KR102513137B1 - Apparatus for grating and squeeze - Google Patents

Abstract

The present invention relates to a pulverized liquid extraction composite device.
In detail,
In the pulverized liquid extraction composite device 1,
A main body housing means 100 formed in a specific shape to be placed on the floor (ground) of a specific place; and a power generating means 200 positioned and fixed inside the main body housing means 100 to generate power And, a grating means 400 coupled to and fixed to one side of the power generating means 200 and crushing and pulverizing the material by the rotational power of the power generating means 200; and, the grating means 400 A grating cover housing means 500 that protects from the outside; and a squeeze means 600 coupled to and fixed to one side of the power generating means 200 to extract liquid from the material by the rotational power of the power generating means 200. ); And a squeeze cover housing means 700 for protecting the squeeze means 600 from the outside;
The grating cover housing means 500 and the squeeze cover housing means 700 are positioned in series or parallel, and the flow path through which the result (crushed, pulverized material or liquid) is discharged is changed by the user,
When the flow path is changed by manipulating the grating cover housing means 500, the grating mode (M1) in which the material is pulverized and pulverized using only the grating means 400 alone;
When the flow path is changed by manipulating the squeeze cover housing means 700, a squeeze mode (M2) for extracting liquid from the material using only the squeeze means 600 alone;
When the flow path of the grating cover housing means 500 and the flow path of the squeeze cover housing means 700 are changed to be connected, the material crushed and pulverized by the grating means 400 is introduced into the squeeze means 600 to extract liquid from the material. By switching to the grating-squeeze mode (M3) to extract,
It is characterized in that it can perform the two functions of grinding, pulverizing, and liquid extraction of materials in a complex manner.
Due to this, the present invention has the advantage of maximizing the usability and effectiveness of the device by allowing materials to be discharged in a variety of properties in one device.

Description

Grinding liquid extraction complex device {Apparatus for grating and squeeze}

The present invention relates to a pulverized liquid extraction complex device, and more particularly, to pulverize and pulverize materials in one device, to extract a liquid from the material, but to pulverize and pulverize the material easily by user's selection. A pulverized liquid extraction complex device that enhances the usability and effectiveness of the device by allowing the function to be transformed into a state in which liquid is extracted from the material, or in a state in which pulverized and pulverized materials are naturally connected to liquid extraction. it's about

In general, a grating device and a liquid extraction device for crushing, pulverizing, or extracting liquid from various fruits, vegetables, seeds, etc., apply pressure to the input material by rotating the screw to obtain liquid and liquid-extracted material It is a device that allows the residues of the to be discharged to the outside.

These conventional grating devices and liquid extraction devices, based on the main purpose as described above, are manufactured only to be coarse and do not respond quickly and appropriately to various situations (characteristics of materials, difficult maintenance, repair, and management). the problem of not being able to

There is a problem in that the properties of the result to be obtained from each material are different, so that a separate device must be prepared.

Therefore, in the present invention, the grating device and the liquid extraction device are organically combined into one device, so that the grating device and the liquid extraction device quickly respond to various situations that may occur in the device as well as the main purpose of the device. It is intended to provide a complex device in which a grating device and a liquid extraction device are combined, which is very easy to maintain, repair, and manage, and which improves the effectiveness of the device.

Accordingly, as a prior art related to the pulverized liquid extraction composite device,

As shown in (a) of FIG. 11, the "large-capacity juicer" (hereinafter referred to as 'prior art 1') of Korean Patent Registration No. 10-0858333,

In order to provide a large amount of green juice or oil at an early time, a crushing roller for crushing the material input into the inlet formed on the upper side of the body and a juice roller for extracting moisture from the crushed material are sequentially combined, and the above crushing By forming a driving motor that drives the roller and the juice roller, it is possible to extract the moisture or oil contained in the material using the driving crushing roller and the juice roller, so that the input material is crushed and juiced sequentially while rapidly It is about a large-capacity juicer that allows extraction.

