CN113398787B - Foundation liquid and processing method thereof - Google Patents

Abstract

The invention belongs to the technical field of foundation liquid processing, and particularly relates to foundation liquid and a processing method thereof; the invention provides a foundation liquid processing method, which comprises the following steps: s1: filling liquid material into a fusion part in the heavy fusion device, and immersing and mixing the solid material into the liquid material by using a sedimentation part in the heavy fusion device; s2: controlling the dissolution degree of the solid material in the liquid material according to the mixing time; s3: repeatedly pumping and pouring the liquid material back into the fusion part for multiple processing; the heavy melting device comprises a fusion part and a sedimentation part, wherein the fusion part is connected with the ground through a bracket, and the sedimentation part is arranged on the fusion part and is used for storing solid materials; the composition of the powder base liquid is as follows: according to the mass parts, 85 parts of titanium dioxide, 90 parts of talcum powder, 20 parts of coloring pigment, 33 parts of stearic acid, 6 parts of stearic acid monoglyceride and 56 parts of deionized water are taken; the invention can accurately control the reaction degree between the solid material and the liquid material.

Description

Foundation liquid and processing method thereof

Technical Field

The invention belongs to the technical field of foundation liquid processing, and particularly relates to foundation liquid and a processing method thereof.

Background

The foundation liquid has light and thin texture, easy application and less greasy feeling, is a foundation cosmetic which is popular at present, is suitable for most of skin, especially oily skin and rapid make-up and finishing in summer, and modern foundation combines beauty treatment and skin care to become a multifunctional product, such as anti-aging, anti-wrinkle, antioxidation, no sensitizer, no eye irritation, high SPF value and the like, and has a certain moisturizing and skin care effect due to the skin care components such as hyaluronic acid, ceramide, plant extracts, compound vitamin ACE, flavonoid, polyphenol and the like.

Disclosure of Invention

The present invention has been made in view of the above circumstances, and an object thereof is to provide a foundation liquid processing method capable of precisely controlling the degree of reaction between a solid material and a liquid material.

The invention provides a foundation liquid processing method, which comprises the following steps:

s1: filling liquid material into a fusion part in the heavy fusion device, and immersing and mixing the solid material into the liquid material by using a sedimentation part in the heavy fusion device;

s2: controlling the dissolution degree of the solid material in the liquid material according to the mixing time;

s3: and repeatedly pumping and pouring the liquid material back into the fusion part, and carrying out multiple processing.

The heavy melting device comprises a fusion part and a sedimentation part, wherein the fusion part is connected with the ground through a bracket, the sedimentation part is arranged on the fusion part and used for storing solid materials, a hole is formed in the sedimentation part, and an extraction observation assembly is arranged at the lower end of the fusion part and used for extracting and pouring liquid materials back into the fusion part.

The sedimentation portion is capable of sliding over the fusion portion.

The sedimentation portion is rotatable on the fusion portion.

The composition of the powder base liquid is as follows: according to the mass portions, 85 portions of titanium dioxide, 90 portions of talcum powder, 20 portions of coloring pigment, 33 portions of stearic acid, 6 portions of stearic acid monoglyceride and 56 portions of deionized water are taken.

The invention has the beneficial effects that:

the position of the sedimentation part on the fusion part is controlled to enable the solid material and the liquid material to be contacted or separated, so that the function of controlling the processing degree of the foundation liquid material is realized, and foundation liquid materials with different concentrations are manufactured; through the design that the solid material is put into the subsidence part and then contacted with the liquid material, the effect of the accurate control of the reaction degree between the solid material and the liquid material can be improved.

Drawings

The following drawings are only intended to illustrate and explain the present invention, wherein:

FIG. 1 is a flow chart of a foundation treatment method of the present invention;

FIG. 2 is a schematic structural view of a first embodiment of a fusion portion of the present invention;

FIG. 3 is a schematic structural view of a second embodiment of a fusion portion of the present invention;

FIG. 4 is a schematic view of a rotary rod according to the present invention;

FIG. 5 is a schematic view of a slide of the present invention;

FIG. 6 is a schematic view of a slider according to the present invention;

FIG. 7 is a schematic view of a perspective arc plate of the present invention;

FIG. 8 is a schematic structural view of a hollow feed cylinder of the present invention;

FIG. 9 is a schematic view of a lever structure of the present invention;

FIG. 10 is a schematic view of the structure of the cap cartridge of the present invention;

FIG. 11 is a schematic view of the structure of the mating frame of the present invention;

fig. 12 is a schematic structural view of the bonding board of the present invention.

