CN117123119B

CN117123119B - Personal care product mixing equipment and mixing method thereof

Info

Publication number: CN117123119B
Application number: CN202311409364.0A
Authority: CN
Inventors: 韩勇
Original assignee: Guangzhou Gaozi Cosmetics Co ltd
Current assignee: Guangzhou Gaozi Cosmetics Co ltd
Priority date: 2023-10-27
Filing date: 2023-10-27
Publication date: 2025-03-11
Anticipated expiration: 2043-10-27
Also published as: CN117123119A

Abstract

The invention relates to the technical field of cosmetics production, in particular to personal care product mixing equipment and a mixing method thereof, wherein the mixing equipment comprises an upper mixing barrel, a main material box and an auxiliary material box are respectively arranged at the top of the upper mixing barrel, at least two spiral pipes are arranged on the inner top wall of the upper mixing barrel, the outer surfaces of the spiral pipes are connected with a feeding pipe, a siphon pipe is arranged in the auxiliary material box, and the outlet end of the siphon pipe is connected with the feeding pipe; the lower mixing drum, connect with the hourglass union coupling between upper mixing drum and the lower mixing drum, the pivot is vertically installed to the inside of hourglass pipe, install the carousel that is located the spiral pipe bottom in the pivot. According to the invention, the automatic mixing of the liquid cosmetics is realized by means of the gravitational potential energy of the liquid falling and the negative pressure effect of the fluid, external power is not needed, the energy waste is avoided, the cost is saved, the mixing effect is improved by a multiple mixing mode, and the product quality is ensured.

Description

Personal care product mixing equipment and mixing method thereof

Technical Field

The invention relates to the technical field of cosmetic production, in particular to personal care product mixing equipment and a mixing method thereof.

Background

Personal care products are generally referred to as cosmetics. Cosmetic refers to chemical industry or fine chemical products that are spread on any part of the surface of the human body, such as skin, hair, nails, lips, teeth, etc., by painting, spraying, or the like, to clean, maintain, beautify, modify, and change the appearance, or correct the smell of the human body, and maintain a good state.

The origin of cosmetics can be traced to the original society, and more types of cosmetics begin to appear, are protected, are nourished and are decorated in recent years along with the progress of science and technology and the improvement of living standard of people. Cosmetics are generally prepared by mixing various materials together during production, and in the case of liquid cosmetics, the conventional method is to mix various components by stirring. The Chinese patent publication No. CN108187540B discloses a liquid cosmetic mixing procedure treatment system which comprises a tank body, a distillation module, a rotation module, a stirring module and an auxiliary material adding module, wherein the tank body is used for containing liquid raw materials to be stirred, the liquid cosmetics are stirred in the tank body, a feed inlet is formed in the side wall of the tank body, the distillation module is used for producing distilled water required by the cosmetics and heating and preserving heat of the tank body by utilizing hot steam, the rotation module is used for driving the stirring module to rotate by utilizing high-pressure steam generated during the production of the distilled water as power, the stirring module is positioned in the tank body and used for realizing stirring of the liquid cosmetics, the auxiliary material adding module is arranged on the stirring module, and the auxiliary material adding module is used for adding auxiliary materials into the tank body by utilizing the rotation of the stirring module.

As demonstrated in the above patents, the cosmetic stirring devices of the present stage are basically powered by external power to rotate the stirring mechanism, most typically by a motor. Although some paste cosmetics with higher viscosity may inevitably require mixing with external power, the use of external power for mixing liquid cosmetics causes waste of energy, which is disadvantageous for saving cost.

Disclosure of Invention

Aiming at the defects existing in the prior art, the invention provides personal care product mixing equipment and a mixing method thereof, which can effectively solve the problem that the energy waste is easily caused by mixing liquid cosmetics by using external power in the prior art.