As another prior art,

As shown in (b) of Figure 11, as the "electric food grater" (hereinafter referred to as 'prior art 2') of Korean Patent Registration No. 10-1480934,

A drive motor and a speed reducer are provided inside, and the grater body has a drum seat protruding so that the output shaft of the reducer is placed in the center, the front part is closed and the rear part is made in the form of an open drum, and the rear part is made of a drum seat of the grater body. It is detachably mounted on the part, and an inlet for inputting food is erected on the upper part, and a housing-drum with a discharge hole extending in the horizontal direction in the lower part facing the inlet, and a housing-drum accommodated in the horizontal direction inside the housing-drum. The rotational shaft provided on the center is detachably coupled to the output shaft and is rotatably arranged while maintaining a constant distance from the inner wall of the housing-drum, and a plurality of grating cutters are arranged at regular intervals on the wall to scrape the ingredients input through the inlet. A grating roller and a push stick for pressing food ingredients into the housing-drum, and scraping and discharging food materials in the form of particles of an appropriate size, so that you can feel the original texture of the food ingredients as it is, and the fiber is It's about a motorized food grater that makes it rich and smooth to eat.

As can be seen, the prior arts 1 to 2 are the same technical field as the present invention, and in contrast to the present invention, there are substantially the same or similar configurations in the solution of the invention from a comprehensive point of view, but they are, of course, the same In the field of technology, it can be said that it is a necessary component and a technical idea.

In other words, it can be said to be the most basic configuration and technical concept that must be configured in order to configure a grating device and a liquid extraction device. (For example, power means for generating power, screws for applying pressure to materials, materials hopper, etc.)

However, there is a difference between the prior arts 1 and 2 and the present invention in terms of specific problems and means to be solved by the present invention, and effects resulting therefrom. (Refer to the technical features of the present invention described later.)

In addition, prior art 1 is a technology related to a liquid extracting device, and prior art 2 is a technology related to a grating device, which is different in technical characteristics from the present invention.

Therefore, the present invention is different from the conventional liquid extractor related technologies including the prior art 1 to the prior art 2, the problem to be solved only by the present invention (object of the invention), means (components) and Based on the better effect exerted by solving this problem, we want to pursue technical features.

Republic of Korea Patent Registration No. 10-0858333 (2008.09.05.) Republic of Korea Patent Registration No. 10-1480934 (2015.01.05.)

The present invention has been made to solve the above-mentioned conventional problems,

To provide a pulverized liquid extraction composite device that allows a grating operation for grinding and pulverizing materials and a squeeze operation for extracting liquid from materials to be performed simultaneously or continuously in one device there is

Another object of the present invention is

The liquid discharge barrel of the squeeze cover that surrounds the expeller screw that applies pressure to the material and extracts the liquid from the material, which is composed of the squeeze means in charge of the squeeze operation, is formed in a divided structure, and due to structural characteristics, maintenance and repair However, the purpose is to provide a pulverized liquid extraction complex device that is easy to manage.

The present invention for achieving the above object has been made to achieve the problem to be solved,

In the pulverized liquid extraction complex device,

Body housing means formed in a specific shape to be placed on the floor (ground) of a specific place;

a power generating means positioned and fixed inside the main body housing means to generate power;

Grating means coupled to and fixed to one side of the power generating means to crush and finely divide the material by the rotational power of the power generating means;

a grating cover housing means for protecting the grating means from the outside;

a squeeze means coupled to and fixed to one side of the power generating means to extract liquid from the material by the rotational power of the power generating means;

It consists of a; squeeze cover housing means for protecting the squeeze means from the outside,

The grating cover housing means and the squeeze cover housing means are positioned in series or in parallel, and the flow path through which the result (crushed, pulverized material or liquid) is discharged is configured to be changed by the user,

When the flow path is changed by manipulating the grating cover housing means, the grating mode uses only the grating means to pulverize and pulverize the material;

When the flow path is changed by manipulating the squeeze cover housing means, the squeeze mode extracts the liquid from the material using only the squeeze means;

When the flow path of the grating cover housing means and the flow path of the squeeze cover housing means are changed to be connected, the grating-squeeze mode in which the material pulverized and pulverized by the grating means is introduced into the squeeze means to extract liquid from the material By switching to,

It is characterized in that it can perform the two functions of grinding, pulverizing, and liquid extraction of materials in a complex manner.