In the figure:

a spherical cylinder 1.1;

a cover cylinder 1.2;

a mounting groove 1.3;

a slider 1.4;

carriage 1.5;

1.6 parts of a matching frame;

a rotating rod 2.1;

a top plate 2.2;

2.3 of a bonding plate;

2.3.1 parts of arc-shaped surface;

limiting edge I2.3.2;

limit edge II 2.3.3;

a slide cylinder 3.1;

chute I3.2;

a liquid discharge pipe 3.3;

3.4 of a control frame;

3.5, perspective arc plates;

4.1 parts of hollow feeding cylinder;

ball retention 4.2;

a leak 4.3;

stirring block 4.4;

4.5, limiting sheets;

a control lever 4.6;

a spool 5.1;

5.2 of a lifting frame;

a connecting frame 5.3;

5.4 of a chute II;

a slide arm 5.5;

an articulated arm 5.6;

toggle plate 5.7.

Detailed Description

Embodiments of the present invention will be described below with reference to specific examples.

See fig. 2, fig. 8-9:

firstly, pouring a liquid material into a fusion part, then pouring a large block of solid material into a sedimentation part for storage, and enabling the liquid material to be in contact with the solid material through holes on the sedimentation part so as to enable the solid material to be dissolved in the liquid material;

the position of the sedimentation part on the fusion part is controlled to enable the solid material and the liquid material to be contacted or separated, so that the function of controlling the processing degree of the foundation liquid material is realized, and foundation liquid materials with different concentrations are manufactured;

through the design that the solid materials are placed into the sedimentation part and then contacted with the liquid materials, the effect of accurately controlling the reaction degree between the solid materials and the liquid materials can be improved;

the solid materials stored in the sedimentation part can be solid materials which are not easy to dissolve, so that the situation that the solid materials cannot be separated from the liquid materials is avoided;

the design of the extraction observation assembly can extract the liquid material in the fusion part;

further, the design of the extraction observation assembly can enable the extracted liquid material to be refilled into the fusion part for reprocessing;

further, the design of the extraction observation assembly is convenient for observing the liquid material in the fusion part;

the color and turbidity of the liquid material in the fusion part can be observed through the extraction observation component, and the mixing efficiency between the solid material and the liquid material can be evaluated;

the fusion part is connected with the ground through a support, the support can be a columnar support structure, one end of the support column is connected with the fusion part, and the other end of the support column is connected with the ground.

See fig. 8-9:

the sedimentation part can slide on the fusion part, so that the control effect of the heavy fusion device on separation or contact between the solid material and the liquid material can be improved.

The settlement part can be designed to rotate on the fusion part, and liquid materials in the fusion part can be thrown out in a centrifugal mode, so that the control effect of the heavy fusion device on stopping reaction between solid materials and liquid materials is improved.

See fig. 2 and 8:

the fusion part comprises a spherical cylinder 1.1 and a cover cylinder 1.2, the cover cylinder 1.2 is arranged on the spherical cylinder 1.1, a liquid filling pipe is arranged on the cover cylinder 1.2, a liquid outlet is arranged at the lower end of the spherical cylinder 1.1, the drawing-away observation assembly is arranged at the liquid outlet, the sedimentation part slides on the cover cylinder 1.2, and the spherical cylinder 1.1 is connected with the ground through a bracket.

Filling liquid material into the spherical cylinder 1.1 through a filling pipe on the cover cylinder 1.2;

the spherical cylinder 1.1 is connected with the ground through a bracket, the bracket can be a columnar supporting structure, one end of a supporting column is connected with the fusion part, and the other end of the supporting column is connected with the ground;

the liquid outlet is used for discharging the foundation liquid material in the spherical cylinder 1.1;

the spherical design of the spherical cylinder 1.1 can improve the easy cleaning effect of the device.