In order to achieve the above purpose, the invention is realized by the following technical scheme:

a personal care product mixing device comprising:

The upper mixing barrel is characterized in that a main material box and an auxiliary material box are respectively arranged at the top of the upper mixing barrel, at least two spiral pipes are arranged on the inner top wall of the upper mixing barrel, the outer surfaces of the spiral pipes are connected with a feeding pipe, a siphon is arranged in the auxiliary material box, and the outlet end of the siphon is connected with the feeding pipe;

The lower mixing drum, with hourglass union coupling between upper mixing drum and the lower mixing drum, the pivot is vertically installed to the inside of hourglass pipe, install the carousel that is located the spiral pipe bottom in the pivot, and the carousel is located the first half section of hourglass pipe, the internally mounted of lower mixing drum has the rabbling mechanism with pivot cooperation work.

When the liquid cosmetic raw materials are mixed, part of the raw materials are poured into the auxiliary material box, the height of the liquid level is lower than the top end of the siphon, then the other raw materials are poured into the main material box, the raw materials start to fall down the spiral pipe, fluid is formed in the spiral pipe, the pressure of the fluid is lower than that of static liquid, the flow rate is higher, the pressure is lower, negative pressure is formed at the joint of the feed pipe and the spiral pipe, and the liquid in the auxiliary material box flows out and is converged into the spiral pipe to fall down the spiral pipe together through the action of the siphon, so that preliminary mixing is realized. When the raw materials flow out from the bottom end of the spiral pipe, liquid can impact the surface of the rotary table, and because the route slope that liquid flows out is towards the surface of the rotary table, a force for promoting the rotary table to rotate is applied to the rotary table, the rotary table starts to rotate rapidly, and the rotary shaft rotates simultaneously to drive the stirring mechanism at the bottom of the lower mixing barrel to work to further mix the liquid falling into the lower mixing barrel, so that the product can be fully mixed.

Further, one end of the feed pipe, which is close to the spiral pipe, is provided with at least three outlets.

Further, the spiral directions of the spiral pipes are the same, and the starting points of the spiral pipes are distributed at equal intervals on the circumference.

Further, a plurality of bearing plates are equidistantly arranged on the turntable and used for receiving the impact of the liquid flowing out of the spiral tube.

Further, a throwing disc is further installed on the rotating shaft, and the throwing disc is located at the lower half section of the hourglass tube.

Further, a plurality of dropping grooves which are in net-shaped distribution are uniformly formed in the inner wall of the lower mixing barrel.

Further, the stirring mechanism comprises a deflector rod arranged at the bottom end of the rotating shaft, a plurality of horizontally sliding scratching plates are elastically arranged on the inner wall of the lower mixing barrel, a poking piece is arranged on the upper surface of each scratching plate, a poking groove matched with the deflector rod is formed in each scratching plate, and the poking groove enables the scratching plates to gradually move backwards when the deflector rod rotates to the scratching plate.

Further, a horizontal guide rod is fixedly arranged on the inner wall of the lower mixing barrel, the sliding plate is movably sleeved on the guide rod, and a spring is sleeved on the guide rod.

The invention also provides a mixing method of the personal care product, which is applied to the mixing equipment and comprises the following steps:

s1, firstly filling raw materials in a secondary material box, then filling other raw materials into a main material box, enabling the raw materials to flow down along a spiral pipe, generating negative pressure at the bottom end of a feed pipe, extracting the raw materials in the secondary material box, mixing the raw materials into the spiral pipe, and finishing primary mixing;

S2, the liquid flowing out of the bottom end of the spiral pipe impacts the rotary table to enable the rotary shaft to rotate, and the liquid is converged in the middle of the hourglass pipe to realize further mixing;

s3, the liquid falls onto the throwing disc and is thrown onto the inner wall of the lower mixing barrel by the rotating throwing disc, flows down along the blanking groove, and is intersected and converged when flowing in the blanking groove, so that the mixing is realized again;

And S4, rotating the rotating shaft to drive the stirring mechanism to work so as to further mix the raw materials entering the lower mixing barrel.

Compared with the prior art, the automatic mixing device has the advantages that the automatic mixing of the liquid cosmetics is realized by means of the gravitational potential energy when the liquid falls and the negative pressure effect of the fluid, external power is not needed, the energy waste is avoided, the cost is saved, the mixing effect is improved in a multiple mixing mode, the product quality is ensured, and the automatic mixing device is efficient and energy-saving.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below. It is evident that the drawings in the following description are only some embodiments of the present invention and that other drawings may be obtained from these drawings without inventive effort for a person of ordinary skill in the art.

