CN219073024U - Original ecological rice embryo retaining processing device - Google Patents

Abstract

The utility model provides an original ecological rice germ-retaining processing device, which comprises a shell, a discharging bin, a lower washboard, an upper washboard mechanism and an electric push rod, wherein: the upper part between the two discharging bins is fixedly provided with an electric push rod, and the extending end of the electric push rod is fixedly connected with the bottom surface of the lower washboard; the lower washboard is positioned above the two lower feed bins, the lower parts of the lower washboard are fixedly connected with one sides above the two lower feed bins respectively, and limiting plates are fixedly arranged at the positions of mirror images on the two sides above the lower washboard; the upper washboard mechanism is connected with the upper part of the lower washboard in a sliding way, and is fixedly connected with one side above one of the lower feed bins. When the utility model is used, the embryo can be uniformly reserved for processing the original ecological rice, and the original ecological rice is prevented from being piled up together, thereby greatly improving the integral processing quality and processing efficiency of the original ecological rice and being convenient for market popularization and application.

Description

Original ecological rice embryo retaining processing device

Technical Field

The utility model belongs to the field of rice processing, and particularly relates to an original ecological rice embryo retaining processing device.

Background

It is known that rice can be eaten after being milled, shelled and peeled by rice. Traditional rice milling technology adopts stone mill and sand roller milling. In order to obtain polished rice, the bran is removed, and meanwhile, the 'embryo' of the essence part of the rice is removed, so that the 'embryo' is quite unknown to contain abundant vitamins, plant fibers and trace elements necessary for human bodies.

As disclosed in chinese patent No. CN217120350U, a multi-extrusion and light-rolling germ-retaining rice mill is disclosed, one end of the processing cylinder is provided with an air box, the other end of the processing cylinder is provided with an air window, grinding wheel rollers are symmetrically and rotatably mounted in the processing cylinder, and rice grooves are formed in the surfaces of the two grinding wheel rollers at equal intervals. The rice milling machine is simple in structure and novel in design, the transmission assembly drives the two grinding wheel rollers to synchronously rotate, rice grains can be milled in the first rice milling cutter set and the second rice milling cutter set, the rice milling efficiency is improved, in addition, fine adjustment of the positions of the first rice milling cutter set and the second rice milling cutter set is realized through threaded connection between the screw rod and the connecting plate, and accordingly the distance between the first rice milling cutter set and the second rice milling cutter set and the grinding wheel rollers is changed, the practicability of the machine is improved, and rice milling of different varieties is facilitated.

However, when the above-mentioned processing device for remaining embryo of rice is used, the rice is easy to accumulate together, and the rice cannot be uniformly processed, so that the processing effect of the rice is affected.

Therefore, it is necessary to invent a processing device for original ecological rice embryo.

Disclosure of Invention

In order to solve the technical problems, the utility model provides an original ecological rice germ-retaining processing device, which comprises a shell, a discharging bin, a lower washboard, an upper washboard mechanism and an electric push rod, wherein: the upper part between the two discharging bins is fixedly provided with an electric push rod, and the extending end of the electric push rod is fixedly connected with the bottom surface of the lower washboard; the lower washboard is positioned above the two lower feed bins, the lower parts of the lower washboard are fixedly connected with one sides above the two lower feed bins respectively, and limiting plates are fixedly arranged at the positions of mirror images on the two sides above the lower washboard; the upper washboard mechanism is connected with the upper part of the lower washboard in a sliding way, and is fixedly connected with one side above one of the lower feed bins.

Preferably, a connecting groove is formed above the shell, a feed inlet is fixedly arranged in the connecting groove, and the feed inlet is communicated with the upper washboard mechanism; a control box is fixedly arranged on one side of the shell, supporting legs are uniformly and fixedly arranged on the bottom surface of the shell, and limit grooves are formed in symmetrical positions on the top surface inside the shell; the controller is fixedly arranged in the control box, and the controller in the control box is electrically connected with the electric push rod.