See fig. 8-9:

the sedimentation part comprises a hollow feeding cylinder 4.1, a reserved ball 4.2, leak holes 4.3, limiting plates 4.5 and a control rod 4.6, wherein the hollow feeding cylinder 4.1 is hollow and is provided with two ends open, the lower end of the hollow feeding cylinder 4.1 is provided with the reserved ball 4.2, the reserved ball 4.2 is uniformly provided with a plurality of leak holes 4.3, two limiting plates 4.5 are arranged on the hollow feeding cylinder 4.1, the inner sides of the two limiting plates 4.5 are respectively matched with the upper end and the lower end of the cover cylinder 1.2, and the control rod 4.6 is arranged on the hollow feeding cylinder 4.1 and is used for controlling the relative position between the hollow feeding cylinder 4.1 and the cover cylinder 1.2.

The hollow feeding cylinder 4.1 slides on the cover cylinder 1.2, the hollow feeding cylinder 4.1 is controlled to lift on the cover cylinder 1.2 in a mode of installing a telescopic rod between the cover cylinder 1.2 and the hollow feeding cylinder 4.1, the fixed end of the telescopic rod is fixedly connected with the cover cylinder 1.2, a lantern ring is installed on the movable end of the telescopic rod, the lantern ring is sleeved on the outer side of the hollow feeding cylinder 4.1, the upper end of the lantern ring is attached to the control rod 4.6, and therefore the hollow feeding cylinder 4.1 lifts on the cover cylinder 1.2 by starting the telescopic rod to stretch;

the telescopic rod can be an electric telescopic rod or a hydraulic telescopic rod;

the limiting piece 4.5 plays a role in limiting, and the device is prevented from being damaged when the extension or contraction amplitude of the telescopic rod is overlarge;

the control rod 4.6 can be used for controlling the hollow feeding cylinder 4.1 to rotate on the cover cylinder 1.2;

the ball-retaining 4.2 is designed to increase the capacity of the solid material, and increase the smoothness of the solid material moving in the ball-retaining 4.2, so that the solid material and the liquid material can be fully contacted;

when the hollow feeding cylinder 4.1 is controlled to rotate by taking the axis of the hollow feeding cylinder as a shaft, the solid material synchronously rotates in the ball retaining cylinder 4.2;

the hollow feeding cylinder 4.1 is controlled to rotate in a differential speed manner, so that solid materials can slide relatively in the synchronous rotation process of the ball 4.2, and the inner side of the ball 4.2 is an arc surface, so that the solid materials can be turned up and down in the rotation process of the hollow feeding cylinder 4.1, and the processing effect of the device is improved.

See fig. 9:

a plurality of stirring blocks 4.4 are arranged on the outer side of the ball retaining body 4.2.

The stirring effect on liquid materials in the process of rotating the hollow feeding cylinder 4.1 by taking the axis of the hollow feeding cylinder as a shaft can be improved by the design of the stirring block 4.4.

See fig. 10:

the spherical cylinder 1.1 is internally provided with a matching frame 1.6, the matching frame 1.6 is provided with a matching stirring plate and a connecting rod, the connecting rod penetrates through one of the plurality of leak holes 4.3, the virtual axis of the connecting rod is collinear with the virtual axis of the hollow feeding cylinder 4.1, and the matching stirring plate is positioned in the ball retaining cylinder 4.2.

The matching frame 1.6 is designed, so that the hollow feeding cylinder 4.1 can relatively rotate with the matching frame 1.6 in the process of rotating by taking the axis of the hollow feeding cylinder as a shaft, and the fusion effect between the solid material and the liquid material is improved by utilizing vortex generated by the relative rotation between the matching frame 1.6 and the hollow feeding cylinder 4.1;

through grooves can be formed in the stirring plate, so that small solid materials can be smashed when the matching frame 1.6 and the hollow feeding cylinder 4.1 relatively rotate, and the processing efficiency of the device is improved.

See fig. 2-3, fig. 5-7:

the drawing observation assembly comprises a sliding block 1.4, a sliding block 1.5, a sliding cylinder 3.1, a sliding groove I3.2, a liquid discharge pipe 3.3, a control frame 3.4 and a perspective arc plate 3.5, wherein the sliding block 1.4 is arranged at the liquid discharge port, the sliding block 1.5 is arranged on the spherical cylinder 1.1, the sliding groove I3.2 is arranged on the sliding cylinder 3.1, the sliding groove I3.2 is in sliding connection with the sliding block 1.4, the sliding groove I3.2 is in sliding connection with the sliding block 1.5, the liquid discharge pipe 3.3 is communicated with the sliding cylinder 3.1, the perspective arc plate 3.5 is arranged on the spherical cylinder 1.1, a cylindrical container is formed between the perspective arc plate 3.5 and the sliding cylinder 3.1, and the control frame 3.4 is arranged on the sliding cylinder 3.1.