FIG. 1 is a schematic diagram of the overall structure of the present invention;

FIG. 2 is a top view of the present invention;

FIG. 3 is a cross-sectional view of A-A of the present invention;

FIG. 4 is a schematic view showing the internal structure of the upper mixing tub of the present invention;

FIG. 5 is a schematic view of a spindle according to the present invention;

FIG. 6 is a schematic view showing the internal structure of the lower mixing tub of the present invention;

fig. 7 is a schematic view of the bottom structure of the rowing plate of the present invention.

The reference numbers in the figure respectively represent a lower mixing bucket 1, an upper mixing bucket 2, a main material box 3, a secondary material box 4, a siphon tube 5, a spiral tube 6, a spiral tube 7, an hourglass tube 8, a feeding tube 9, a rotary table 10, a bearing plate 11, a throwing disc 12, a rotary shaft 13, a deflector rod 14, a blanking groove 15, a scratching plate 16, a guide rod 17, a poking sheet 18 and a poking groove.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention more clear, the technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention. It will be apparent that the described embodiments are some, but not all, embodiments of the invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

The invention is further described below with reference to examples.

Examples

Referring to fig. 1-7, a personal care product mixing apparatus comprising:

the top of the upper mixing barrel 2 is provided with a main material box 3 and an auxiliary material box 4 respectively, the main material box 3 and the auxiliary material box 4 can be used for containing different liquid raw materials respectively, the inner top wall of the upper mixing barrel 2 is provided with at least two spiral pipes 6, the outer surface of each spiral pipe 6 is connected with a feeding pipe 8, the inside of the auxiliary material box 4 is provided with a siphon pipe 5, and the outlet end of each siphon pipe 5 is connected with the feeding pipe 8.

When the liquid cosmetic raw materials are mixed, part of the raw materials are poured into the auxiliary material box 4, the liquid level is lower than the top end of the siphon pipe 5, then the other raw materials are poured into the main material box 3, the raw materials start to fall along the spiral pipe 6, fluid is formed in the spiral pipe 6, the pressure of the fluid is smaller than that of static liquid, the pressure is larger, the pressure is smaller, negative pressure is formed at the joint of the feed pipe 8 and the spiral pipe 6, and the liquid in the auxiliary material box 4 flows out and is converged into the spiral pipe 6 to fall along the spiral pipe 6 under the action of the siphon pipe 5, so that preliminary mixing is realized.

Wherein at least three outlets are provided at the end of the feed pipe 8 near the spiral pipe 6. The liquid flowing out from the auxiliary material box 4 is divided into a plurality of branches through a plurality of outlets before being converged into the spiral pipe 6, and the liquid is distributed more uniformly after being converged, so that the mixing effect is improved.

Referring to fig. 1, the invention is also provided with a lower mixing drum 1, an upper mixing drum 2 is connected with the lower mixing drum 1 through an hourglass tube 7, liquid flowing down from the upper mixing drum 2 is converged together when passing through a neck part in the middle of the hourglass tube 7, the further mixing effect is achieved, a rotating shaft 12 is vertically arranged in the hourglass tube 7, a rotating disc 9 positioned at the bottom end of a spiral tube 6 is arranged on the rotating shaft 12, the rotating disc 9 is positioned at the upper half section of the hourglass tube 7, and a stirring mechanism matched with the rotating shaft 12 is arranged in the lower mixing drum 1. The shaft 12 may be mounted by a mounting bracket fixed on the inner wall of the hourglass tube 7, which is a common mounting manner and will not be described herein.

When the raw materials flow out from the bottom end of the spiral pipe 6, the liquid can impact the surface of the rotary table 9, and because the route of the liquid flow out is inclined towards the surface of the rotary table 9, a force for promoting the rotary table 9 to rotate is applied to the rotary table 9, the rotary table 9 starts to rotate rapidly, and the rotating shaft 12 rotates simultaneously, so that the stirring mechanism at the bottom of the lower mixing drum 1 is driven to work to further mix the liquid falling into the lower mixing drum 1, and the products can be fully mixed.