On the other hand, prior to this, the terms or words used in the claims for patent registration should not be construed as being limited to the usual or dictionary meaning, and the inventors should not interpret the concept of terms in order to explain their invention in the best way. It should be interpreted as a meaning and concept consistent with the technical spirit of the present invention based on the principle that can be properly defined.

Therefore, the embodiments described in this specification and the configurations shown in the drawings are only one of the most preferred embodiments of the present invention, and do not represent all of the technical ideas of the present invention, so that various alternatives can be made at the time of this application. It should be understood that there may be equivalents and variations.

According to the present invention as described above in the above configuration and operation,

1. A grating operation for crushing and pulverizing materials and a squeeze operation for extracting liquid from materials can be performed simultaneously or continuously in one device.

That is, it is converted into a grating mode, a squeeze mode, and a grating-squeeze mode by a user's simple manipulation, so that various properties of the material can be obtained according to the user's needs.

More specifically,

Materials can be pulverized or finely divided by the user's choice.

Only the liquid can be extracted from the material by the user's selection.

In addition, the material may be pulverized and pulverized according to the user's selection, and a liquid may be extracted from the pulverized and pulverized material.

2. In addition, since the grating cover housing means and the squeeze cover housing means are formed independently from the main body housing means, separation and assembly are easy, management (cleaning, parts replacement, etc.) is easy.

3. In addition, the liquid discharge barrel of the squeeze cover that surrounds the expeller screw that applies pressure to the material and extracts the liquid from the material, constituted by the squeeze means in charge of the squeeze operation, is formed in a divided structure, due to structural characteristics , maintenance, repair and management are easy.

4. In addition, the portion of the squeeze cover where the liquid is discharged, that is, the width of the liquid discharge passage formed in the liquid discharge barrel can be changed so that the liquid can be extracted in response to the characteristics of various materials.

5. In addition, the amount of liquid extraction can be temporarily improved by arbitrarily suppressing the discharge of the residue of the liquid-extracted material to the outside through the outlet pressure control unit formed in the squeeze means.

As described above, the present invention, due to the respectively formed grating cover housing means and the squeeze cover housing means, facilitates the management of the pulverized liquid extraction composite device, as well as according to the characteristics of various materials by the liquid discharge barrel and the outlet pressure control unit of the squeeze cover. It is a very effective invention that can extract liquid and temporarily increase or control the amount of liquid extracted.

In particular, as described above, the work of grinding, pulverizing, and extracting the liquid of the material is easily performed by the user's selection in one device, so that the material can be prepared in various properties according to the characteristics of various materials. By changing and discharging, the utilization and effectiveness of the device is maximized.

Therefore, it is an invention that is very suitable for export (technology transfer) as an appropriate technology as well as domestically and internationally.

In addition, the material feed section and the liquid extraction section are clearly distinguished by the specific shape of the expeller screw formed in the squeeze means, so that unnecessary energy loss of the system of the pulverized liquid extraction complex device is prevented and efficiency is improved do.

1 shows a conceptual diagram of a pulverized liquid extraction composite device according to the present invention.
Figure 2 shows the configuration of the present inventors pulverized liquid extraction composite device.
3 is a state perspective view showing an embodiment of the pulverized liquid extraction composite device of the present invention.
4 is a perspective view of another embodiment of the pulverized liquid extraction composite device of the present invention.
5 is a conceptual diagram showing a squeeze means and a squeeze cover housing means among the components of the pulverized liquid extraction complex apparatus of the present invention.
6 is a detailed view of the liquid discharge barrel of the squeeze cover housing means among the components of the pulverized liquid extraction composite device of the present invention.
7 is a simplified schematic diagram of an embodiment of the outlet pressure adjusting unit of the squeeze cover housing means among the components of the pulverized liquid extraction composite device of the present invention.
Figure 8 shows a conceptual diagram of the force acting on the expeller screw of the squeeze means, among the components of the pulverized liquid extraction composite device of the present invention.
Figure 9 is a simplified flow chart showing the operating mechanism of the pulverized liquid extraction composite device of the present invention in chronological order.
Figure 10 shows another conceptual diagram for the pulverized liquid extraction composite device of the present invention.
Figure 11 shows a representative view of the prior art for the pulverized liquid extraction composite device of the present invention.