Preferably, a connecting frame is fixedly arranged between the two discharging bins, the front surfaces of the two discharging bins are respectively fixedly provided with a fan case, and the inside of each fan case is communicated with the inside of each discharging bin; the bottom ends of the two discharging bins are fixedly provided with discharging pipes respectively, and the interiors of the discharging pipes are communicated with the interiors of the discharging bins respectively; the two discharging bins are fixedly provided with bran discharging pipes on the back sides respectively, the interior of each bran discharging pipe is communicated with the interior of each discharging bin, and the positions of the bran discharging pipes correspond to the positions of the fan boxes and are on the same straight line; a fan is fixedly arranged in each fan case, the air outlet end of each fan corresponds to the bran inlet end of each bran outlet pipe, and each fan is electrically connected with a controller in the control case; one end of each of the two discharging pipes and one end of each of the two bran discharging pipes penetrate from the inside of the shell to the outside of the shell.

Preferably, a motor is fixedly arranged at one end of each discharging pipe, each motor is positioned at the outer side corresponding to the lower end of the discharging bin, and a shell breaking column is rotatably arranged in each discharging pipe; spiral bulges are fixedly arranged on the outer surface of each shell breaking column respectively, and one end of each shell breaking column is fixedly connected with a power shaft corresponding to the motor respectively; each motor is electrically connected with a controller in the control box.

Preferably, the upper washboard mechanism comprises an upper washboard, a discharging opening, a guide rail, a rotating shaft, a rocker arm, a rotating shaft I, a turntable and a servo motor, wherein the surface of the upper washboard is provided with the discharging opening, and the guide rail is fixedly arranged at the mirror image position of the two sides of the upper surface of the upper washboard; each guide rail is in sliding connection with the interior of the corresponding limit groove; the bottom surface of the upper washboard is in sliding connection with the upper surface of the lower washboard, the upper washboard is positioned between the two limiting plates above the lower washboard, one side above the upper washboard is in rotary connection with one end of a rocker arm through a rotating shaft, and the other end of the rocker arm is in rotary connection with one side above a rotary table through a first rotating shaft; the bottom end of the rotating shaft is fixedly connected with one side above the upper washboard, and the rotating shaft is rotationally connected with one end of the rocker arm; the bottom end of the first rotating shaft is fixedly connected with one side above the disc, and the first rotating shaft is rotationally connected with the other end of the rocker arm; the bottom surface of the turntable is fixedly connected with a power shaft of a servo motor, the bottom of the servo motor is fixedly connected with one side above one of the discharging bins, and the servo motor is electrically connected with a controller in the control box; the feed opening is located the below of feed inlet, and the inside of feed opening communicates with the inside of feed inlet.

Compared with the prior art, the utility model has the advantages that:

when the original ecological rice is processed by leaving the embryo, the original ecological rice can firstly enter between the upper washboard and the lower washboard, then the upper washboard is driven to reciprocate on the lower washboard, so that the original ecological rice can be subjected to bran removal work, and simultaneously, the two lower bins are matched, when the upper washboard reciprocates, the original ecological rice can uniformly fall into the corresponding two lower bins from the two sides of the lower washboard, when the bran removed original ecological rice carries bran shells to pass through the bran outlet pipe, the corresponding fan can blow the bran shells of the original ecological rice to the corresponding bran outlet pipe, the original ecological rice with the embryo left can fall into the discharging pipe, and then the motor drives the shell breaking column to rotate, in the rotating process, the spiral protrusions can discharge the bran removed original ecological rice through the discharging pipe, so that the original ecological rice is prevented from being piled together, and the bran removal work can be uniformly performed on the original ecological rice, and the whole processing quality and the processing efficiency of the bran removed original ecological rice are greatly improved.

Drawings

Fig. 1 is a schematic view of the structure of the blanking bin of the present utility model.

