KR20230010371A - Manufacturing apparatus for scorched rice - Google Patents

Abstract

Disclosed is a device for manufacturing scorched rice. The device for manufacturing scorched rice according to the present invention comprises: a raw material supply unit receiving and stirring raw materials for scorched rice, extruding and transporting the stirred raw materials, and supplying the same through a raw material discharge port; a molding unit provided with a plurality of molding plates disposed at a lower part of the raw material discharge port having a lower plate which receives the raw materials discharged from the raw material discharge port and an upper plate which is relatively rotatably connected to the lower plate and pressurizes the raw materials supplied to the lower plate to mold scorched rice, and a molding plate moving unit connected to the plurality of molding plates and allowing the plurality of molding plates to cross the raw material supply unit and move continuously; and a moving unit connected to the raw material supply unit and returning the raw material supply unit to supply the raw materials to the next lower plate after supplying raw materials to the lower plate by moving the raw material supply unit at the same speed as the moving speed of the lower plate along a moving direction of the lower plate so that the lower plate is placed at the lower part of the raw material discharge port to supply the raw materials to the lower plate while the lower plate is moving. Accordingly, product quality can be improved and production yield can be increased.

Description

Nurungji manufacturing device {MANUFACTURING APPARATUS FOR SCORCHED RICE}

The present invention relates to a scorched rice manufacturing apparatus.

In general, scorched rice is created according to the temperature difference of the bottom surface of the rice cooker when cooking rice. It is widely used as a substitute for snacks due to its savory and unique taste. are manufactured using

Nurungji is produced in two food types: Nurungji, a processed grain product for boiling made with boiled rice, and Nurungji, an instant cooking product for instant cooking made with Jinbap.

In particular, in order to make the ready-to-cook food Nurungji ready-to-eat by pouring only hot water into the product, it must be sufficiently luxurious before being put into a molding plate equipped with a bottom plate and an upper plate for forming Nurungji, so jinbap with a high moisture content should be used. Therefore, unlike Nurungji, a processed grain product, Nurungji, an instant cooked food, takes a long time to bake on a molded plate and must be baked at a high temperature. Compared to Nurungji, a processed grain product, the product yield is reduced. There is a problem of deterioration in quality.

In addition, raw materials (jinbap) for ready-to-cook nurungji are manually put into a hot molding plate, so workers are exposed to continuous heat and frequently suffer low-temperature burns, and workers constantly complain of dizziness and headaches due to hot heat. There is a problem in that workability is deteriorated due to the increase in fatigue of workers due to frequent cases.

Republic of Korea Patent Registration No. 10-0920333 (2009.10.07. Notice)

Therefore, the technical problem to be solved by the present invention is to provide a scorched rice manufacturing apparatus capable of improving product quality and product yield and reducing the number of man-hours.

According to one aspect of the present invention, a raw material supply unit for receiving and stirring raw materials for scorched rice, extruding and transferring the stirred raw materials, and supplying them through a raw material discharge port; A plurality of molded nurungji having a lower plate disposed below the raw material outlet and receiving the raw material discharged from the raw material outlet and an upper plate rotatably connected to the lower plate and pressurizing the raw material supplied to the lower plate. a forming unit having a forming plate and a forming plate moving unit connected to the plurality of forming plates and continuously moving the plurality of forming plates crossing the raw material supply unit; And connected to the raw material supply unit, while the lower plate is moved, the lower plate is disposed under the raw material outlet so as to supply the raw material to the lower plate at the same speed as the moving speed of the lower plate along the moving direction of the lower plate. A scorched rice manufacturing apparatus including a moving unit for moving the raw material supply unit to supply raw materials to the lower plate and then returning the raw material supply unit to supply raw materials to the lower plate in the next order may be provided.

The moving unit may include a base plate connected to a lower portion of the raw material supply unit to support the raw material supply unit; A plurality of first LM guide rails disposed under the base plate along the moving direction of the lower plate; and a first LM drive unit having one side connected to the base plate and the other side connected to the plurality of first LM guide rails to allow the base plate to reciprocate along the plurality of first LM guide rails. .

The first LM driver may include a plurality of first LM blocks having one side coupled to the base plate and the other side coupled to the first LM guide rail; at least one ball screw coupled to a lower portion of the base plate; and a driving motor connected to the ball screw to rotate the ball screw.

