JP6704497B1 - Blender for extracting nutrients in plants - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a blender for extracting nutrients in plants. SOLUTION: A cell wall crushing tank 3 fixed to the top of a frame 1 and a protective tank 9 fixedly installed on the bottom of the frame are provided, and an ultrasonic generator 10 is provided on each inner wall on both sides inside the protective tank. First cell wall crushing units 5 and second cell wall crushing units 6 are symmetrically and alternately provided inside the cell wall crushing tank, and the first cell wall crushing unit and the second cell wall crushing unit are provided inside the cell wall crushing tank. A supporting filter plate 8 located below the crushing unit is provided, a grind mechanism is provided inside the grind tank 11, and the grind mechanism includes a grind drum and a push unit for pushing and swinging the grind drum. , A blender for extracting nutrients in plants. [Selection diagram] Figure 1

Description

The present invention relates to the field of plant processing equipment, and more particularly to a blender for extracting nutrients in plants.

Cell wall disruption is a method of rupturing the cell wall. In the case of plant cells, the cell wall is divided into three layers, an intercellular layer, a primary wall and a secondary wall. Such multiple layers of thick walls prevent water and nutrients from permeating. The technique of crushing cells to crush the cell wall is a technique of crushing the cell wall of a plant to improve the absorption of water and nutrients and retain the active ingredient.It releases phytochemicals and the dietary fiber in it. , Maximize the combination of vitamins and other nutrients, thus promoting absorption by the human body.

Usually, as the cell wall crushing method of the plant, the plant is crushed using a crusher, and the outflow of juice is recognized in the crushing process, but since a large amount of complete biomass cells are present, it is difficult to secure the cell wall crushing efficiency, We cannot meet the requirements of the finished product.

Chinese Patent Application Publication No. 204949421

An object of the present invention is to provide a blender for extracting nutrients in plants in order to solve the problems described in the background art.

In order to achieve the above object, the present invention provides the following technical solutions.

A blender for extracting nutrients in plants, comprising a cell wall crushing tank fixed to the top of the frame and a protective tank fixedly installed on the bottom of the frame, and a supply unit is provided at the top of the cell wall crushing tank. , A grind tank in which the bottom of the cell wall crushing tank is in communication, the grind tank extends to the inside of the protective tank, and an ultrasonic generator is provided on each of the inner walls on both sides inside the protective tank. Is provided,
Inside the cell wall crushing tank, first cell wall crushing units and second cell wall crushing units are provided symmetrically and alternately, and inside the cell wall crushing tank below the first cell wall crushing unit and the second cell wall crushing unit. A supporting filter plate located is provided, a grind mechanism is provided inside the grind tank, and the grind mechanism comprises a grind drum and a push unit for rocking the grind drum.
A grind cylinder communicating with the bottom end of the cell wall crushing tank via a supply pipe is provided inside the protective tank, and a cone grind rod is rotatably provided inside the grind cylinder. A discharge port is provided at one end of the cylinder.

As a further aspect of the present invention, the supply unit is provided in communication with the top of the cell wall crushing tank, and provided with a preliminary crushing tank provided with a preliminary crushing mechanism inside thereof, and at the top of the preliminary crushing tank. Is provided with a charging port, and the supply unit further includes a rotating ring rotatably provided in the cavity at the top of the cell wall crushing tank, and the supply cavity is provided between the rotating ring and the inner wall of the top of the cell wall crushing tank. The outlet of the bottom end of the preliminary crushing tank extends to the inside of the supply cavity,
Further, an annular block plate is fixedly attached to the outer ring at the bottom of the rotating ring, and the annular block plate is symmetrically provided with two supply through holes that fit into the supply ports in the bottom plate of the supply cavity. .. In the present embodiment, when the rotating ring is rotated until the feed through hole is aligned with the feed port, the material in the feed cavity enters the cell wall crushing tank through the feed port and the feed through hole, respectively, and the material is intermittently charged into the cell wall crushing tank. It solves the problem that the material is deposited by batch injection and impairs the crushing effect.