Hereinafter, with reference to the accompanying drawings, the function, configuration and action of the present invention, the composite device 1 for extracting the pulverized liquid, will be described in detail.

Figure 1 shows a conceptual diagram of the pulverized liquid extraction complex device of the present invention, Figure 2 is a configuration diagram of the pulverized liquid extraction complex device of the present invention, Figure 3 is a state perspective view of an embodiment of the pulverized liquid extraction complex device of the present invention 4 is a perspective view showing another embodiment of the pulverized liquid extraction composite device of the present invention.

As shown in Figures 1 to 4, the present invention,

In the pulverized liquid extraction composite device 1,

Body housing means 100 formed in a specific shape to be placed on the floor (ground) of a specific place;

a power generating means (200) positioned and fixed inside the body housing means (100) to generate power;

Grating means 400 coupled to and fixed to one side of the power generating means 200 to crush and pulverize materials by the rotational power of the power generating means 200;

a grating cover housing means 500 for protecting the grating means 400 from the outside;

Squeeze means 600 coupled to and fixed to one side of the power generating means 200 to extract liquid from the material by the rotational power of the power generating means 200;

It consists of a; squeeze cover housing means 700 for protecting the squeeze means 600 from the outside,

The grating cover housing means 500 and the squeeze cover housing means 700 are positioned in series or in parallel, and the flow path through which the result (crushed, pulverized material or liquid) is discharged is changed by the user,

When the flow path is changed by manipulating the grating cover housing means 500, the grating mode (M1) in which the material is pulverized and pulverized using only the grating means 400 alone;

When the flow path is changed by manipulating the squeeze cover housing means 700, a squeeze mode (M2) for extracting liquid from the material using only the squeeze means 600 alone;

When the flow path of the grating cover housing means 500 and the flow path of the squeeze cover housing means 700 are changed to be connected, the material crushed and pulverized by the grating means 400 is introduced into the squeeze means 600 to extract liquid from the material. By switching to the grating-squeeze mode (M3) to extract,

It is characterized in that it can perform the two functions of grinding, pulverizing, and liquid extraction of materials in a complex manner.

That is, the pulverized liquid extraction composite device 1 of the present invention,

In one device, the grating work of crushing and pulverizing the material and the squeeze work of extracting the liquid from the material are performed simultaneously or individually according to the user's choice, thereby improving the usability of the device and This is to maximize effectiveness.

At this time, simultaneous or individual means,

The user crushes or pulverizes the material using the grating mode (M1), extracts liquid using the squeeze mode (M2), or uses the grating mode (M1) and squeeze mode (M2) at the same time It means that the grinding and pulverization of materials and the liquid can be obtained separately, or the work from pulverization and pulverization of the material to liquid extraction is performed continuously at once by using the grating-squeeze mode (M3). .

Looking at the pulverized liquid extraction complex device 1 in more detail,

The body housing means 100,

A main body housing 110 formed in a specific shape with a certain volume so as to be placed in close contact with the bottom surface (ground), and in which the power generating means 200 and the gear box means 300 are positioned and fixed;

a vibration-proof pad block 120 formed on one side of the bottom surface of the main housing 110 to absorb vibration of the main housing 110;

An anti-slip element 130 coupled to the lower surface of the anti-vibration pad block 120 and formed in a concavo-convex shape of a certain pattern to prevent slipping by improving friction with the ground; composed of (anti-vibration pad block 120 and The non-slip element 130 is to maximize the stability of the operation and position of the body housing 110.)

The grating cover housing means 500,

As an example,

A grating cover 510 that surrounds the grating means 400 and protects it from the outside;

A grating hopper unit 520 protruding and formed on the upper portion of the grating cover 510 to induce input of materials into the grating cover 510;

A grating discharge unit 530 protruding and formed at the lower portion of the grating cover 510 to discharge pulverized and pulverized materials to the outside;

The squeeze cover housing means 700,

As an example,

A squeeze cover 710 that surrounds the squeeze means 600 and protects it from the outside;

a squeeze hopper unit 720 protruding and formed on the upper portion of the squeeze cover 710 to induce input of materials into the squeeze cover 710;

It is composed of; a squeeze discharge portion 730 protruding and formed at the bottom of the squeeze cover 710 so that the liquid extracted from the material is discharged to the outside,

The pulverized liquid extraction composite device 1 of the present invention is formed.