Further comprising an alignment unit provided between the raw material supply unit and the moving unit to align the raw material discharge port to be located on the upper part of the lower plate, wherein the alignment unit intersects the first LM guide rail on the upper part of the base plate a plurality of second LM guide rails arranged in a direction; And a second LM drive unit having one side connected to the raw material supply unit and the other side connected to the plurality of second LM guide rails to enable the raw material supply unit to reciprocate along the plurality of second LM guide rails. can

The raw material supply unit includes an agitator for receiving and agitating the raw material; And it may include an extrusion conveying part formed with the raw material discharge port for extruding and conveying the raw material supplied from the stirring part and discharging the raw material at the end.

The stirring unit, a hopper into which the raw material is put; and a stirrer disposed at a lower portion of the hopper to stir the raw material and supply it to the extrusion transfer unit.

The agitator may include a body into which the raw material flows from the hopper; A plurality of stirring blades disposed inside the body, one side of which is coupled to a rotation shaft passing through the body, the other side extending in a radial direction of the rotation shaft, and formed in a “T” shape with an end parallel to the rotation shaft; and a first rotation motor disposed outside the body and connected to the rotation shaft to rotate the plurality of stirring blades.

The extrusion transfer unit, the raw material stirred in the stirrer is introduced into the cylinder and the raw material inlet is formed at the end; a conveying screw provided inside the cylinder and extruding and transporting the raw material in the direction of the raw material discharge port as it rotates; and a second rotation motor disposed outside the cylinder and connected to the transfer screw to rotate the transfer screw.

The raw material supply unit, doedoe provided in the cylinder, further includes a discharge amount control unit for adjusting the discharge amount of the raw material discharged from the raw material outlet to the lower plate, the discharge amount control unit is coupled to the cylinder, the raw material discharge port Combining block disposed at the bottom; a cutting plate provided inside the coupling block and disposed below the raw material outlet, opening and closing the raw material outlet as it reciprocates, and cutting the raw material discharged from the raw material outlet; and an actuator coupled to the coupling block and connected to the cutting plate to allow the cutting plate to reciprocate.

The discharge amount control unit may further include a water supply hose coupled to the coupling block and supplying water to the upper surface of the cutting plate to prevent the raw material from adhering to the upper surface of the cutting plate.

The embodiment of the present invention synchronizes the moving speed of the molding plate and the raw material supply unit to supply the raw material to the lower plate while moving the raw material supply unit along the moving direction of the lower plate, and then returns the raw material supply unit to supply the raw material to the next lower plate. By repeating the commanded operation, the operator's exposure to heat can be minimized and man-hours can be reduced.

In addition, the embodiment of the present invention can improve the product quality and increase the product yield by extruding and transferring the raw material and automatically supplying the raw material in a fixed amount to the lower plate forming the molding plate.

1 is a schematic diagram showing a scorched rice manufacturing apparatus according to the present invention.
2 is a perspective view showing a stirring blade according to the present invention.
3 and 4 are side views illustrating the operation of the discharge amount control unit according to the present invention.
5 is a perspective view showing movement of molding plates according to the present invention.
6 and 7 are diagrams showing the moving operation of the raw material supply unit by the moving unit according to the present invention.

In order to fully understand the present invention and the advantages in operation of the present invention and the objects achieved by the practice of the present invention, reference should be made to the accompanying drawings illustrating preferred embodiments of the present invention and the contents described in the accompanying drawings.

Hereinafter, the present invention will be described in detail by describing preferred embodiments of the present invention with reference to the accompanying drawings. Like reference numerals in each figure indicate like elements.

1 is a schematic view showing a scorched rice manufacturing apparatus according to the present invention, Figure 2 is a perspective view showing a stirring blade according to the present invention, Figures 3 and 4 are side views showing the operation of the discharge amount control unit according to the present invention, Figure 5 is a perspective view showing the movement of molding plates according to the present invention, and FIGS. 6 and 7 are views showing the moving operation of the raw material supply unit by the moving unit according to the present invention.

Referring to FIG. 1, the scorched rice manufacturing apparatus 100 according to the present invention includes a raw material supply unit 110 having a raw material discharge port 132 for supplying raw materials of scorched rice, and a molding plate 151, but the raw material supply unit The raw material supply unit 110 along the moving direction of the forming plate 151 by synchronizing the molding unit 150 for receiving raw materials from the 110 and molding the nurungji, the molding plate 151, and the raw material supply unit 110 A moving unit 160 for reciprocating, an alignment unit 170 for aligning the raw material outlet 132 to be located on the upper part of the molding plate 151, and moving the raw material supply unit 110 and the molding unit 150 It includes a control unit (not shown) connected to the unit 160 and the alignment unit 170 to control the operation.