The position of the sliding cylinder 3.1 on the spherical cylinder 1.1 is adjusted by utilizing the control frame 3.4, so that the volume of a cylindrical container formed between the perspective arc plate 3.5 and the sliding cylinder 3.1 is changed, the amount of liquid material in the cylindrical container is changed, and then the functions of pumping and refilling the liquid material in the spherical cylinder 1.1 are realized;

when the sliding cylinder 3.1 slides on the liquid outlet, the sliding cylinder 3.1 always keeps a fitting state with the perspective arc plate 3.5, so that the sealing function of the device is maintained;

the perspective arc plate 3.5 is made of transparent materials, and the perspective arc plate 3.5 is used for observing the liquid materials in the cylindrical container, so that the mixing efficiency between the solid materials and the liquid materials is evaluated;

the design of the slide block 1.4 and the slide frame 1.5 can improve the guiding effect in the moving process of the slide cylinder 3.1.

See fig. 2-4, fig. 11-12:

the auxiliary dissolving component is arranged on the spherical cylinder 1.1 and is inserted into two sides of the spherical cylinder 1.1, the auxiliary dissolving component can stir in the spherical cylinder 1.1, and the sealing component is arranged between the auxiliary dissolving component and the spherical cylinder 1.1.

The auxiliary dissolving component is controlled to stir the liquid material in the fusion part, so that the mixing effect between the liquid material and the solid material is improved;

further, the design of stirring the auxiliary dissolving assembly in the fusion part can improve the cleaning effect of the device on the spherical cylinder 1.1;

further, the design of stirring the auxiliary dissolving assembly in the fusion part can improve the efficiency of the device for discharging the liquid material in the spherical cylinder 1.1;

the sealing assembly is used for maintaining the sealing effect of the device when the auxiliary dissolving assembly is stirred in the fusion part.

See fig. 11-12:

the auxiliary dissolving component comprises a sliding column 5.1, a lifting frame 5.2, a connecting frame 5.3, a sliding chute II 5.4, a sliding arm 5.5, a hinge arm 5.6 and a stirring plate 5.7, wherein two openings are symmetrically arranged on the spherical cylinder 1.1, mounting grooves 1.3 are symmetrically arranged at two ends of the openings, a top plate 2.2 is mounted at the position of the mounting groove 1.3, a rotating rod 2.1 is mounted between the two top plates 2.2, the stirring plate 5.7 is hinged to the rotating rod 2.1, the hinge arm 5.6 is fixedly connected to the stirring plate 5.7, the sliding arm 5.5 slides in the sliding chute II 5.4, the sliding chute II 5.4 is arranged on the connecting frame 5.3, two connecting frames 5.3 are symmetrically mounted on the lifting frame 5.2, the lifting frame 5.2 is connected with the two sliding columns 5.1 in a sliding manner, the sliding column 5.1 is mounted at the bottom of the spherical cylinder 1.1, and the sealing component is mounted between the two top plates 2.2 at the same side.

The lifting frame 5.2 is controlled to lift on the sliding column 5.1, and the sliding arm 5.5 can slide in the sliding groove II 5.4, so that the sliding arm 5.5 drives the stirring plate 5.7 to rotate on the rotating rod 2.1 through the hinged arm 5.6, and the stirring plate 5.7 can stir liquid materials in the spherical cylinder 1.1.

See fig. 2-4:

the sealing assembly comprises a bonding plate 2.3, an arc-shaped surface 2.3.1, a limiting edge I2.3.2 and a limiting edge II 2.3.3, two bonding plates 2.3 are arranged between two top plates 2.2 on the same side, the arc-shaped surface 2.3.1 is arranged on the bonding plate 2.3, the arc-shaped surface 2.3.1 is bonded with a poking plate 5.7, the bonding plate 2.3 is provided with the limiting edge I2.3.2 and the limiting edge II 2.3.3, the poking plate 5.7 is matched with the limiting edge I2.3.2, and the hinge arm 5.6 is matched with the limiting edge II 2.3.3.