As a further aspect of the present invention, the first cell wall crushing unit and the second cell wall crushing unit have the same structure, and both have a rotary shaft rotatably provided inside the cell wall crushing tank and a rotary shaft. A plurality of crushing blades provided evenly are provided, a fixed bush is fixedly provided on the outer ring of the rotating shaft, and the crushing blade is fixedly attached to the fixed bush, and the first cell wall crushing unit is provided. The crushing blades included in and the crushing blades included in the second cell wall crushing unit are alternately provided.

As a further aspect of the present invention, a plurality of guide bases are evenly provided on the inner wall of the cell wall crushing tank, the top of the guide base is an inclined surface, and the bottom end of the inclined surface is above the crushing blade. Due to the action of the guide base, the material that has fallen into the cell wall crushing tank falls onto the crushing blade that is rotating at a sufficiently high speed to ensure the cell wall crushing effect.

As a further aspect of the present invention, a drive motor for synchronously rotating the first cell wall crushing unit, the second cell wall crushing unit and a rotary ring is provided at the top of the cell wall crushing tank, and the output of the drive motor is provided. A shaft and a top end of the rotary shaft are connected to each other by a gear meshing method so as to be able to be transmitted. In the present embodiment, the drive motor that turns on the power and energizes it has the effect of crushing the material in the cell wall crushing tank by rotationally driving the rotary shaft and rotating the crushing blade at high speed.

As a further aspect of the present invention, a drive gear is attached to an output shaft of the drive motor, a transmission gear that meshes with the drive gear is attached to a top end of the rotation shaft, and the transmission is attached to an inner ring of the rotation ring. An annular rack that meshes with the other side of the gear is fixedly attached.

As a further aspect of the present invention, the push mechanism is rotatably provided inside a swinging guide plate that is elastically supported by the grind drum via a support spring and the grind tank. A rotating disk is provided, the rotating disk is rotatably installed inside the grind tank via a support rotating shaft provided on the center axis thereof, and one side of an outer end surface of the rotating disk is provided. A guide column is fixedly attached, a lower part of the rocking guide plate is rotatably provided inside the grind tank, and an upper part of the rocking guide plate has a long hole formed therein. It is slidably mounted on the guide column via.

As a further aspect of the present invention, a support plate is fixedly attached to the bottom end of the rotating disk, a base is fixedly attached to the top surface of the grind drum, and the support plate and the base are support springs. A support guide rod is symmetrically provided on the top surface of the grind drum, and the support guide rod is slidably provided on the support plate so as to be able to penetrate therethrough.

As a further aspect of the present invention, the bottom plate of the grind tank has an arcuate structure, and the push unit includes a rocking guide plate rotatably provided inside the grind tank. The support spring is in the compressed state when the pivot axis of the plate is located below the center of the circle of the bottom plate of the grind tank and the swinging guide plate is in the vertical state.

As a further aspect of the present invention, a feed screen is provided at a feed port at the bottom end of the grind tank communicating with the feed pipe, and the material sufficiently ground in the grind tank passes through the feed screen to pass through the feed pipe. Through the inside of the grind cylinder.

As a further aspect of the present invention, a motor for rotationally driving the cone grind rod is provided inside one side of the protective tank, and the rotating cone grind rod is made of a material that enters a grind cylinder. It can be finely ground.

Compared with the prior art, in the blender for extracting nutrients in plants according to the embodiment of the present invention, when the rotating ring is rotated until the feed through hole is aligned with the feed port, the material in the feed cavity is separated from the feed port and the feed through hole respectively to the cell wall. It solves the problem of entering the crushing tank and intermittently charging the material into the cell wall crushing tank, and the problem of impairing the crushing effect due to the material being accumulated by batch charging, and then using the drive motor. By rotating the first cell wall crushing unit and the second cell wall crushing unit in synchronism with each other, the initial cell wall crushing process is performed on the material put in the cell wall crushing tank from the inlet, and the ultrasonic generator and the grind drum are used. The cell wall crushing process is further performed on the material that has entered the grind tank through the supporting filter plate. Here, when the rotating disk is rotating, the guide column is interlocked with the circular motion to further swing the rocking sleeve. The installation plate is oscillated around its lower axis to oscillate the grind drum, and the pivot axis of the oscillating shaft is located below the center of the bottom plate of the grind tank. During the rocking process of the drum, the grinding force on the material in the grind tank by the grind drum changes continuously, which can ensure and improve the grinding effect of the material, and finally, the grind in the grinding tank. The material processed by the mechanism enters the grind cylinder, and the rotating cone grind rod pulverizes the material entered into the grind cylinder.