The raw material supply unit 110 according to the present embodiment plays a role in receiving and stirring raw materials for scorched rice, extruding and transporting the stirred raw materials, and supplying them to the forming unit 150.

In this embodiment, the raw material for nurungji is not particularly limited, and may be selected from various food materials in consideration of the taste, nutrition, and preference of consumers of nurungji. The raw material for scorched rice may be selected from cooked grains including, for example, rice, beans, barley, mung beans, sesame seeds, nuts and/or mixtures thereof (multigrains). In addition, the raw material for nurungji may further include nutrients such as vitamins and minerals, and/or seasonings such as salt and sugar, in addition to grains. In particular, in this embodiment, it can be used as a raw material for scorched rice regardless of the moisture content contained in rice such as doenbap and jinbap.

Specifically, the raw material supply unit 110 includes a stirring unit 120 for receiving and stirring the raw material, and an extrusion transfer unit 130 for extruding and transferring the raw material supplied to the stirring unit 120 .

The agitator 120 includes a hopper 121 into which raw materials are introduced, and an agitator 122 disposed under the hopper 121 to stir the raw materials and supply them to the extrusion transfer unit 130 .

In this embodiment, the agitator 122 is coupled to the body 123 into which raw materials are introduced from the hopper 121, and the rotating shaft 125 disposed inside the body 123 and passing through the body 123 to be spaced apart from each other It includes a plurality of stirring blades 124 and a first rotation motor 126 connected to the rotating shaft 125 to rotate the rotating shaft 125 and the stirring blades 124 .

The hopper 121 and the body 123 are formed to communicate with each other, and the raw material put into the hopper 121 flows into the body 123 of the agitator 122. And the raw material introduced into the body 123 is stirred by a plurality of stirring blades 124 disposed inside the body 123.

The stirring blades 124 are coupled to the rotation shaft 125 penetrating the body 123 to be spaced apart from each other. A first rotation motor 126 connected to the rotation shaft 125 is disposed outside the body 123 . The stirring speed of the raw material may be adjusted by controlling the rotation and rotation speed of the first rotation motor 126 .

On the other hand, as shown in FIG. 2, in this embodiment, in order to facilitate stirring of the raw material, the shape of the stirring blades 124 is formed in a “T” shape (or hoe shape). That is, the agitation blade 124 may be formed in a "T" shape (or hoe shape) with one side coupled to the rotation shaft 125 and the other side extending in the radial direction of the rotation shaft 125 and the end parallel to the rotation shaft 125. there is.

Then, the raw material put into the hopper 121 and stirred by the agitator 122 is supplied to the extrusion transfer unit 130. The extrusion transfer unit 130 extrudes and transfers the raw material supplied from the stirrer 122 and supplies it to the molding unit 150 .

The extrusion transfer unit 130 includes a cylinder 131 into which the raw material agitated by the agitator 122 is introduced and a raw material outlet 132 formed at the end, and a cylinder head 133 detachably coupled to the end of the cylinder 131 ), and a transfer screw 134 provided inside the cylinder 131 and extruding and transporting the raw material in the direction of the raw material discharge port 132 as it rotates, and a transfer screw 134 disposed outside the cylinder 131 and connected to the transfer screw 134 and a second rotation motor 135 for rotating the transfer screw 134.

The cylinder 131 communicates with the body 123 of the agitator 122 at one end to form a raw material supply hole H through which the raw material stirred in the agitator 122 is supplied, and at the other end (ie, the end). A raw material discharge port 132 through which the raw material transported by the transfer screw 134 is discharged is formed. In this embodiment, the cylinder 131 is shown as one long cylinder 131, but is not limited thereto and may be formed by combining a plurality of unit cylinders.

At least one first water supply hose 136 is connected to the cylinder 131 along the longitudinal direction of the cylinder 131 to prevent the raw material from being attached (or adhered) to the inner wall of the cylinder 131 while the raw material is being transported. It is possible to supply water to the inner wall of the cylinder 131.