At this time, the grating cover housing means 500 and the squeeze cover housing means 700 are, for example, the grating discharge part 530 formed in the grating cover housing means 500 and the squeeze hopper part of the squeeze cover housing means 700. As described above, only 720 is rotated by the user at a specific angle,

The grating mode (M1) in which the grating discharge unit 530 is rotated at a specific angle and the grating means 400 is used alone to crush and pulverize the material,

The squeeze mode (M2) for extracting liquid from the material by rotating the squeeze hopper unit 720 at a specific angle and using only the squeeze means 600 alone,

The grating discharge unit 530 and the squeeze hopper unit 720 are rotated at a specific angle so that the grating discharge unit 530 and the squeeze hopper unit 720 coincide, so that the material pulverized and pulverized by the grating means 400 is It is naturally introduced into the squeeze means 600 to activate the grating-squeeze mode (M3) for extracting liquid from pulverized and pulverized materials.

In addition, in the pulverized liquid extraction composite device 1 of the present invention,

It is formed between the power generating means 200 and the grating means 400 or between the power generating means 200 and the squeeze means 600, and the rotational power generated from the power generating means 200 is transferred to the grating means 400 and the squeeze means. Gearbox means 300 that transmits to 600; may be further included and configured.

The gearbox means 300,

As described above, it is located inside the main body housing means 100, is coupled and fixed to one side of the power generating means 200, and the rotational power generated from the power generating means 200 is transferred to the grating means 400 and the squeeze means ( 600),

At this time, the grating means 400 is formed by the gear box means 300,

Combined and fixed to one side of the gear box means 300, crushing and pulverizing the material by the rotational power of the power generating means 200 transmitted through the gear box means 300,

The squeeze means 600 is formed by the gearbox means 300,

It is coupled and fixed to one side of the gearbox means 300, so that liquid can be extracted from the material by the rotational power of the power generating means 200 transmitted through the gearbox means 300.

In addition, the gearbox means 300,

As an example,

At least two or more rotational shafts may be formed so that the grating means 400 and the squeeze means 600 are coupled and fixed to a predetermined position, respectively.

Two or more gears are meshed and combined to form an appropriate gear ratio so that suitable rotational power is transmitted to the grating means 400 and the squeeze means 600, respectively.

At this time, the gearbox means 300, as described above, consists of one set, forms an appropriate gear ratio, and outputs rotational power to two rotational shafts, so that the grating means 400 and the squeeze means are respectively on the two rotational shafts structure combining 600;

Alternatively, each gearbox means 300 may be formed in the grating means 400 and the squeeze means 600 so that rotational power is transmitted independently. (The grating means 400 and the squeeze means ( 600), when each gear box means 300 is formed, the power generating means 200 must also be formed respectively.)

On the other hand, in the squeeze means 600 for extracting liquid from the material,

More specifically, as shown in FIG. 8,

It is configured to include; an expeller screw 610 that feeds the material introduced through the squeeze hopper unit 720 and applies pressure to extract the liquid.

The expeller screw 610,

For example, in the tapered shaft method, threads formed on the outer periphery are variably formed to have different pitches, and the threads may also be formed at a variable feed angle.

This is designed as the most optimal shape for extracting the liquid by the expeller screw 610, and can be said to be a shape that clearly distinguishes the material feed section and the liquid extraction section. (Liquid The discharge barrel 711 is shaped such that a high pressure is formed inside, so that the material injected into the squeeze hopper unit 720 moves forward naturally, so that pressure is gradually applied.)

That is, at first, the main purpose is feed, so that the material is moved smoothly, while preventing the bottleneck of the material to increase the efficiency of the system, and by gradually applying pressure to the material, the liquid is extracted from the section where the liquid is to be extracted. By allowing this to be extracted, it can be said to be an optimal shape for extracting liquid to prevent unnecessary loss of energy. (Of course, a screw of a conventional shape for extracting liquid can also be applied to the present invention.)