It should be noted that the spiral direction of the spiral pipe 6 is the same, and the starting points of the spiral pipe 6 are equally distributed on the circumference. When two or more spiral pipes 6 are arranged, the spiral direction of each spiral pipe 6 is set to be the same, and when liquid flowing out of each spiral pipe 6 impacts on the rotary table 9, torsion force in the same direction is applied to the rotary table 9, so that the rotary table 9 is driven to rotate at a faster speed, and the phenomenon that the rotary state of the rotary table 9 is unstable due to the fact that the impact directions of each liquid are opposite is avoided.

Further, referring to fig. 4-5, a plurality of force-bearing plates 10 are equidistantly mounted on the turntable 9, the force-bearing plates 10 being adapted to receive the impact of the liquid flowing out of the spiral pipe 6. When the liquid flowing out from the bottom end of the spiral pipe 6 impacts the surface of the turntable 9, the force for driving the turntable 9 to rotate is the friction force between the liquid and the surface of the turntable 9, so that the utilization rate of kinetic energy contained in the liquid is low, and therefore, the turntable 9 is provided with a plurality of force bearing plates 10 for bearing the impact of the liquid, each strand of liquid can directly impact the force bearing plates 10, the turntable 9 can receive larger impact force, the rotating speed can be higher, and sufficient power can be provided for the stirring mechanism. Therefore, the bearing plate 10 can improve the utilization rate of kinetic energy contained in the liquid and avoid energy waste.

Under normal conditions, when the liquid raw materials subjected to primary mixing fall into the lower mixing barrel 1 from the hourglass pipe 7, most of liquid directly and vertically falls down, so that the rotating shaft 12 is further provided with the throwing disc 11, the throwing disc 11 is positioned at the lower half section of the hourglass pipe 7, when the rotating shaft 12 rotates, the throwing disc 11 rotates, the raw materials fall on the surface of the throwing disc 11 after falling from the middle part of the hourglass pipe 7, and the liquid is thrown out of the surface of the throwing disc 11 along the radial direction of the throwing disc 11 through the rotation throwing motion of the throwing disc 11 and falls onto the inner wall of the lower mixing barrel 1, and then flows down along the inner wall of the lower mixing barrel 1 and finally falls down to the bottom of the lower mixing barrel 1 again. In the falling process, the raw materials can be scattered, so that the mixing effect is improved.

Further, referring to fig. 6, a plurality of drop tanks 14 are uniformly provided on the inner wall of the lower mixing tub 1 in a net-like distribution. The dropping groove 14 is in a net shape and evenly distributed on the inner wall of the lower mixing barrel 1, liquid dropping onto the inner wall of the lower mixing barrel 1 slides down along the dropping groove 14 preferentially, as the net-shaped dropping groove 14 is provided with a plurality of intersecting points, the sliding liquid can be mixed together after meeting the intersecting points, the mixed liquid continuously drops and is further mixed with the liquid in other dropping grooves 14 at the other intersecting points, and the raw materials are mixed to a deeper degree finally through repeated meeting and merging in the dropping groove 14.

Referring to fig. 5 to 7, the stirring mechanism includes a shift lever 13 mounted at the bottom end of the rotary shaft 12, a plurality of horizontally slidable scraping plates 15 are elastically mounted on the inner wall of the lower mixing drum 1, a paddle 17 is mounted on the upper surface of the scraping plates 15, a shift groove 18 adapted to the shift lever 13 is formed on the scraping plates 15, and when the shift lever 13 rotates to the position of the scraping plates 15, the shift groove 18 gradually moves the scraping plates 15 backward.

The inner wall of the lower mixing drum 1 is fixedly provided with a horizontal guide rod 16, the sliding plate 15 is movably sleeved on the guide rod 16, and the guide rod 16 is also sleeved with a spring.