In order to more clearly describe the technical solution in the embodiments of the present invention, the drawings necessary for explaining the embodiments or the prior art will be briefly described below. It is only part of the example.

FIG. 3 is a structural schematic view of a blender for extracting nutrients in plants according to an example of the present invention.

FIG. 2 is an enlarged schematic diagram of a portion A in FIG. 1.

FIG. 3 is a structural schematic diagram of a grind mechanism in a blender for extracting nutrients in plants according to an example of the present invention.

FIG. 3 is a partial structural perspective view of a grind mechanism in a blender for extracting nutrients from plants according to an embodiment of the present invention.

FIG. 3 is a schematic diagram of a three-dimensional structure of a rotating disk in a blender for extracting nutrients from plants according to an example of the present invention.

1 is a front view of a gear transmission structure in a blender for extracting nutrients from plants according to an embodiment of the present invention.

It is an enlarged structure schematic diagram of B part in FIG.

To make the technical problems, technical solutions and beneficial effects to be solved by the present invention clearer, the present invention will be described in more detail with reference to the drawings and the embodiments. It should be noted that the specific embodiments described herein are merely for the purpose of interpreting the present invention and are not intended to limit the present invention.

As shown in FIGS. 1 to 7, in one embodiment according to the present invention, a blender for extracting nutrients in a plant is fixedly installed on the cell wall crushing tank 3 fixed to the top of the frame 1 and the bottom of the frame 1. Is a grind tank 11 in which a supply section is provided at the top of the cell wall crushing tank 3 and the bottom of the cell wall crushing tank 3 is in communication, and the grind tank 11 is the protective tank. 9, and an ultrasonic wave generator 10 is provided on each of the inner walls on both sides inside the protective tank 9.
In the supply unit according to the embodiment of the present invention, the supply unit includes a preliminary crushing tank 35 that is provided in communication with the top of the cell wall crushing tank 3 and has a preliminary crushing mechanism provided therein. The inlet 35 is provided at the top of the tank 35, and the supply unit further includes a rotating ring 27 rotatably provided in the cavity at the top of the cell wall crushing tank 3, and the rotating ring 27 and the cell wall crushing tank 3 are provided. A supply cavity 28 is formed between the inner wall of the top of the supply cavity 28 and the outlet of the bottom end of the preliminary crushing tank 25 extending to the inside of the supply cavity 28;
Further, an annular block plate 31 is fixedly attached to the outer ring at the bottom of the rotating ring 27, and the annular block plate 31 has two supply through holes 30 that are fitted to the supply ports 29 in the bottom plate of the supply cavity 28. Are provided symmetrically. In this embodiment, when the rotating ring 27 rotates until the supply through hole 30 is aligned with the supply port 29, the material in the supply cavity 28 enters the cell wall crushing tank 3 through the supply port 29 and the supply through hole 30, respectively, and the cell wall crushing tank. 3 plays a role of intermittently charging the material, and solves the problem that the material is deposited by batch charging and the crushing effect is impaired.

Inside the cell wall crushing tank 3, first cell wall crushing units 5 and second cell wall crushing units 6 are symmetrically provided alternately, and the first cell wall crushing unit 5 and the second cell wall crushing unit 5 are provided at the top of the cell wall crushing tank 3. A driving motor 4 for synchronously rotating the crushing unit 6 and the rotary ring 27 is further provided, and is located below the first cell wall crushing unit 5 and the second cell wall crushing unit 6 inside the cell wall crushing tank 3. A support filter plate 8 is provided, a grind mechanism is provided inside the grind tank 11, and the grind mechanism includes a grind drum 24 and a push unit for pushing and rocking the grind drum 24,
A grind cylinder 12 communicating with the bottom end of the cell wall crushing tank 3 via a supply pipe 16 is provided inside the protective tank 9, and a cone grind rod 14 rotates inside the grind cylinder 12. A discharge port 13 is provided at one end of the grind cylinder 12.