The cylinder head 133 is detachably coupled to the other end of the cylinder 131, that is, to the end of the cylinder 131. After separating the cylinder head 133 from the end of the cylinder 131, the transfer screw 134 can be mounted in the cylinder 131 or the transfer screw 134 installed in the cylinder 131 can be separated, and the cylinder ( 131), the cylinder head 133 is coupled to the end of the cylinder 131 after mounting the transfer screw 134 therein.

The transfer screw 134 extrudes and transfers the raw material supplied to the cylinder 131 in the direction of the raw material outlet 132 . In this embodiment, the transfer screw 134 is shown as one long transfer screw 134, but may be configured as a screw combination in which a plurality of screw elements are combined.

The conveying screw 134 extrudes and transfers the raw material supplied into the cylinder 131, and the conveying speed of the raw material conveyed by the conveying screw 134 can be controlled by adjusting the pitch of the conveying screw 134. there is. That is, as the pitch of the conveying screw 134 increases, the conveying speed of the raw material in the cylinder 131 increases.

In this embodiment, the pitch of the transfer screw 134 may be 60 mm, and the pitch of the transfer screw 134 may be adjusted in consideration of the amount of the raw material supplied to the molding unit 150 through the raw material outlet 132.

The second rotation motor 135 is disposed outside the cylinder 131 and is connected to the transfer screw 134. The feed rate of the raw material in the cylinder 131 may be adjusted by controlling the rotation and rotation speed of the second rotation motor 135 .

As described above, the extrusion transfer unit 130 adjusts the pitch and rotational speed of the transfer screw 134 to extrude and transfer the raw material in the cylinder 131 in the direction of the raw material outlet 132 so that a fixed amount of the raw material is supplied to the raw material outlet 132. ) to be supplied to the molding unit 150 through.

As a result, when the amount of raw material supplied to the molding plate 151 is non-uniform according to the properties of rice, which is the raw material of scorched rice, such as conventional rice or jinbap, and the raw material is baked in the molding plate 151 at a set baking time and temperature, the amount of raw material supplied Accordingly, it is possible to solve the problem of deterioration in quality of the product, such as that the raw material is not heated uniformly as a whole, a part is burned or the whole is not baked uniformly.

That is, the raw material is extruded and transferred through the extrusion transfer unit 130 and the raw material is supplied in a fixed amount to the lower plate 152 constituting the molding plate 151 to improve product quality and increase product yield.

On the other hand, the raw material supply unit 110 according to the present embodiment further includes a discharge amount control unit 140 to more precisely control the supply amount regardless of the properties of the raw material supplied to the molding unit 150. The supply amount of the raw material can be more precisely controlled by the discharge amount control unit 140, so that the baking time and temperature of the raw material in the molding plate 151 can be kept constant according to the supply amount of the raw material, thereby improving product quality and increasing product yield. can

The discharge amount control unit 140 is provided in the cylinder 131 and controls the discharge amount (or supply amount) of the raw material discharged from the raw material discharge port 132 to the lower plate 152 of the molding plate 151 to be described later.

As shown in FIGS. 3 and 4, the discharge amount control unit 140 is coupled to the cylinder 131, and the coupling block 141 disposed below the raw material discharge port 132 and the inside of the coupling block 141 It is provided and disposed under the raw material outlet 132, and opens and closes the raw material outlet 132 as it reciprocates, but is coupled to the cutting plate 142 for cutting the raw material discharged from the raw material outlet 132 and the coupling block 141. Doedoe connected to the cutting plate 142 to enable the cutting plate 142 to reciprocate back and forth, coupled to the actuator 143 and the coupling block 141 to prevent raw materials from being attached to the upper surface of the cutting plate 142 It includes a second water supply hose 144 for supplying water to the upper surface of the cutting plate 142 to do so.

The raw material is extruded and conveyed in the direction of the raw material discharge port 132 in the cylinder 131 by the extrusion transfer unit 130 . At this time, as shown in FIG. 3 , in order to supply the raw material to the molding plate 151 , the raw material outlet 132 is opened by reversing the cutting plate 142 , which closes the raw material outlet 132 .

The forward and backward reciprocation of the cutting plate 142 is operated by an actuator 143 connected to the cutting plate 142 . In this embodiment, the actuator 143 can be operated by hydraulic pressure or pneumatic pressure, and one end of the cutting plate 142 is connected to the rod of the actuator 143, and the cutting plate 142 moves forward according to the extension and contraction of the rod. and backward reciprocating motion.

