KR20200045127A - Apparatus for cutting daikon preferably into cubic shape - Google Patents

Abstract

The present invention relates to an apparatus for processing radish for cubed radish kimchi to significantly reduce the number of defective parts. According to the present invention, the apparatus comprises: a housing (400) installing or embedding a driving means, such as a motor and the like, an electric/electronic component, and various mechanical elements, therein; a control unit (300) disposed on the upper part side of the housing (400); a slicing unit (100) and cube cutting unit (200) disposed on the lower side of the control unit (300) in upper and lower two stages; and a cutting unit (500) disposed on the front side of the housing (400) to simultaneously communicate with the front end sides of the slicing unit (100) and the cube cutting unit (200), having an assembly of a rotary blade of the slicing unit (100) and a fixed blade of the cube cutting unit (200) installed therein, and having a transfer path formed therein to allow the front end part of the slicing unit (100) to communicate with the front end part of the cube cutting unit (200).

Description

{Apparatus for cutting daikon preferably into cubic shape}

The present invention relates to a radish processing device for dipping, more specifically, the amount of defective products (pachi) generated when processing (cutting) radish to make dip can be significantly reduced, and cuts in the height direction of the processing device It is possible to install even if the area of the work shop or store is narrow because the total length of the cutting device is shortened because the slicing part and the slicing part are arranged in two stages up and down, and the cutting load applied to the cutting blade and the cutting blade is reduced. The durability of the processing device can be improved, and the like. The present invention relates to a non-processing device for cutting pods having various advantages compared to a conventional cutting device.

A number of patent documents exist as prior arts that are the background of the present invention, and some of them are as follows.

As a first example, in Patent Document 1, the driver for transmitting power, the rotating bar formed by a screw thread on the outer circumferential surface by the driver, and coupled to the outer circumferential surface of the rotating bar while pressing the vegetable for dipping while ascending according to the rotation of the rotating bar And a vertical cutter for vertically cutting the vegetable for dipping, which is arranged on the lower side of the pressing portion, and which is installed to be replaceable at the lower portion of the inlet and is composed of a plurality of grids to be pressed under the pressing portion. , It is disposed on the lower side of the vertical cutter and has a reciprocating motion within a certain angle interlocking with the actuator, and a vegetable cutting device for cutting the vegetable is provided with a horizontal cutter for cutting vegetables vertically cut by the vertical cutter horizontally.

According to the description of Patent Document 1, by such a configuration, it is possible to produce a large amount of dices having a constant length and size in a short time, and also, there are several different grid shapes (square, triangle, hexagon, circle, snowman shape, etc.). It is supposed to obtain the effect of easily making various types of dices by preparing a kind of vertical cutter in advance and replacing it with an appropriate grid-shaped vertical cutter if necessary.

As a second example, in Patent Document 2, the upper portion is opened, and a receiving chamber capable of injecting radish from above, a pressing device for pressing radish from the rear of the receiving chamber, a horizontal frame formed in front of the receiving chamber and vertically installed, Disclosed is a root vegetable cutting device comprising a cutting device installed on a side of a front side of a horizontal blade and having a rotating cutting blade and a tray installed under the cutting device.

Among these components, the horizontal blade has a plurality of horizontal blades and vertical blades, and a horizontal fixed groove and a vertical fixed groove are formed on the rim of the horizontal blade more than the number of horizontal blades and vertical blades. In addition, the pressing device is composed of a pressing plate vertically installed to press the rear of the radish, and a pressing rod installed behind the pressing plate. The cutting device consists of a rotating shaft rotated by a motor, a rotating plate installed on the rotating shaft, and a cutting blade that is fixed to the rotating plate by a fixture and bent in an arc shape.

In addition, a side cover is installed on the side of the transverse frame to prevent the dip from splashing outward, and a door that pivots around the hinge is installed on the side of the cutting device. It is configured such that the cross-sectional shape can be a square, a heart shape, a star shape, and the like.

According to the root vegetable cutting device of patent document 2, it is possible to mass-produce a large amount of cuts, etc. in a short period of time, and it is easy to maintain because the main parts are arranged on the front part of the device, and the safety of the operator by the door provided in the cutting device It is said that protection of facilities and facilities can be guaranteed.