At this time, the variable feed angle of the thread is

Based on the resultant force (squeeze, screw, feed), 'b', 'θ _b ', 'θ _p ' are varied so that the feed section of the material and the liquid extraction section are distinguished so that the screw thread suitable for each section is created. to form

For example, to be more specific,

The θ _p of the screw thread formed in the conveying section of the material is formed at 90 [°] to maximize the feed force,

By forming θ _p of the thread formed in the liquid extraction section to be smaller than 90 [°], the squeeze force is increased.

In addition, the part where the liquid is discharged from the squeeze cover 710,

It is formed of a pot-shaped liquid discharge barrel 711 having liquid discharge passages B2 formed in a certain arrangement on the outer periphery so that the liquid extracted from the material is discharged.

The liquid discharge barrel 711,

As shown in Figure 6,

A barrel block element (711a) divided into a plurality of pieces;

An inclined barrel block fixing flange element 711b having a second inclined surface 711b' for fitting and fixing the barrel block element 711a;

The barrel block element 711a,

A barrel block (B1) in which a first inclined surface (B1') is formed in a specific shape having a certain length, width, and thickness;

A liquid discharge passage (B2) formed as a groove on one side or both sides of the barrel block (B1) so that the liquid extracted from the material is discharged to the outside;

The liquid extracted from the material by the rotation of the expeller screw 610 is discharged to the outside through the liquid discharge passage B2.

At this time, due to the characteristics of the squeeze means 600 and the squeeze cover housing means 700, since high pressure is generated inside the liquid discharge barrel 711, the first inclined surface B1 'on the barrel block B1 and the inclined barrel block By forming a second inclined surface (711b') on the fixed flange element (711b),

The binding force of the barrel block element 711a of the split structure is maximized. (711a) is less likely to separate.)

In addition, in the barrel block element 711a,

a simplate (B3) coupled to and fixed to the liquid discharge passage (B2) according to the characteristics of the material by the user, so that the width of the liquid discharge passage (B2) can be arbitrarily changed;

It consists of a simple plate fixing pin (B4) for fixing the simple plate (B3) to the liquid discharge passage (B2),

The rotation of the expeller screw 610 allows the liquid extracted from the material to be discharged to the outside through the liquid discharge passage B2,

Depending on the characteristics of the material, the user can change the width of the liquid discharge passage B2 using the simplate B3.

At this time, when the barrel block element 711a is configured to further include the simplate B3 and the simplate fixing pin B4, the liquid discharge passage B2,

It should be formed on one side of the barrel block (B1) in the direction of rotation of the expeller screw (610), which means that the simplate (B3) coupled to the liquid discharge passage (B2) is continuously rotated by the expeller screw (610). This is to prevent separation from the liquid discharge passage (B2).

That is, with the rotation of the expeller screw 610, a force is generated to bring the simplate (B4) into close contact with the simplate (B3), which is coupled and fixed to the liquid discharge passage (B2). (If the barrel block (B1) ) When the liquid discharge passage B2 is formed on the side opposite to the rotation direction of the expeller screw 610, there is no significant effect on the liquid discharge passage B2 itself, but a simple coupled to the liquid discharge passage B2 The rotation of the expeller screw 610 generates a force to escape from the liquid discharge passage B2 in the rate B3.)

In addition, at the end of the squeeze cover housing means 700, an outlet pressure adjusting unit 740 for interfering with the discharge of the remaining material from which the liquid is extracted; may be further included and configured,

It is formed as a poppet valve, or

As a first embodiment, as shown in (a) of FIG. 7,

A part of the liquid discharge barrel 711 is inserted into the liquid discharge barrel 711 by a user's operation, or is spaced a certain distance apart, so that the outlet interference slope (I) is formed to interfere with the discharge of the liquid-extracted material to the outside. nozzle module 741;

a pressure adjusting nozzle support module 742 assisting the forward and backward movement of the pressure adjusting nozzle module 741 in a horizontal direction;

It consists of a pressure adjusting means support bracket 743 for fixing and supporting the position of the pressure adjusting nozzle support module 742,

By preventing the liquid-extracted material from being discharged to the outside by manipulation by the user, the extraction amount of the liquid is temporarily increased.