In addition, when the cutting plate 142 moves backward, water is supplied to the upper surface of the cutting plate 142 through the second water supply hose 144 to prevent the raw material from adhering or sticking to the upper surface of the cutting plate 142. can

Then, the material is continuously discharged through the raw material outlet 132 by the extrusion transfer unit 130 in a state in which the raw material outlet 132 is opened by moving the cutting plate 142 backward. At this time, in order to supply a quantity of raw material to the molding plate 151, as shown in FIG. 4, the cutting plate 142 is moved forward to cut the raw material continuously discharged from the raw material outlet 132 and the raw material outlet 132 is closed. do. The raw material lump cut by the cutting plate 142 is dropped onto the lower plate 152 of the molding plate 151 .

The forming unit 150 according to the present embodiment plays a role in forming scorched rice by receiving raw materials from the raw material supply unit 110 and pressurizing the raw materials.

As shown in FIGS. 1 and 5, the molding unit 150 is connected to a plurality of molding plates 151 arranged continuously to form scorched rice and a plurality of molding plates 151 ( 151) sequentially crosses the raw material supply unit 110 and includes a molding plate moving unit 154 that continuously moves.

The molding plate 151 is disposed below the raw material outlet 132 and is connected to the lower plate 152 to receive the raw material discharged from the raw material outlet 132 and to the lower plate 152 so as to be rotatably connected to the lower plate 152. It includes an upper plate 153 for pressurizing the supplied raw material. When the raw material is supplied to the lower plate 152, the upper plate 153 rotates relative to the lower plate 152 to press and compress the raw material supplied to the lower plate 152.

In addition, a conveyor capable of continuously moving the molding plate 151 may be used as the molding plate moving unit 154, but the scope of the present invention is not limited thereto, and a plurality of molding plates 151 are supplied as a raw material supply unit. Anything that can intersect and move continuously with respect to (110) can be used. The plurality of molding plates 151 may be circularly moved by the molding plate moving unit 154, and during the circular movement, the lower plate 152 and the upper plate 153 are heated by a heating means (not shown), and the lower plate 152 ) and the moisture contained in the raw material pressurized and compressed by the upper plate 153 is evaporated to form scorched rice. On the other hand, by controlling the moving speed and heating temperature of the forming plate 151, it is possible to adjust the heating time and the like in forming scorched rice.

On the other hand, the scorched rice manufacturing apparatus 100 according to the present embodiment includes a remover (not shown) for removing scorched rice or debris attached or stuck to the lower plate 152 and the upper plate 153, and the completed scorched paper is recovered and dried. It may further include a drying belt (not shown) to allow drying, and a rotating brush (not shown) to remove debris or foreign substances remaining on the lower plate 152 from which the fried rice has been removed.

In supplying raw materials to the molding unit 150, the moving unit 160 according to the present embodiment synchronizes the moving speed of the molding plate 151 and the moving speed of the raw material supply unit 110 so that the molding plate 151 moves. It serves to supply raw materials to the lower plate 152 of the molding plate 151 while being formed.

The moving unit 160 is connected to the raw material supply unit 110, and the lower plate 152 is disposed below the raw material discharge port 132 so as to supply the raw material to the lower plate 152 while the lower plate 152 is moved. While moving the raw material supply unit 110 at the same speed as the moving speed of the lower plate 152 along the moving direction of ), the raw material is supplied to the lower plate 152. Then, the moving unit 160 returns the raw material supply unit 110 to supply the raw material to the next lower plate 152 after supplying the raw material to the corresponding lower plate 152 .

By repeatedly moving the raw material supply unit 110 back and forth using the moving unit 160, the raw material can be automatically supplied to the plurality of lower plates 152 in sequence, thereby reducing the number of workers and preventing the worker from being exposed to heat. can be minimized.

Specifically, the moving unit 160 is connected to the lower part of the raw material supply unit 110, the base plate 161 supporting the raw material supply unit 110, and the lower plate 152 below the base plate 161 in the moving direction A plurality of first LM guide rails 162 disposed along, one side connected to the base plate 161 and the other side connected to the plurality of first LM guide rails 162 to make the base plate 161 a plurality of It includes a first LM drive unit 163 that enables reciprocating motion along one LM guide rail 162.