Specifically, in the embodiment according to the present invention, the first cell wall crushing unit 5 and the second cell wall crushing unit 6 have the same structure, and both are rotatably provided inside the cell wall crushing tank 3. The rotating shaft 51 and a plurality of crushing blades 53 evenly provided on the rotating shaft 51 are provided with a fixed bush 52 fixed to the outer ring of the rotating shaft 51, and the crushing blades 53 are fixed to each other. Fixedly attached to the bush 52,
The crushing blades 53 included in the first cell wall crushing unit 5 and the crushing blades 53 included in the second cell wall crushing unit 6 are alternately provided.
Further, in this embodiment, a plurality of guide bases 7 are evenly provided on the inner wall of the cell wall crushing tank 3, the top of the guide base 7 is an inclined surface, and the bottom end of the inclined surface is the crushing blade. The guide base 7 is located above 53, and by the action of the guide base 7, the material dropped in the cell wall crushing tank 3 falls on the crushing blade 53 rotating at a sufficiently high speed, and the cell wall crushing effect is secured.

Further, the output shaft of the drive motor 4 and the top end of the rotary shaft 51 are connected to each other by a gear meshing method so that they can be transmitted. In the present embodiment, the drive motor 4 that turns on the power and energizes the rotary shaft 51 to rotate the crushing blade 53 at high speed, thereby crushing the material in the cell wall crushing tank 3.

Specifically, a drive gear 33 is attached to the output shaft of the drive motor 4, a transmission gear 34 that engages with the drive gear is attached to the top end of the rotary shaft 51, and an inner ring of the rotary ring 27 is attached. The annular rack 32, which meshes with the other side of the transmission gear 34, is fixedly attached.

In the embodiment of the present invention, the support filter plate 8 is a support separator 81 in which a plurality of filter holes 82 are evenly provided. Here, the bottom end of the rotary shaft 51 and the support separator 81 are rotatable. Connected.

Further, as shown in FIGS. 1 to 5, in the embodiment according to the present invention, the push mechanism is connected to the grind drum 24 via a support spring 22 so as to be elastically supported so as to be supported. , And a rotating disc 17 rotatably provided inside the grind tank 11, and the rotating disc 17 is provided inside the grind tank 11 via a support rotating shaft 25 provided at the center axis thereof. A guide column 19 is fixedly attached to one side of an outer end surface of the rotating disk 17 so as to be rotatable, and a lower portion of the swinging guide plate 18 is rotated inside the grind tank 11. Movably provided, and the upper part of the swinging guide plate 18 is slidably mounted on the guide column 19 through an elongated hole formed in the swinging guide plate 18,
Further, a support plate 20 is fixedly attached to the bottom end of the rotating disk 17, and a base 21 is fixedly attached to the top surface of the grind drum 24. The support plate 20 and the base 21 are supported by each other. A support guide rod 23 is symmetrically provided on the top surface of the grind drum 24 via a spring 22 so that the support guide rod 23 can slide through the support plate 20 and penetrate therethrough. Is provided,
In particular, the bottom plate of the grind tank 11 has an arcuate structure, and the push unit includes a swinging guide plate 18 rotatably provided inside the grind tank 11, and the swinging guide plate 18 is provided. When the pivot axis of is located below the center of the circle of the bottom plate of the grind tank 11 and the swinging guide plate 18 is in the vertical state, the support spring 22 is in the compressed state,
Although not shown, a servomotor for rotationally driving the support rotary shaft 25 is attached to the rear side wall of the grind tank 11, and when the rotary disc 17 is rotated, the guide column 19 is provided. A circular motion is made in conjunction with each other, and further, the swinging guide plate 18 is swingably driven around an axis line at the lower part thereof to swingably drive the grind drum 24, and the rotation axis of the swinging support plate 18 is the above-mentioned grind. Since it is located below the center of the bottom plate of the tank 11, the grinding force of the grinding drum 24 on the material in the grinding tank 11 continuously changes during the swinging process of the grinding drum 24, whereby the grinding of the material is performed. The effect can be secured and improved.