As a third example, in Patent Document 3, the pressing rod equipped with the pressing rod on the front side is moved forward and backward with a straw rod connected to the chain, and at the same time, the forward and backward speed of the straw rod can be adjusted in two stages by a clutch. , As the rotating cutter rotates as a speed control motor, it can be adjusted in various lengths depending on the application, such as from thinly sliced vegetables, cut vegetables, and long cut vegetables, due to the adjustment of the forward speed of the pressurizing table and the rotational speed of the rotating cutter. It can be selected and cut, and the vegetable guide can be easily cleaned for hygienic management, and a predetermined space is formed at the tip of the M-shaped seating table, so that it can be opened and closed with a separate configured slide cover. It is very convenient to use, such as being able to stably disassemble and assemble, as well as to cut diced vegetables into various thicknesses. A horizontally pressurized vegetable cutting device is disclosed.

Patent Literature 1: Published Patent Publication No. 10-2009-0071819 Patent Document 2: Published Patent Publication No. 10-2013-0040113 Patent Document 3: Registered Patent Publication No. 10-1768408

However, since the vegetable cutting device for diced vegetables disclosed in Patent Literature 1 is processed by putting radish in an inlet that stands vertically, if the radish is so thick that it cannot be placed in the inlet, trimming the radish with a knife (for example, hitting a side of the radish with a knife) Should be done further. This makes the worker troublesome and increases the amount of trash treated as garbage. On the contrary, if the radish is thin, the radish is biased to one side or tilted at an angle within the inlet, so that the pusher does not pressurize the radish evenly, so there is a lot of patch with a shape that is distorted or a thick turn on the radish shell. There is this.

In addition, the vegetable cutting device for dipping according to Patent Document 1 is a configuration in which a plurality of knives are diced by a vertical cutter arranged in a lattice shape, and then cut into pieces by a transverse cutter. Until the entire length passes completely between the lattices of the vertical cutter, there is a disadvantage in that the durability of the cutting device is significantly reduced, such as damage or deformation of the vertical cutter due to a very large cutting load applied to all knives that are in contact.

Next, in the root vegetable cutting apparatus disclosed in Patent Document 2, after feeding raw radish (for example, radish with both ends cut flat) into a storage chamber in which a horizontal blade is arranged on the front side and a pressure plate is installed on the back side, the platen is forwardly transferred. By making it, the raw radish is cut into thin and long pieces while passing through the transverse frame, followed by the cutting of the long and long radish chips into fine slices by cutting blades arranged on the outside front of the transverse frame.

However, according to such a configuration, since the cutting device provided with the cutting edge for cutting the dices and the cutting edge for cutting into pieces is arranged in a straight line, the overall length of the root vegetable cutting device is lengthened, which is difficult to install in a store with a small area. have.

In addition, as in Patent Document 1, the durability of the device is such that the transverse frame is damaged or deformed by applying a large cutting load to all blades that the radish comes into contact with, until the entire length of the solid radish completely passes between the lattices of the transverse frame. There is a downside to this decline. In addition, since the end of the elongated radish stub is not fixed when the stub that has passed out of the transverse frame is cut into pieces by the cutting blade, the part to which the rotational force (cutting force) of the cutting blade is applied sags downward. It has the disadvantage that it is difficult to cut into a straight shape because the chips are rattled. This is a factor that increases the amount of parch.

Lastly, the horizontal press-type vegetable cutting device for dicing disclosed in Patent Document 3 has the same disadvantages as in Patent Document 2 because it is configured with the same principle as the root vegetable cutting device of Patent Document 2.

Therefore, the present invention was devised to solve the problems common to the cutting device of the conventional configuration, and the amount of the generated parch when processing radish can be significantly reduced, and as the overall length of the device is greatly reduced, Even if the area is small, it can be installed, and by cutting into small pieces after cutting into pieces, it is possible to greatly reduce the cutting load applied to the blade and improve the durability of the device. An object of the present invention is to provide a novel configuration of a cutting machine for dipping, which can exhibit excellent advantages in many respects compared to a device.

As a solution to the above problems, the radish processing device for dipping according to the present invention adopts the following configuration.

[1] A radish processing device for cutting radish by cutting raw radish, a housing in which driving means, electric and electronic elements and mechanical elements are installed, a control unit disposed on the upper side of the housing, and controlled by the control unit It is placed in front of the housing so that the slicing unit and the slicing unit, which are installed in two steps up and down, and the front end side of the slicing unit and the front end side of the slicing unit are simultaneously communicated, and the rotating blade and the fixed blade of the slicing unit An assembly is mounted, and the cutting unit for cutting the dices is characterized in that it comprises a cutting portion formed with a moving path connecting the front end of the dice and the dice.

[2] In the above [1], the slicing unit is disposed above the slicing unit.