In the second embodiment, as shown in (b) of FIG. 7,

an outlet pressure adjusting member 741' that moves forward and backward in the horizontal direction and interferes with the discharge of the residue to the outside;

It may be composed of; a bushing member 742' inserted into the end of the expeller screw 610 and supporting the expeller screw 610,

In the third embodiment, as shown in (c) of FIG. 7,

The other end of the expeller screw 610 is made of a spline shaft, so that the expeller screw 610 moves forward and backward in the horizontal direction,

The end of the expeller screw 610 is interpolated and fixed, and the expeller screw 610 is moved forward and backward in the horizontal direction by the user's manipulation, so that the expeller screw 610 moves forward and backward. A screw movement induction module 741'' that allows the residue of the extracted material to interfere with being discharged to the outside;

It consists of a screw support module (742'') that assists the motion (rotation) of the screw movement induction module (741'').

In various embodiments, it is possible to adjust the pressure of the outlet through which the residue from which the liquid is extracted is discharged.

As described above, the outlet pressure control unit 740 is ultimately composed of a role of increasing the amount of liquid extraction by adjusting the pressure of the outlet through which the remainder of the material is discharged, but it serves to adjust the pressure of the outlet. Of course, the role of the bushing bearing supporting the expeller screw 610 is also included, so that the stability and durability of the expeller screw 610 are maintained.

For reference, FIG. 9 briefly illustrates the operating mechanism of the pulverized liquid extraction composite device 1 of the present invention in chronological order.

In addition, the embodiment shown in FIG. 3 shows a device that can be used at home with a relatively small capacity, for example, and another embodiment shown in FIG. 4 can be used in a factory with a large capacity, for example. device is shown.

In addition, (a) of FIG. 6 shows a perspective view of the state of the liquid discharge barrel 711,

(b) is a cross-sectional view of the liquid discharge barrel 711,

(c) shows a detailed view of the barrel block element 711a among the components of the liquid discharge barrel 711.

In addition, the 'flow path' described in the present invention,

It refers to the path through which materials enter and exit.

1 is a conceptual diagram illustrating an embodiment in which the grating means 400 and the squeeze means 600 are configured in parallel, and FIG. 10 is a conceptual diagram illustrating an embodiment configured in series.

As described above, the present invention is not limited to the described embodiments, and it is obvious to those skilled in the art that various modifications and variations can be made without departing from the spirit and scope of the present invention.

Therefore, since it can be implemented in various other forms without departing from the technical spirit or main characteristics, the embodiments of the present invention are mere examples in all respects and should not be construed as being limited and can be implemented in various ways.

The present invention relates to a pulverized liquid extraction complex device, which manufactures, manufactures and sells the same, and a grating device and liquid extraction that automatically extracts liquid from pulverization, pulverization, and materials to which the present invention is applied. Appropriate technology is exported (technology transferred) to developing countries as well as industries related to equipment, that is, industries such as cooking and household items that require various properties of materials, and is used as a foundation for industrial development in the country. It can be applied to improve quality.

1: pulverized liquid extraction complex device
100: body housing means 110: body housing
120: anti-vibration pad block 130: anti-slip element
200: power generating means 300: gearbox means
400: grating means 500: grating cover housing means
510: grating cover 520: grating hopper part
530: grating discharge unit 600: squeeze means
610: expeller screw 700: squeeze cover housing means
710: squeeze cover 711: liquid discharge barrel
711a: barrel block element 711b: inclined barrel block fixed flange element
720: squeeze hopper unit 730: squeeze discharge unit
740: outlet pressure control unit 741: pressure control nozzle module
741': outlet pressure regulating member 741'': screw movement induction module
742: pressure control nozzle support module 742': bushing member
742'': screw support module 743: pressure control means support bracket
I: exit interference slope
B1: Barrel block B2: Liquid discharge passage
B3: SIMPLATE B4: SIMPLATE fixing pin
M1: Grating Mode M2: Squeeze Mode
M3: Grating - Squeeze Mode

Claims (1)