Further, in the embodiment according to the present invention, a supply screen 26 is provided at the supply port at the bottom end of the grind tank 11 communicating with the supply pipe 16, and the material sufficiently ground in the grind tank 11 is supplied to the supply screen 26. And falls into the inside of the grind cylinder 12 via the supply pipe 16.

In the embodiment of the present invention, a motor 15 for rotatably driving the cone grind rod 14 is provided inside one side of the protective tank 9, and the rotating cone grind rod 14 serves as the grind cylinder 12. Finely crush the target material.

In the blender for extracting nutrients in plants according to the embodiment of the present invention, the driving motor 4 is used to rotationally drive the first cell wall crushing unit 5 and the second cell wall crushing unit 6 in synchronization, so that the cell wall from the input port 2 is driven. The initial cell wall crushing treatment is performed on the material put into the crushing tank 3, and the cell wall crushing treatment is further performed on the material that has entered the grind tank 11 through the supporting filter plate 8 by the ultrasonic generator 10 and the grind drum 24. ,
Here, when the rotating disk 17 is rotating, the guide column 19 is interlocked with each other to make a circular motion, and further, the swinging guide plate 18 is swingably driven around the axis line of the lower portion thereof to move the grind drum 24. Since it is driven to swing, and the rotation axis of the swinging guide plate 18 is located below the center of the circle of the bottom plate of the grind tank 11, during the swinging process of the grind drum 24, the grind drum 24 causes the grind tank 11 to move. The grind force on a material changes continuously, which can ensure and improve the grind effect of the material,
Finally, the material processed by the grind mechanism in the grind tank 11 enters the grind cylinder 12, and the rotating cone grind rod 14 finely grinds the material entered in the grind cylinder 12.

All the electric elements described in the present specification are electrically connected to an external main controller and a 220V commercial power source, and the main controller may be a known device for controlling, such as a computer.

In the description of the present invention, unless otherwise specified and limited, the terms “attach”, “connect”, and “connect” should be understood in a broad sense, for example, they may be fixedly connected, and detachable. They may be connected, integrally connected, mechanically connected, electrically connected, directly connected, or indirectly connected via an intermediate medium. The two elements may communicate with each other. Those skilled in the art can understand the meaning of the above terms in the present specification depending on the specific situation. ..

The above are only preferred embodiments of the present invention, and do not limit the present invention. All modifications, equivalent substitutions and improvements made without departing from the gist and principle of the present invention are protected by the present invention. Included in the range.

1-frame, 2-input port, 3-cell wall crushing tank, 4-drive motor, 5-first cell wall crushing unit, 6-second cell wall crushing unit, 7-guide base, 8-support filter plate , 9-protective tank, 10-ultrasonic generator, 11-grind tank, 12-grind cylinder, 13-discharge port, 14-cone grind rod, 15-motor, 16-supply pipe, 17-rotating disc, 18 -Rotating plate, 19-guide column, 20-support plate, 21-base, 22-support spring, 23-support guide rod, 24-grind drum, 25-support rotary shaft, 26-supply screen, 27- Rotating ring, 28-feed cavity, 29-feed port, 30-feed through hole, 31-annular block plate, 32-annular rack, 33-drive gear, 34-transmission gear, 35-preliminary grinding tank;
51-rotating shaft, 52-fixing bush, 53-crushing blade, 81-supporting separator, 82-filtering hole.

Claims (10)