[3] In the above [1] or [2], the slicing unit includes a trough made of a part of the housing, a transport unit that is movably installed in the trough in the front-rear direction, and transports raw radish to the front side, and is rotatable in the cutting unit The rotation blade cuts a certain thickness of non-stick every time one rotation, and the shear of the raw radish is fixed at the time of cutting the first non-stick and the shear of the rest of the raw radish remaining in the trough after the second It is fixed, and after the cutting of the current stub is completed, it comprises a shear fixing unit for releasing the fastening of the current stub.

[4] In the above [1] to [3], the slicing portion, the fixed blade assembly is formed by pressing a large amount of raw earthenware into a fixed blade assembly and a large number of raw earthenware is made, and the pressing force forcibly passing through the earthenware side toward the fixed blade assembly A non-processing device for dipping, comprising a unit.

[5] In the above [1] to [4], the cutting part includes a back plate fixed to the housing, a front plate disposed in front of the back plate, and a hinge installed on one side of the front plate and the back plate. , A fastener installed on the other side of the front plate and the back plate, and a moving path concavely formed at a certain depth on the rear side of the front plate, and the lower portion of the moving path that is supported by contact with no soil is an arc surface A radish processing device for dipping, characterized in that consisting of.

[6] In the above [5], the moving furnace is a non-processing device for dipping, characterized in that in the form of a vertical channel or an inclined channel.

[7] In the above [3] to [6], the transfer unit includes a motor disposed in a lower section of the housing, a screw shaft installed in the front and rear directions in a lower section of the housing, and a power connecting the motor to the screw shaft. As a transmission mechanism, a timing mechanism composed of a timing belt and a pair of pulleys, a conveying block assembly through which a screw shaft passes, a spike mechanism coupled to an upper side of the conveying block assembly so as to be located on the trough, and a part to enable seesaw movement The lever fixed to the transport block assembly and the semi-circular ring portion are engaged to the screw portion of the screw shaft when the user does not press and the semi-circular ring portion is detached from the screw portion of the screw shaft when the user presses it. Between the combined slider, the spring connected at both ends to the slide and the conveying block assembly, and the screw shaft. With respectively through the right and left sides of the transport block assembly dices non-processing apparatus which is characterized by being a slide rod which is installed in the front-rear direction.

[8] In the above [3] to [7], the front end fixing unit is disposed on the rear side of the front plate and has a plurality of pin holes drilled in contact with the contact plate, and the front side of the front plate to be in a corresponding position with the contact plate. It is disposed on the spike plate is provided with a plurality of pins that can be exposed through the pin hole of the contact plate, and two solenoids for bringing the spike plate into close contact with or away from the front plate, and interposed between the front plate and the contact plate A non-processing device for dipping, characterized in that it consists of a spring.

[9] In the above [1] to [8], the fixed blade assembly is a structure in which a plurality of vertical blades and a plurality of horizontal blades are assembled in a lattice form, and the slab partially passes through the vertical blades first, followed by the horizontal blades. To pass through, the end of the blade of the vertical blade and the edge of the horizontal blade are machined for dipping.

[10] In the above [4] to [9], the pressurizing unit is a pressurizing block that pushes the dust-free membrane toward the fixed blade assembly, and the rotational motion of the motor is converted into a linear motion of the link rod to reciprocate the pressurizing block forward and backward. One end of the link rod is made of a link mechanism coupled to the pressing block, characterized in that the cutting machine for dipping.

[11] In the above [1] to [10], a non-processing device for dipping, characterized in that an ejector bar is provided in an integral form with a rotating blade or overlapping with a rotating blade.

According to the present invention, when the raw radish is introduced and processed into raw kkakdu, the amount of parch generated can be significantly reduced, and the overall length of the device is shortened so that it can be installed even if the area of the workshop or store is narrow. By performing the cutting force applied to the horizontal and vertical blades of the fixed blade assembly is reduced, the durability of the device can be improved.