Fig. 2 is a schematic diagram of the cut-away structure of the blanking bin of the present utility model.

Fig. 3 is a schematic view of the housing of the present utility model in a cut-away configuration.

Fig. 4 is a schematic structural view of the upper washboard mechanism of the present utility model.

Fig. 5 is a schematic view of the overall structure of the present utility model.

In the figure:

the automatic feeding device comprises a shell 1, a lower bin 2, a lower washboard 3, an upper washboard mechanism 4, an upper washboard 41, a feed opening 42, a guide rail 43, a rotating shaft 44, a rocker arm 45, a rotating shaft I46, a rotating disc 47, a servo motor 48, a fan box 5, a discharge pipe 6, an electric push rod 7, a bran outlet pipe 8, a fan 9, a connecting frame 10, a motor 11, a shell breaking column 12, a spiral protrusion 13, a feed opening 14, a connecting groove 15, a control box 16, supporting legs 17 and a limiting groove 18.

Detailed Description

In order that those skilled in the art will better understand the present utility model, a technical solution of the embodiments of the present utility model will be clearly and completely described below, and it is apparent that the described embodiments are only some embodiments of the present utility model, not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the present utility model without making any inventive effort, shall fall within the scope of the present utility model.

The utility model is further described below with reference to the accompanying drawings:

example 1

Referring to fig. 1 to 5, an original ecological rice germ-retaining processing device comprises a shell 1, a lower bin 2, a lower washboard 3, an upper washboard mechanism 4 and an electric push rod 7, wherein: two blanking bins 2 are fixedly arranged at the mirror image position inside the shell 1, an electric push rod 7 is fixedly arranged above the two blanking bins 2, and the extending end of the electric push rod 7 is fixedly connected with the bottom surface of the lower washboard 3, so that when the original ecological rice is subjected to embryo retaining processing, the distance between the lower washboard 3 and the upper washboard mechanism 4 can be adjusted through the electric push rod 7, and the original ecological rice with different quantities can be subjected to embryo retaining processing; the lower washboard 3 is positioned above the two lower feed bins 2, the lower parts of the lower washboard 3 are fixedly connected with one sides above the two lower feed bins 2, and the two ends of the lower washboard 3 are respectively positioned in the middle above the corresponding lower feed bins 2, so that when the upper washboard mechanism 4 is rubbed, original ecological rice can enter the corresponding two lower feed bins 2 from the two ends of the lower washboard 3, and limiting plates are fixedly arranged at the positions of mirror images of the two sides above the lower washboard 3; the upper washboard mechanism 4 is in sliding connection with the upper part of the lower washboard 3, and the upper washboard mechanism 4 is fixedly connected with one side above one of the lower feed bins 2.

The upper part of the shell 1 is provided with a connecting groove 15, a feed inlet 14 is fixedly arranged in the connecting groove 15, and the feed inlet 14 is communicated with the upper washboard mechanism 4; a control box 16 is fixedly arranged on one side of the shell 1, supporting legs 17 are uniformly and fixedly arranged on the bottom surface of the shell 1, and limit grooves 18 are formed in symmetrical positions on the top surface inside the shell 1; the controller is fixedly arranged in the control box 16, and the controller in the control box 16 is electrically connected with the electric push rod 7;

when the original ecological rice is left to be embryo processed, the original ecological rice can be fixedly connected with a discharge hole of an external original ecological rice automatic feeding device through the connecting groove 15, so that the external automatic feeding device feeds the original ecological rice into the feed inlet 14, and then the original ecological rice enters between the lower washboard 3 and the upper washboard 41 through the feed inlet 14 to perform bran removing work.