A blender for extracting nutrients in plants, comprising a cell wall crushing tank (3) fixed to the top of the frame (1) and a protective tank (9) fixedly installed at the bottom of the frame (1), A supply part is provided at the top of the cell wall crushing tank (3), and the bottom of the cell wall crushing tank (3) is in communication with the grind tank (11), and the grind tank (11) is the protective tank ( 9) extends to the inside of the protective tank (9), and an ultrasonic generator (10) is provided on each of the inner walls on both sides inside the protective tank (9),
The first cell wall crushing unit (5) and the second cell wall crushing unit (6) are symmetrically provided alternately inside the cell wall crushing tank (3), and the first cell wall crushing unit (6) is provided inside the cell wall crushing tank (3). A support filtration plate (8) located below the cell wall crushing unit (5) and the second cell wall crushing unit (6) is provided, and a grind mechanism is provided inside the grind tank (11). A grind drum (24) and a push unit for pushing and swinging the grind drum (24), and inside the protective tank (9), the cell wall crushing tank (3) via a supply pipe (16). A grind cylinder (12) communicating with the bottom end of the grind cylinder (12) is provided, and a corn grind rod (14) is rotatably installed inside the grind cylinder (12). Blender. The supply unit includes a preliminary crushing tank (35) provided in communication with the top of the cell wall crushing tank (3) and having a preliminary crushing mechanism provided therein, and the top of the preliminary crushing tank (35) is provided. Is provided with an input port (2), and the supply unit further includes a rotating ring (27) rotatably provided in a cavity at the top of the cell wall crushing tank (3). A supply cavity (28) is formed between the cell wall crushing tank (3) and the inner wall of the top, and an outlet at the bottom end of the preliminary crushing tank (25) extends to the inside of the supply cavity (28),
An annular block plate (31) is fixedly attached to the outer ring at the bottom of the rotating ring (27), and the annular block plate (31) is fitted with a supply port (29) in the bottom plate of the supply cavity (28). The blender for extracting nutrients in a plant according to claim 1, wherein two mating supply through holes (30) are provided symmetrically. The first cell wall disruption unit (5) and the second cell wall disruption unit (6) have the same structure, and both are rotatable shafts (51) rotatably provided inside the cell wall disruption tank (3). And a plurality of crushing blades (53) evenly provided on the rotating shaft (51),
A fixed bush (52) is fixedly provided on the outer ring of the rotating shaft (51), and the crushing blade (53) is fixedly attached to the fixed bush (52). The crushing blade (53) included in (5) and the crushing blade (53) included in the second cell wall crushing unit (6) are provided alternately with each other, for extracting nutrients in plants according to claim 2. Blender. A plurality of guide bases (7) are evenly provided on the inner wall of the cell wall crushing tank (3), the top of the guide base (7) is an inclined surface, and the bottom end of the inclined surface is the crushing blade ( The blender for extracting nutrients in plants according to claim 3, wherein the blender is located above 53). At the top of the cell wall crushing tank (3), there is a drive motor (4) for synchronously rotating the first cell wall crushing unit (5), the second cell wall crushing unit (6) and the rotary ring (27). The extractor for nutrients in plants according to claim 3, wherein the output shaft of the drive motor (4) and the top end of the rotary shaft (51) are provided so as to be able to be transmitted by a gear meshing method. Blender. A drive gear (33) is attached to the output shaft of the drive motor (4), a transmission gear (34) meshing with the drive gear is attached to the top end of the rotary shaft (51), and the rotary ring (27). 6. The blender for extracting nutrients in plants according to claim 5, wherein an annular rack (32) meshing with the other side of the transmission gear (34) is fixedly attached to the inner ring of (4). The push unit pivots into the inside of the swing tank plate (18), which is elastically supported by the swing drum (24) via a support spring (22), and the grind tank (11). Rotatably provided with a rotating disc (17), and the rotating disc (17) is rotatable inside the grind tank (11) via a support rotating shaft (25) provided at its center axis. Was erected in
A guide column (19) is fixedly attached to one side of the outer end surface of the rotating disk (17), and the lower part of the swinging guide plate (18) rotates inside the grind tank (11). A swingably mounted plate (18) is slidably mounted on the guide column (19) through an elongated hole formed in the swingable plate (18). A blender for extracting nutrients in a plant according to any one of Items 2 to 6. A support plate (20) is fixedly attached to the bottom end of the rotating disk (17), and a base (21) is fixedly attached to the top surface of the grind drum (24). 20) and the base (21) are supportably connected via a support spring (22),
Support guide rods (23) are symmetrically provided on the top surface of the grind drum (24), and the support guide rods (23) are slidably provided on the support plate (20) so as to be penetrated. The blender for extracting nutrients in plants according to claim 7. The blender for extracting nutrients in plants according to claim 7, wherein a feed screen (26) is provided at a feed port at a bottom end of the grind tank (11) communicating with the feed pipe (16). .. A motor (15) for rotationally driving the cone grind rod (14) is provided inside one side of the protective tank (9), according to any one of claims 1 to 5. The blender for extracting nutrients in plants according to 1.