1 is a three-dimensional view schematically showing the overall appearance of a radish processing apparatus for dipping according to an embodiment of the present invention, when the direction in which the radish is transferred is a front-rear direction, FIG. 1 (a) is a three-dimensional view from the front side Fig. 1 (b) is a three-dimensional view as viewed from the rear side.
FIG. 2 is a front view of the radish processing device for dipping shown in FIG. 1, and is a front view showing the front portion of the housing partially removed so that the main components of the digging portion and the dicing portion can be seen.
FIG. 3 is a plan view of the radish processing device for dipping illustrated in FIG. 1, and is a plan view partially removed by removing a top plate of a control unit disposed on an upper side of the housing.
4 is a cross-sectional view taken along line Ⅰ-Ⅰ of FIG. 3, and is a cross-sectional view of the radish processing device for cutting.
5 is a three-dimensional view as viewed from the front side of the main configuration of the radish cutting machine shown in FIG. 1, and is a three-dimensional view showing the detailed structure of the slicing unit and the slicing unit.
FIG. 6 is a corresponding view of FIG. 5 omitting a part of the housing in which the control unit is disposed, and is a three-dimensional view of the main configuration of the no-cutting machine for dipping.
7 is a view showing in more detail the configuration of the dice cut according to an embodiment of the present invention, Figure 7 (a) is a three-dimensional view from the front side with a cutting portion, Figure 7 (b) is a cutting portion It is a three-dimensional view as viewed from the rear side in an omitted state.
8 is a picture for explaining the principle that the conveying unit of the slicing unit according to an embodiment of the present invention is automatically transported in the front-rear direction, a picture taken near the screw shaft disposed below the trough.
9 is a three-dimensional view showing in more detail the spike mechanism of the transport unit according to an embodiment of the present invention.
10A is a cross-sectional view showing the internal structure of the spike mechanism shown in FIG. 9.
10B is a cross-sectional view taken along the line ⅠⅠ-ⅠⅠ in FIG. 9.
11 is a three-dimensional view showing a schematic structure of a rotating blade assembly according to an embodiment of the present invention.
12 is a three-dimensional view showing a state in which the front end fixing unit of the slicing unit according to an embodiment of the present invention is installed on the outer surface side of the front plate of the cutting unit.
13 is a three-dimensional view showing the detailed configuration of the front end fixing unit shown in FIG. 12, FIG. 13 (a) is a three-dimensional view viewed from the front side, and FIG. 13 (b) is a three-dimensional view viewed from the rear side.
14 is a cross-sectional view of the front end fixing unit taken along the line ⅠIⅠ-ⅠⅠⅠ of FIG. 13 (a).
15 is a photograph of the right side of the cut portion according to an embodiment of the present invention.
16 is a photograph of an upper portion of the front side of the rear plate of the cut portion according to an embodiment.
17 is a photograph of the rear side of the front plate of the cut portion according to an embodiment.
18 is a schematic diagram showing a state in which the remaining portion of the raw radish remaining in the trough descends and contacts the inner surface of the trough during the slicing process.
19 is a view schematically showing a three-step process in which raw radish is processed into raw kkakdugi by the radish processing device for kkakdugi according to the present invention.

Various advantages and features of the radish processing machine for dipping according to the present invention, and a configuration of an apparatus that can achieve this, will be clarified through the description of the embodiments described below together with the accompanying drawings.

However, the present invention is not limited to the embodiments disclosed below, but may be implemented in various different forms.

In other words, the embodiments described below are provided only to sufficiently inform the scope of the present invention to those skilled in the art to which the present invention pertains, and the technical spirit of the present invention is defined by the description of claims.

In addition, the technical terminology used in this specification is for facilitating the description of the embodiments, and the present invention is not limited by the technical terminology. In one example, a singular form includes a plural form unless otherwise specified. Among the terms used herein, “comprises” and / or “comprising” does not exclude the presence or addition of one or more other components other than the components mentioned.

Also, throughout the specification, the same reference numerals refer to the same components, and “and / or” includes each and every combination of one or more of the components mentioned.

Unless otherwise defined, terms used in this specification are used in a sense commonly understood by those skilled in the art to which the present invention pertains.

The terms "below", "bottom", "upper", etc., referring to relative positions in space, are used to describe the positional relationship between one component and another component shown in the drawings. In addition to the directions shown in, in use or operation, it should be understood as terms including different directions. As an example, when a component shown in the drawing is turned over, a component described as “below” another component is placed “above” another component. Thus, the exemplary term "below" may include both the direction of the top and bottom.

In addition, since each component of the non-processing device for dipping according to the present invention can be oriented in a direction different from the direction shown in the drawings, the term indicating the relative position in space should be interpreted differently depending on the orientation.

Hereinafter, the configuration, action, and effects of the radish processing apparatus for dipping according to an embodiment of the present invention will be described in detail based on the accompanying drawings.

Example

First, with reference to FIG. 1, the overall appearance of a radish processing apparatus for dipping according to an embodiment of the present invention (hereinafter simply referred to as a “no processing apparatus”) will be schematically described.

In addition, in the following description, the terms raw material radish (A), raw radish (B), and raw radish (C) shown in FIG. 19 will be frequently used.

When the direction in which the raw material radish (A) is conveyed is referred to as a front-rear direction, FIG. 1 (a) is a three-dimensional view of the radish processing apparatus as viewed from the front side, and FIG. 1 (b) is a three-dimensional view of the radish processing apparatus as viewed from the rear side. to be.