A connecting frame 10 is fixedly arranged between the two discharging bins 2, the front surfaces of the two discharging bins 2 are respectively fixedly provided with a fan case 5, and the inside of each fan case 5 is communicated with the inside of each discharging bin 2; the bottom ends of the two discharging bins 2 are fixedly provided with discharging pipes 6 respectively, and the interiors of the discharging pipes 6 are communicated with the interiors of the discharging bins 2 respectively; the back surfaces of the two discharging bins 2 are fixedly provided with bran discharging pipes 8 respectively, the interior of each bran discharging pipe 8 is communicated with the interior of each discharging bin 2, and the positions of each bran discharging pipe 8 correspond to the positions of each fan box 5 and are on the same straight line; a fan 9 is fixedly arranged in each fan case 5, the air outlet end of each fan 9 corresponds to the bran inlet end of each bran outlet pipe 8, and each fan 9 is electrically connected with a controller in the control case 16; one end of each of the two discharging pipes 6 and the two bran discharging pipes 8 penetrates from the inside of the shell 1 to the outside of the shell 1;

when the original ecological rice is left with embryo, each bran outlet pipe 8 is connected with an external bran shell collecting device, when the bran removed original ecological rice carries bran shells to pass through the bran outlet pipe 8, the fan 9 blows the bran shells of the original ecological rice into the bran outlet pipe 8, so that the bran shells enter the collecting device through the bran outlet pipe 8, and the original ecological rice left with embryo automatically falls into the corresponding discharging pipe 6.

One end of each discharging pipe 6 is fixedly provided with a motor 11, each motor 11 is positioned at the outer side of the lower end of the corresponding discharging bin 2, and a shell breaking column 12 is rotatably arranged in each discharging pipe 6; the outer surface of each shell breaking column 12 is fixedly provided with a spiral protrusion 13, and one end of each shell breaking column 12 is fixedly connected with a power shaft of a corresponding motor 11; each motor 11 is electrically connected with a controller inside the control box 16;

when the original ecological rice is left with embryo, the outer end of the discharging pipe 6 can be connected with a bin of an external automatic feeding device, so that when the original ecological rice entering the discharging pipe 6 is not thoroughly bran-removed, under the condition that the shell breaking column 12 rotates, the spiral bulge 13 can perform bran-removing work on the original ecological rice again, then the bran-removed original ecological rice carries bran shells into the bin of the external automatic feeding device, and the original ecological rice carries bran shells into the feed inlet 14 through the external automatic feeding device, so that bran-removing separation work can be circularly performed on the original ecological rice; simultaneously, the outer end of the discharging pipe 6 can be directly connected with other external separating mechanisms, so that the whole discharging pipe is very flexible and convenient.

The upper washboard mechanism 4 comprises an upper washboard 41, a feed opening 42, a guide rail 43, a rotating shaft 44, a rocker arm 45, a rotating shaft I46, a rotating disc 47 and a servo motor 48, wherein the feed opening 42 is formed in the surface of the upper washboard 41, and the guide rail 43 is fixedly arranged at the mirror image position of the two sides of the upper surface of the upper washboard 41; each guide rail 43 is in sliding connection with the inside of the corresponding limit groove 18; the bottom surface of the upper washboard 41 is in sliding connection with the upper surface of the lower washboard 3, the upper washboard 41 is positioned between the two limiting plates above the lower washboard 3, one side above the upper washboard 41 is in rotary connection with one end of a rocker 45 through a rotary shaft 44, and the other end of the rocker 45 is in rotary connection with one side above a rotary table 47 through a rotary shaft 46; the bottom end of the rotating shaft 44 is fixedly connected with one side above the upper washboard 41, and the rotating shaft 44 is rotationally connected with one end of the rocker arm 45; the bottom end of the first rotating shaft 46 is fixedly connected with one side above the disc 47, and the first rotating shaft 46 is rotationally connected with the other end of the rocker arm 45; the bottom surface of the turntable 47 is fixedly connected with a power shaft of a servo motor 48, the bottom of the servo motor 48 is fixedly connected with one side above one of the discharging bins 2, and the servo motor 48 is electrically connected with a controller in the control box 16; the feed opening 42 is arranged below the feed opening 14, and the upper part of the feed opening 42 is in contact sliding connection with the bottom of the feed opening 14 and is communicated with the inside of the feed opening 14; the feed opening 42 is always movable within the range of the feed opening 14; the distance between the upper washboard 41 and the lower washboard 3 is 3cm to 10cm;