The bonding plate 2.3 is arranged between the two top plates 2.2 on the same side, and the sealing performance of the device can be maintained by keeping the bonding effect between the arc-shaped surface 2.3.1 and the poking plate 5.7, so that the leakage of liquid materials in the spherical cylinder 1.1 is prevented;

the design along I2.3.2 and II 2.3.3 plays a limiting role, and simultaneously enables the toggle plate 5.7 and the hinge arm 5.6 to be in a surface fit state when contacting with the laminating plate 2.3, so that the stabilizing effect in the using process of the device is improved.

Claims (4)

1. A foundation liquid processing method is characterized in that: the method comprises the following steps:

s1: filling liquid material into a fusion part in the heavy fusion device, and immersing and mixing the solid material in the liquid material by using a sedimentation part in the heavy fusion device;

s2: controlling the dissolution degree of the solid material in the liquid material according to the mixing time;

s3: repeatedly pumping out and pouring the liquid material into the fusion part for multiple processing,

the re-melting device comprises a fusion part and a sedimentation part, the fusion part is connected with the ground through a bracket, the sedimentation part is arranged on the fusion part and used for storing solid materials, a hole is arranged on the sedimentation part, the lower end of the fusion part is provided with a drawing-off observation component for drawing off and pouring liquid materials back into the fusion part,

the fusion part comprises a spherical cylinder (1.1) and a cover cylinder (1.2), the cover cylinder (1.2) is arranged on the spherical cylinder (1.1), a liquid filling pipe is arranged on the cover cylinder (1.2), a liquid outlet is arranged at the lower end of the spherical cylinder (1.1), the drawing-away observation component is arranged at the liquid outlet, the sedimentation part slides on the cover cylinder (1.2), the spherical cylinder (1.1) is connected with the ground through a bracket,

the sedimentation part comprises a hollow feeding cylinder (4.1), a retaining ball (4.2), a leak hole (4.3), limiting sheets (4.5) and a control rod (4.6), wherein the hollow feeding cylinder (4.1) is hollow and is provided with two ends open, the lower end of the hollow feeding cylinder (4.1) is provided with the retaining ball (4.2), the retaining ball (4.2) is uniformly provided with a plurality of leak holes (4.3), the hollow feeding cylinder (4.1) is provided with two limiting sheets (4.5), the inner sides of the two limiting sheets (4.5) are respectively matched with the upper end and the lower end of the cover cylinder (1.2), the control rod (4.6) is arranged on the hollow feeding cylinder (4.1) and is used for controlling the relative position between the hollow feeding cylinder (4.1) and the cover cylinder (1.2),

a plurality of stirring blocks (4.4) are arranged on the outer side of the ball retaining (4.2),

the spherical cylinder (1.1) is internally provided with a matching frame (1.6), the matching frame (1.6) is provided with a matching stirring plate and a connecting rod, the connecting rod penetrates through one of the plurality of leakage holes (4.3), the virtual axis of the connecting rod is collinear with the virtual axis of the hollow feeding cylinder (4.1), and the matching stirring plate is positioned in the reserved ball (4.2).

2. The method for processing foundation liquid according to claim 1, wherein: the sedimentation portion is capable of sliding over the fusion portion.

3. The method for processing foundation liquid according to claim 1, wherein: the sedimentation portion is rotatable on the fusion portion.

4. The method for processing foundation liquid according to claim 1, wherein: the drawing observation assembly comprises a sliding block (1.4), a sliding block (1.5), a sliding cylinder (3.1), a sliding groove I (3.2), a liquid discharge pipe (3.3), a control frame (3.4) and a perspective arc plate (3.5), wherein the sliding block (1.4) is arranged at the liquid discharge port, the sliding block (1.5) is arranged on the spherical cylinder (1.1), the sliding groove I (3.2) is arranged on the sliding cylinder (3.1), the sliding groove I (3.2) is in sliding connection with the sliding block (1.4), the sliding groove I (3.2) is in sliding connection with the sliding block (1.5), the liquid discharge pipe (3.3) is communicated with the sliding cylinder (3.1), the perspective arc plate (3.5) is arranged on the spherical cylinder (1.1), a cylindrical container is formed between the perspective arc plate (3.5) and the sliding cylinder (3.1), and the control frame (3.4) is arranged on the sliding cylinder (3.1).

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