In addition, the first LM drive unit 163 includes a plurality of first LM blocks 164 having one side coupled to the base plate 161 and the other side coupled to the first LM guide rail 162, and a lower portion of the base plate 161 It includes at least one first ball screw (not shown) coupled to, and a first drive motor (not shown) connected to the first ball screw to rotate the first ball screw.

Looking at the operation of supplying the raw material to the lower plate 152, as shown in FIG. 3, when the raw material outlet 132 is opened by moving the cutting plate 142 backward, the raw material is extruded and transported by the extrusion transfer unit 130 to the raw material outlet It is discharged at 132. At this time, since the plurality of molding plates 151 are continuously moved to the right by the molding plate moving unit 154, the raw material is supplied to the lower plate 152 through the raw material outlet 132 as shown in FIG. The base plate 161 is moved to the first LM guide rail 162 by rotating the first ball screw by controlling the drive motor at the same speed as the moving speed of the lower plate 152 so that the lower plate 152 is positioned under the discharge port 132. ) to the right along the lines.

And, as shown in FIG. 4, when a quantity of raw material is discharged through the raw material outlet 132, the cutting plate 142 is moved forward to cut the raw material continuously discharged from the raw material outlet 132 to cut the raw material lump. It is dropped to the lower plate 152 of the temporary molding plate 151. When the raw material discharged from the raw material outlet 132 is cut, as shown in FIG. 7 , the base plate 161 is rotated by controlling the driving motor to supply the raw material to the next lower plate 152 by rotating the first ball screw. By moving the first LM guide rails 162 in the left direction, the raw material outlet 132 is located on the upper part of the next lower plate 152.

Meanwhile, the alignment unit 170 according to the present embodiment is provided between the raw material supply unit 110 and the moving unit 160 and molds the raw material supply unit 110 so that the raw material discharge port 132 is positioned above the lower plate 152. It serves to move in the direction of the plate 151. That is, the alignment unit 170 aligns the raw material outlet 132 and the lower plate 152 with each other before performing an operation of supplying the raw material to the lower plate 152 through the raw material outlet 132 .

As shown in FIG. 1 , the alignment unit 170 moves the raw material supply unit 110 forward and backward in a direction approaching the molding plate 151 or in a direction away from the molding plate 151 .

Specifically, the alignment unit 170 includes a plurality of second LM guide rails 171 disposed in a direction crossing the first LM guide rail 162 on the top of the base plate 161, and one side of the raw material supply unit 110 ) and the other side is connected to the plurality of second LM guide rails 171 to enable the raw material supply unit 110 to reciprocate along the plurality of second LM guide rails 171 2 LM drive unit 172 includes

And the second LM drive unit 172 includes a plurality of second LM blocks 173 having one side connected to the lower part of the raw material supply unit 110 and the other side connected to the second LM guide rail 171, and the raw material supply unit 110 ) may include at least one second ball screw (not shown) coupled to a lower portion of the second ball screw, and a second drive motor (not shown) connected to the second ball screw to rotate the second ball screw.

On the other hand, when the operator manually positions the raw material outlet 132 on the upper part of the lower plate 152, the second ball screw and the second driving motor may be omitted.

As described above, the alignment unit 170 aligns the positions of the raw material outlet 132 and the lower plate 152 before performing an operation of supplying raw materials to the lower plate 152 through the raw material outlet 132. However, while supplying the raw material to the lower plate 152, it is possible to detect whether the position of the raw material outlet 132 and the lower plate 152 coincide with each other so that the raw material outlet 132 and the lower plate 152 are connected.

Meanwhile, operations of the raw material supply unit 110, the molding unit 150, the moving unit 160, and the alignment unit 170 according to the present embodiment may be controlled by a control unit (not shown). The control unit is electrically connected to control the raw material supply unit 110, the molding unit 150, the moving unit 160, and the alignment unit 170.

For example, the stirring speed of the agitator 122, the rotation speed of the transfer screw 134, the amount and cycle of water supplied from the first water supply hose 136 and the second water supply hose 144, the cutting plate The operation of moving the raw material supply unit 110 at the same speed as the moving speed of the actuator 143 for moving the 142 forward and backward, and the lower plate 152, etc. can be controlled through operation switches provided in a separate control unit. .

As such, 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, it should be said that such modifications or variations fall within the scope of the claims of the present invention.