When the rotating shaft 12 rotates, the deflector rod 13 rotates by taking the rotating shaft 12as a circle center, when the deflector rod 13 rotates beside the deflector rod 15, the end part of the deflector rod 13 starts to enter the deflector groove 18, and referring to fig. 7, as the deflector groove 18 is obliquely opened, when the deflector rod 13 moves inside the deflector groove 18, the deflector rod 15 gradually moves backwards, and the deflector piece 17 on the deflector rod 15 is driven to transfer liquid inside the lower mixing barrel 1 backwards, so that liquid cosmetics form turbulence inside the lower mixing barrel 1, the purpose of full mixing is achieved, and the mixing effect of products is ensured.

Although the present invention has been described in detail with reference to the foregoing embodiments, it should be understood by those skilled in the art that the foregoing embodiments may be modified or equivalents may be substituted for some of the features thereof, and that the modification or substitution does not depart from the spirit and scope of the embodiments.

Claims

1. A personal care product mixing device, comprising:

An upper mixing barrel (2), wherein a main material box (3) and a subsidiary material box (4) are respectively installed on the top of the upper mixing barrel (2), at least two spiral tubes (6) are installed on the inner top wall of the upper mixing barrel (2), the outer surface of the spiral tube (6) is connected to a feed pipe (8), and a siphon tube (5) is installed inside the subsidiary material box (4), and the outlet end of the siphon tube (5) is connected to the feed pipe (8);

A lower mixing barrel (1), wherein the upper mixing barrel (2) and the lower mixing barrel (1) are connected by an hourglass tube (7), a rotating shaft (12) is vertically installed inside the hourglass tube (7), a rotating disk (9) located at the bottom end of the spiral tube (6) is installed on the rotating shaft (12), and the rotating disk (9) is located in the upper half of the hourglass tube (7), and a stirring mechanism that cooperates with the rotating shaft (12) is installed inside the lower mixing barrel (1);

A plurality of bearing plates (10) are equidistantly mounted on the rotating disk (9), and the bearing plates (10) are used to receive the impact of liquid flowing out of the spiral tube (6);

The stirring mechanism comprises a lever (13) mounted at the bottom end of a rotating shaft (12); a plurality of horizontally slidable padding plates (15) are elastically mounted on the inner wall of the lower mixing barrel (1); a paddle (17) is mounted on the upper surface of the paddling plate (15); a paddle groove (18) adapted to the lever (13) is formed on the paddling plate (15); the paddle groove (18) enables the paddling plate (15) to gradually move backward when the lever (13) is rotated to the paddling plate (15) position;

A horizontal guide rod (16) is fixedly mounted on the inner wall of the lower mixing barrel (1), the rowing plate (15) is movably sleeved on the guide rod (16), and a spring is also sleeved on the guide rod (16).

2. A personal care product mixing device according to claim 1, characterized in that at least three outlets are provided at one end of the feed pipe (8) close to the spiral tube (6).

3. A personal care product mixing device according to claim 1, characterized in that the spiral directions of the spiral tubes (6) are the same, and the starting points of the spiral tubes (6) are equidistantly distributed on the circumference.

4. A personal care product mixing device according to claim 3, characterized in that a spinner (11) is also installed on the rotating shaft (12), and the spinner (11) is located in the lower half of the hourglass tube (7).

5. A personal care product mixing device according to claim 4, characterized in that a plurality of material dropping grooves (14) distributed in a mesh shape are evenly arranged on the inner wall of the lower mixing barrel (1).

6. A method for mixing personal care products, applied to the mixing device as claimed in claim 5, characterized in that it comprises the following steps:

S1: First, fill the auxiliary material box with raw materials, and then put other raw materials into the main material box. The raw materials flow down along the spiral tube, and negative pressure is generated at the bottom of the feed tube, and the raw materials in the auxiliary material box are drawn out and mixed into the spiral tube to complete the initial mixing;

S2: The liquid flowing out from the bottom of the spiral tube hits the rotating disk to rotate the shaft, and the liquid gathers in the middle of the hourglass tube to achieve further mixing;

S3: The liquid falls onto the spinning disc and is thrown onto the inner wall of the lower mixing barrel by the rotating spinning disc, and flows down along the chute. The liquids intersect and merge while flowing in the chute, achieving mixing again;

S4: The shaft rotates, driving the stirring mechanism to further mix the raw materials entering the lower mixing barrel.