate, and the multiple guide columns are disposed through the grinding cylinder. Each of the multiple guide columns is provided with a scale strip, and a connecting frame is fixedly connected between the top ends of the multiple guide columns. An adjusting screw is threadedly connected inside the connecting frame, and an adjusting motor is fixedly connected to the top end of the adjusting screw, so that the distance between the fixed grinding disc and the rotating grinding disc can be adjusted, thereby enabling the emulsion microspheres to be ground into different particle sizes.

[0013] This invention provides an improved structure for a microbead grinding machine for exfoliating emulsions. Compared with existing technologies, it has the following advantages:

[0014] 1. This exfoliating emulsion microbead grinding machine has an improved structure. The emulsion is delivered into the guide cavity in the distribution seat by a delivery pump. The drive motor drives the outlet seat to rotate, and the emulsion flows out from the opening on the outlet seat, so that the emulsion flows evenly between the fixed grinding disc and the rotating grinding disc. The grinding motor drives the rotating grinding disc to rotate, and the rotating grinding disc and the fixed grinding disc are used to fully grind the emulsion microbeads, effectively improving the grinding effect.

[0015] 2. The improved structure of the exfoliating emulsion microbead grinding machine allows for the adjustment of the motor to drive the adjusting screw to rotate. The rotation of the adjusting screw drives the connecting frame to move, which in turn drives the guide column to move. The guide column then drives the support plate to move, which in turn drives the fixed grinding disc to move. By adjusting the distance between the fixed grinding disc and the rotating grinding disc, the emulsion microbeads can be ground into different particle sizes. 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 of the emulsion distribution mechanism of this utility model;

[0018] Figure 3 This is a schematic diagram of the distribution seat structure of this utility model;

[0019] Figure 4 This is a schematic diagram of the adjustment mechanism of this utility model.

[0020] In the diagram: 1. Base; 2. Emulsion distribution mechanism; 201. Fixed grinding disc; 202. Rotating grinding disc; 203. Support plate; 204. Guide seat; 205. Connecting pipe; 206. Distribution seat; 207. Flow guide cavity; 208. Bearing; 209. Outlet seat; 210. Opening; 211. Driven gear; 212. Drive gear; 213. Drive motor; 214. Support frame; 3. Grinding motor; 4. Adjustment mechanism; 401. Guide column; 402. Connecting frame; 403. Adjusting screw; 404. Adjusting motor. Detailed Implementation

[0021] 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.

[0022] Please see Figures 1 to 3This utility model provides a technical solution: an improved structure for a microbead grinding machine for removing dead skin emulsion, including a base 1, a control panel on the base 1 for easy operation of the whole, a grinding cylinder fixedly connected to the base 1, a grinding motor 3 installed at the bottom of the grinding cylinder, an emulsion distribution mechanism 2 installed inside the grinding cylinder, and an adjustment mechanism 4 installed on the grinding cylinder. The emulsion can be introduced through the emulsion distribution mechanism 2, so that the emulsion can be evenly distributed inside the grinding cylinder, so that it can be fully ground and improve the grinding effect.

[0023] The emulsion distribution mechanism 2 includes a fixed grinding disc 201 and a rotating grinding disc 202. The fixed grinding disc 201 is located on top of the rotating grinding disc 202, and the rotating grinding disc 202 is connected to the output shaft of the grinding motor 3. The grinding motor 3 can drive the rotating grinding disc 202 to rotate, thereby cooperating with the fixed grinding disc 201 to grind the microspheres in the emulsion. Two support plates 203 are fixedly connected to the fixed grinding disc 201. Connecting pipes 205 are fixedly connected to the bottom ends of the two support plates 203, and the top ends of the two connecting pipes 205 penetrate the support plates 203 and... Extending to the outside of the grinding cylinder, and connected to a delivery pump, the connecting pipe 205 allows the emulsion to be introduced into the grinding cylinder. Guide seats 204 are fixedly connected to the bottom ends of the two connecting pipes 205. A distribution seat 206 is rotatably connected to the bottom of the guide seat 204. A flow guiding cavity 207 is provided inside the distribution seat 206 to guide the emulsion towards the outlet seat 209. A bearing 208 is provided between the distribution seat 206 and the guide seat 204, and the distribution seat 206 is rotatably connected to the guide seat 204 via the bearing 208. The connecting pipe 205... 5 is connected to the guide seat 204, allowing the emulsion to enter the guide seat 204 through the connecting pipe 205. Both sides of the bottom of the guide cavity 207 are fixedly connected to the outflow seats 209. The two outflow seats 209 are symmetrically and obliquely arranged on both sides of the bottom of the distribution seat 206, and both outflow seats 209 are connected to the guide cavity 207, allowing the emulsion inside the guide cavity 207 to enter the outflow seats 209. The outflow seats 209 are provided with multiple openings 210, allowing the outflow seats 209 to use the openings 210 to allow the emulsion to enter. The material is discharged onto the side surface of the rotating grinding disc 202. Multiple driven teeth 211 are fixedly connected to the inner surface of the distribution seat 206. A support frame 214 is provided inside the distribution seat 206. A drive motor 213 is fixedly connected to the support frame 214. A drive gear 212 is fixedly connected to the end of the output shaft of the drive motor 213. The support frame 214 is fixedly connected to the inner surface of the guide seat 204. The drive gear 212 meshes with the distribution seat 206 through multiple driven teeth 211, so that the drive gear 212 can drive the distribution seat 206 to rotate.