100: scorched rice manufacturing device 110: raw material supply unit
120: stirring unit 130: extrusion transfer unit
140: discharge amount control unit 150: molding unit
160: movement unit 170: alignment unit

Claims (10)

A raw material supply unit that receives raw materials for scorched rice, stirs them, extrudes and transfers the stirred raw materials, and supplies them through a raw material discharge port;
A plurality of molded nurungji having a lower plate disposed below the raw material outlet and receiving the raw material discharged from the raw material outlet and an upper plate rotatably connected to the lower plate and pressurizing the raw material supplied to the lower plate. a forming unit having a forming plate and a forming plate moving unit connected to the plurality of forming plates and continuously moving the plurality of forming plates crossing the raw material supply unit; and
Connected to the raw material supply unit, the raw material is connected to the lower plate at the same speed as the moving speed of the lower plate along the moving direction of the lower plate so that the lower plate is disposed below the raw material outlet so as to supply the raw material to the lower plate while the lower plate is moved. A nurungji manufacturing apparatus comprising a moving unit that moves the supply unit to supply raw materials to the lower plate and then returns the raw material supply unit to supply raw materials to the lower plate in the next order. According to claim 1,
The mobile unit,
a base plate connected to a lower portion of the raw material supply unit to support the raw material supply unit;
A plurality of first LM guide rails disposed under the base plate along the moving direction of the lower plate; and
A first LM driving unit having one side connected to the base plate and the other side connected to a plurality of the first LM guide rails to enable the base plate to reciprocate along the plurality of first LM guide rails. . According to claim 2,
The first LM drive unit,
a plurality of first LM blocks having one side coupled to the base plate and the other side coupled to the first LM guide rail;
at least one ball screw coupled to a lower portion of the base plate; and
Nurungji manufacturing apparatus including a driving motor connected to the ball screw to rotate the ball screw. According to claim 2,
Further comprising an alignment unit provided between the raw material supply unit and the moving unit to align the raw material outlet so that the raw material outlet is located on the upper part of the lower plate,
The sorting unit is
a plurality of second LM guide rails disposed on the base plate in a direction crossing the first LM guide rail; and
A second LM drive unit having one side connected to the raw material supply unit and the other side connected to a plurality of second LM guide rails to enable the raw material supply unit to reciprocate along the plurality of second LM guide rails. manufacturing device. According to claim 1,
The raw material supply unit,
An agitator for receiving and agitating the raw material; and
Nurungji manufacturing apparatus comprising an extrusion conveying part formed with the raw material discharge port for extruding and conveying the raw material supplied from the stirring part and discharging the raw material at an end. According to claim 5,
The stirring part,
a hopper into which the raw material is put; and
A scorched rice manufacturing apparatus comprising a stirrer disposed at the bottom of the hopper and stirring the raw material to supply it to the extrusion transfer unit. According to claim 6,
The agitator,
a body into which the raw material flows from the hopper;
A plurality of stirring blades disposed inside the body, one side of which is coupled to a rotation shaft passing through the body, the other side extending in a radial direction of the rotation shaft, and formed in a “T” shape with an end parallel to the rotation shaft; and
A nurungji manufacturing apparatus including a first rotation motor disposed outside the body and connected to the rotation shaft to rotate the plurality of stirring blades. According to claim 7,
The extrusion transfer unit,
a cylinder in which the raw material stirred by the agitator is introduced and the raw material inlet is formed at an end;
a conveying screw provided inside the cylinder and extruding and transporting the raw material in the direction of the raw material discharge port as it rotates; and
A nurungji manufacturing apparatus including a second rotation motor disposed outside the cylinder and connected to the transfer screw to rotate the transfer screw. According to claim 8,
The raw material supply unit,
Doedoe provided in the cylinder, further comprising a discharge amount control unit for adjusting the discharge amount of the raw material discharged from the raw material discharge port to the lower plate,
The discharge amount control unit,
Doedoe coupled to the cylinder, the coupling block disposed in the lower portion of the raw material outlet;
a cutting plate provided inside the coupling block and disposed below the raw material outlet, opening and closing the raw material outlet as it reciprocates, and cutting the raw material discharged from the raw material outlet; and
A nurungji manufacturing apparatus comprising an actuator coupled to the coupling block and connected to the cutting plate to enable reciprocating movement of the cutting plate. According to claim 9,
The discharge amount control unit,
A water supply hose coupled to the coupling block and supplying water to the upper surface of the cutting plate to prevent the raw material from adhering to the upper surface of the cutting plate.

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