when the original ecological rice is left to be embryo, the original ecological rice can enter a gap between the upper washboard 41 and the lower washboard 3 through the blanking opening 42, then the servo motor 48 drives the rotary disc 47 to drive one end of the rocker arm 45 to rotate along with the rotary disc 47, the other end of the rocker arm 45 pulls the upper washboard 41 to reciprocate on the lower washboard 3, so that bran removing work is carried out on the original ecological rice between the upper washboard 41 and the lower washboard 3, and the limiting groove 18 can limit the upper washboard 41 when the upper washboard 41 reciprocates, so that the upper washboard 41 is prevented from displacement.

In this embodiment, each bran outlet pipe 8 is connected with an external bran shell collecting device, and then is fixedly connected with a discharge port of an external original ecological automatic rice feeding device through a connecting groove 15, so that the external automatic feeding device feeds original ecological rice into a feed port 14, then the original ecological rice enters a discharge port 42 through the feed port 14, and then the original ecological rice enters a gap between a lower washboard 3 and an upper washboard 41 through the discharge port 42; at the moment, one end of the rocker arm 45 is driven by the turntable 47 to rotate along with the turntable 47 through the servo motor 48, so that the other end of the rocker arm 45 pulls the upper washboard 41 to reciprocate on the lower washboard 3, and the original ecological rice between the upper washboard 41 and the lower washboard 3 is rubbed to remove bran; when the upper washboard 41 is used for twisting in a reciprocating manner, the original ecological rice after bran removal can be extruded, the original ecological rice after bran removal at the two ends of the lower washboard 3 falls into the two corresponding lower bins 2, when the original ecological rice after bran removal passes through the bran outlet pipe 8 with bran shells carried by the original ecological rice, the bran shells of the original ecological rice are blown into the bran outlet pipe 8 by the fan 9, so that the bran shells enter the collecting device through the bran outlet pipe 8, and the original ecological rice after embryo retention automatically falls into the corresponding discharging pipe 6; at this time, the motor 11 drives the shell breaking column 12 to rotate, when the shell breaking column 12 rotates, the spiral protrusion 13 can push the raw rice after bran removal and embryo retention to be discharged through the discharging pipe 6, and at this time, a corresponding collecting device is placed below the discharging pipe 6.

By utilizing the technical scheme of the utility model or under the inspired by the technical scheme of the utility model, a similar technical scheme is designed by a person skilled in the art, so that the technical effects are achieved, and the technical scheme falls into the protection scope of the utility model.

Claims (5)

1. An original ecology rice leaves embryo processingequipment, its characterized in that: including shell (1), feed bin (2), lower washboard (3), go up washboard mechanism (4) and electric putter (7), wherein: two discharging bins (2) are fixedly arranged at the mirror image position inside the shell (1), an electric push rod (7) is fixedly arranged above the space between the two discharging bins (2), and the extending end of the electric push rod (7) is fixedly connected with the bottom surface of the lower washboard (3); the lower washboard (3) is positioned above the two lower feed bins (2), the lower parts of the lower washboard (3) are fixedly connected with one sides above the two lower feed bins (2), and limiting plates are fixedly arranged at mirror image positions on two sides above the lower washboard (3); the upper washboard mechanism (4) is connected with the upper part of the lower washboard (3) in a sliding way, and the upper washboard mechanism (4) is fixedly connected with one side above one of the lower storage bins (2).