[0024] Please see Figure 1 and Figure 4The adjusting mechanism 4 includes multiple guide posts 401. The bottom ends of the multiple guide posts 401 are fixedly connected to the support plate 203. The multiple guide posts 401 are connected through the grinding cylinder. The multiple guide posts 401 are provided with scale strips. A connecting frame 402 is fixedly connected between the top ends of the multiple guide posts 401. An adjusting screw 403 is threadedly connected inside the connecting frame 402. An adjusting motor 404 is fixedly connected to the top end of the adjusting screw 403. The adjusting motor 404 can drive the adjusting screw 403 to rotate. The rotation of the adjusting screw 403 drives the connecting frame 402 to move. The movement of the connecting frame 402 drives the guide posts 401 to move. The movement of the guide posts 401 drives the support plate 203 to move. The movement of the support plate 203 drives the fixed grinding disc 201 to move. By adjusting the distance between the fixed grinding disc 201 and the rotating grinding disc 202, the emulsion microspheres can be ground into different particle sizes.

[0025] During operation, the delivery pump feeds the emulsion into the connecting pipe 205 at a certain speed. The emulsion then flows through the connecting pipe 205 into the guide cavity 207 in the distribution seat 206, and then from the guide cavity 207 into the outlet seat 209. Simultaneously, the drive motor 213 drives the drive gear 212 to rotate. The drive gear 212 drives the distribution seat 206 to rotate through the driven gear 211. The rotation of the distribution seat 206 drives the outlet seat 209 to rotate, and the emulsion flows out through the opening 210 on the outlet seat 209, so that the emulsion flows evenly between the fixed grinding disc 201 and the rotating grinding disc 202. The grinding motor 3 drives the rotating grinding disc 202 to rotate, and the rotating grinding disc 202 and the fixed grinding disc 201 are used to fully grind the emulsion microspheres, effectively improving the grinding effect.

[0026] Furthermore, any content not described in detail in this specification is existing technology known to those skilled in the art.

Claims

1. An improved structure of a micro-bead exfoliating cream grinder comprising a base (1), characterized in that: A grinding cylinder is fixedly connected to the base (1), a grinding motor (3) is installed at the bottom of the grinding cylinder, an emulsion distribution mechanism (2) is installed inside the grinding cylinder, and an adjustment mechanism (4) is installed on the grinding cylinder. The emulsion distribution mechanism (2) includes a fixed grinding disc (201) and a rotating grinding disc (202). Two support plates (203) are fixedly connected to the fixed grinding disc (201). Connecting pipes (205) are fixedly connected to the bottom ends of the two support plates (203). Guide seats (204) are fixedly connected to the bottom ends of the two connecting pipes (205). A distribution seat (206) is rotatably connected to the bottom of the guide seat (204). A guide cavity (207) is opened on the inner side of the distribution seat (206). The distribution seat (206) and the guide... A bearing (208) is provided between the seats (204). Both sides of the bottom of the flow guide cavity (207) are fixedly connected to the outflow seats (209). The outflow seats (209) are provided with multiple openings (210). Multiple driven teeth (211) are fixedly connected to the inner surface of the distribution seat (206). A support frame (214) is provided inside the distribution seat (206). A drive motor (213) is fixedly connected to the support frame (214). A drive gear (212) is fixedly connected to the end of the output shaft of the drive motor (213).

2. The improvement to a microdermabrasion system of claim 1, wherein: The fixed grinding disc (201) is located on top of the rotating grinding disc (202), and the rotating grinding disc (202) is connected to the output shaft of the grinding motor (3).

3. The improvement to a microdermabrasion system of claim 1, wherein: The top ends of the two connecting pipes (205) penetrate the support plate (203) and extend to the outside of the grinding cylinder, and the connecting pipes (205) are connected to the delivery pump.

4. The improvement to a microdermabrasion system of claim 1, wherein: The distribution seat (206) is rotatably connected to the guide seat (204) via a bearing (208), and the connecting pipe (205) is connected to the guide seat (204).

5. The improvement to a microdermabrasion system of claim 1, wherein: The two outflow seats (209) are symmetrically arranged on both sides of the bottom of the distribution seat (206), and both outflow seats (209) are connected to the guide cavity (207).

6. The improvement to a microdermabrasion system of claim 1, wherein: The support frame (214) is fixedly connected to the inner surface of the guide seat (204), and the driving gear (212) meshes with the distribution seat (206) through multiple driven teeth (211).

7. The improvement to a microdermabrasion system of claim 1, wherein: The adjustment mechanism (4) includes multiple guide posts (401), the bottom ends of the multiple guide posts (401) are fixedly connected to the support plate (203), the multiple guide posts (401) are through the grinding cylinder, and the multiple guide posts (401) are provided with scale strips.

8. The improvement to a microdermabrasion system of claim 7, wherein: A connecting frame (402) is fixedly connected between the top ends of the multiple guide columns (401), and an adjusting screw (403) is threadedly connected inside the connecting frame (402). An adjusting motor (404) is fixedly connected to the top end of the adjusting screw (403).

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