In the pulverized liquid extraction composite device 1,
Body housing means 100 formed in a specific shape to be placed on the floor (ground) of a specific place;
a power generating means (200) positioned and fixed inside the body housing means (100) to generate power;
Grating means 400 coupled to and fixed to one side of the power generating means 200 to crush and pulverize materials by the rotational power of the power generating means 200;
a grating cover housing means 500 for protecting the grating means 400 from the outside;
Squeeze means 600 coupled to and fixed to one side of the power generating means 200 to extract liquid from the material by the rotational power of the power generating means 200;
It consists of a; squeeze cover housing means 700 for protecting the squeeze means 600 from the outside,
The grating cover housing means 500 and the squeeze cover housing means 700 are positioned in series or in parallel, and the flow path through which the result (crushed, pulverized material or liquid) is discharged is changed by the user,
When the flow path is changed by manipulating the grating cover housing means 500, the grating mode (M1) in which the material is pulverized and pulverized using only the grating means 400 alone;
When the flow path is changed by manipulating the squeeze cover housing means 700, a squeeze mode (M2) for extracting liquid from the material using only the squeeze means 600 alone;
When the flow path of the grating cover housing means 500 and the flow path of the squeeze cover housing means 700 are changed to be connected, the material crushed and pulverized by the grating means 400 is introduced into the squeeze means 600 to extract liquid from the material. By switching to the grating-squeeze mode (M3) to extract,
It is possible to perform the two functions of pulverization, pulverization, and liquid extraction of materials in a complex way,
The user crushes or pulverizes the material using the grating mode (M1), extracts liquid using the squeeze mode (M2), or uses the grating mode (M1) and squeeze mode (M2) at the same time Grinding, finely divided materials and liquids can be obtained separately, or, by using the grating-squeeze mode (M3), the work from grinding and grinding of materials to liquid extraction is continuously performed at once, ,
In the squeeze means 600 for extracting liquid from the material,
It is configured to include; an expeller screw 610 that feeds the material introduced through the squeeze hopper unit 720 and applies pressure to extract the liquid.
The expeller screw 610,
In the tapered shaft method, the screw thread formed on the outer periphery is formed variably and has a different pitch, and the screw thread is also formed with a variable feed angle,
The feed section of the material and the liquid extraction section are separated so that a high pressure is formed inside the liquid discharge barrel 711, and the material injected into the squeeze hopper unit 720 moves forward, gradually applying pressure By letting
At first, the main purpose of the feed is to increase the efficiency of the system by preventing the bottleneck of the material while moving the material, and gradually applying pressure to the material so that the liquid is extracted from the section where the liquid should be extracted. , to prevent unnecessary loss of energy,
The squeeze cover housing means 700,
A squeeze cover 710 that surrounds the squeeze means 600 and protects it from the outside;
a squeeze hopper unit 720 protruding and formed on the upper portion of the squeeze cover 710 to induce input of materials into the squeeze cover 710;
A squeeze discharge portion 730 protruding and formed at the bottom of the squeeze cover 710 so that the liquid extracted from the material is discharged to the outside;
The part where the liquid is discharged from the squeeze cover 710,
It is formed of a jar-shaped liquid discharge barrel 711 having liquid discharge passages B2 formed in a certain arrangement on the outer periphery so that the liquid extracted from the material is discharged.
The liquid discharge barrel 711,
A barrel block element (711a) divided into a plurality of pieces;
An inclined barrel block fixing flange element 711b having a second inclined surface 711b' for fitting and fixing the barrel block element 711a;
The barrel block element 711a,
A barrel block (B1) in which a first inclined surface (B1') is formed in a specific shape having a certain length, width, and thickness;
A liquid discharge passage (B2) formed as a groove on one side or both sides of the barrel block (B1) so that the liquid extracted from the material is discharged to the outside;
The liquid extracted from the material by the rotation of the expeller screw 610 is discharged to the outside through the liquid discharge passage B2,
At the end of the squeeze cover housing means 700, an outlet pressure adjusting unit 740 for interfering with the discharge of the remainder of the material from which the liquid was extracted; is further included and configured,
The role of the bushing bearing supporting the expeller screw 610 as well as the role of increasing the liquid extraction amount by adjusting the pressure at the outlet where the residue of the material is discharged is also included, so the stability and durability of the expeller screw 610 Characterized in that it is maintained,
Grinding liquid extraction complex device.

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