2. The original ecology rice germ cell processing apparatus of claim 1 wherein: a connecting groove (15) is formed above the shell (1), a feed inlet (14) is fixedly arranged in the connecting groove (15), and the inside of the feed inlet (14) is communicated with the inside of the upper washboard mechanism (4); one side of the shell (1) is fixedly provided with a control box (16), the bottom surface of the shell (1) is uniformly and fixedly provided with supporting legs (17), the top surface of the interior of the shell (1) is provided with limit grooves (18) at symmetrical positions, and the interior of each limit groove (18) is respectively in sliding connection with the upper washboard mechanism (4); the controller is fixedly arranged in the control box (16), and the controller in the control box (16) is electrically connected with the electric push rod (7).

3. The original ecology rice germ cell processing apparatus of claim 1 wherein: a connecting frame (10) is fixedly arranged between the two discharging bins (2), a fan box (5) is fixedly arranged on the front surfaces of the two discharging bins (2), and the inside of each fan box (5) is communicated with the inside of each discharging bin (2); the bottom ends of the two discharging bins (2) are fixedly provided with discharging pipes (6), and the inside of each discharging pipe (6) is communicated with the inside of the discharging bin (2); the back surfaces of the two discharging bins (2) are respectively fixedly provided with a bran outlet pipe (8), the interior of each bran outlet pipe (8) is communicated with the interior of each discharging bin (2), and the position of each bran outlet pipe (8) corresponds to the position of each fan box (5) and is on the same straight line; a fan (9) is fixedly arranged in each fan box (5), the air outlet end of each fan (9) corresponds to the bran inlet end of each bran outlet pipe (8), and each fan (9) is electrically connected with a controller in the control box (16); one end of each of the two discharging pipes (6) and one end of each of the two bran discharging pipes (8) penetrate from the inside of the shell (1) to the outside of the shell (1).

4. A primary ecological rice germ cell processing apparatus as in claim 3 wherein: one end of each discharging pipe (6) is fixedly provided with a motor (11), each motor (11) is positioned at the outer side corresponding to the lower end of the discharging bin (2), and a shell breaking column (12) is rotatably arranged in each discharging pipe (6); the outer surface of each shell breaking column (12) is fixedly provided with a spiral protrusion (13), one end of each shell breaking column (12) is fixedly connected with a power shaft corresponding to the motor (11), and each motor (11) is electrically connected with a controller in the control box (16).

5. The original ecology rice germ cell processing apparatus of claim 2 wherein: the upper washboard mechanism (4) comprises an upper washboard (41), a feed opening (42), guide rails (43), a rotating shaft (44), a rocker arm (45), a first rotating shaft (46), a rotary table (47) and a servo motor (48), wherein the feed opening (42) is formed in the surface of the upper washboard (41), and the guide rails (43) are fixedly arranged at the mirror image positions of the two sides of the upper surface of the upper washboard (41); each guide rail (43) is in sliding connection with the inside of the corresponding limit groove (18); the bottom surface of the upper washboard (41) is in sliding connection with the upper surface of the lower washboard (3), the upper washboard (41) is positioned between the two limiting plates above the lower washboard (3), one side above the upper washboard (41) is in rotary connection with one end of a rocker arm (45) through a rotary shaft (44), and the other end of the rocker arm (45) is in rotary connection with one side above a rotary table (47) through a rotary shaft I (46); the bottom end of the rotating shaft (44) is fixedly connected with one side above the upper washboard (41), and the rotating shaft (44) is rotationally connected with one end of the rocker arm (45); the bottom end of the first rotating shaft (46) is fixedly connected with one side above the disc (47), and the first rotating shaft (46) is rotationally connected with the other end of the rocker arm (45); the bottom surface of the rotary table (47) is fixedly connected with a power shaft of a servo motor (48), the bottom of the servo motor (48) is fixedly connected with one side above one of the discharging bins (2), and the servo motor (48) is electrically connected with a controller in the control box (16); the blanking port (42) is arranged below the feeding port (14), and the inside of the blanking port (42) is communicated with the inside of the feeding port (14).

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