As shown in FIG. 1, the machining-free device of the present embodiment includes a housing 400 in which a driving means such as a motor, electric and electronic elements, and various mechanical elements are installed or embedded; A control unit 300 disposed on an upper side of the housing 400; A slicing unit 100 and a slicing unit 200 disposed in two stages up and down under the control unit 300; It is disposed in front of the housing 400 so as to be simultaneously communicated to the front end side of the slicing unit 100 and the slicing unit 200, and the rotating blades of the slicing unit 100 and the fixed blades of the slicing unit 200 The assembly is mounted, and consists of a configuration including a cutting portion 500 having a moving path communicating the front end portion of the chip-cutting portion 100 and the front-end portion of the dicing portion 200.

Next, the main configuration of the no-machining apparatus shown in FIG. 1 will be described in more detail.

Among the attached drawings, FIG. 2 is a front view showing the front surface of the housing 400 by removing the front plate of the housing 400 so that the main slicing part 100 and the slicing part 200, which are the main components of the non-processing device, can be easily seen. 400) is a plan view showing the top plate of the control unit 300 disposed on the upper side, and FIG. 4 is a cross-sectional view taken along the line I-I of FIG. 3 and viewed from the front side.

First, among the main components, the slicing unit 100 that sequentially cuts the raw material radish (A) of a certain length from the raw radish (B) of a certain thickness with a time difference, the trough (part of the housing 400) The trough, 110, and the transport unit 120 which is movably installed in the trough 110 in the front-rear direction and transfers the raw material A introduced into the trough 110 to the front side, and the cutting unit 500 Rotating blade 131 which is arranged to be rotated within and cuts the non-stick film B of a certain thickness every revolution, and the front end of the non-stick film B until the cutting of the non-stick film B is completed. And after the cut of the earthenware (B) is completed, it consists of a configuration including a front end fixing unit 140 for releasing the anchorage of the earthenware (B).

The slicing unit 200, which is installed below the slicing unit 100 and processes (cuts) one radish (B) into raw kkakdu (C), presses through the swarf (B) and passes a large number of Consists of a configuration including a fixed blade assembly 210 in which the raw kkakdugi C is made, and a pressing unit 220 for forcibly passing the non-stick membrane B toward the fixed blade assembly 210.

The control unit 300 is an operation to control the driving of the power on / off switch for power supply and interruption to the electric and electronic elements installed in the housing 400, and the driving of the slicing unit 100 and the slicing unit 200 It consists of a button and an emergency stop button and a status indicator that notifies the user when an abnormality occurs in the electrical and electronic elements. The electric and electronic elements constituting the control unit 300 are connected to a substrate equipped with a control circuit, for example.

The housing 400 is divided into an upper section in which a part of the cutting unit 100 and a control unit 300 are disposed, and a lower section in which the remaining components of the cutting unit 100 and the dicing unit 200 are disposed. The upper section has a smaller dimension in the left-right direction of the non-processing device than the lower section. In the right region of the upper plate dividing the lower section, a V-shaped, U-shaped, or semi-circular trough 110 is formed to have a length almost equal to the total length in the front-rear direction of the non-machined apparatus. In addition, a leveler 410 is installed on the edge side of the lower section, and a vibration damping function may be provided to the leveler as necessary.

The front end portion of the slicing unit 100 and the front end portion of the slicing unit 200 are disposed at the front of the housing 400 so as to communicate at the same time, one side side is pivotable around the hinge 530 It is provided with a front plate 510 and a back plate 520 fixed to the housing 400, and at the rear of the front plate 510, the front end portion of the slicing unit 100 and the front end portion of the slicing unit 200 are up and down. A moving path communicating with the furnace is formed. The detailed configuration of the cutting part 500 will be described later.

Among the attached drawings, FIG. 5 is a three-dimensional view of the detailed configuration of the slicing unit 100, the dice cutting unit 200, and the cutting unit 500 from the front side, and FIG. 6 is a housing in which the control unit 300 is installed ( It is a corresponding view of FIG. 5 omitting the upper section of 300) and is a three-dimensional view viewed from the rear side.

As more clearly understood through FIGS. 5 and 6, the slicing unit 100 according to the present embodiment includes a trough 110 and a trough formed as a part of an upper plate partitioning a lower section of the housing 400. Transport unit 120 for conveying the raw material radish (A) introduced in 110 to the front side, and a motor 132 for driving the rotary blade 131 and the rotary blade 131 rotatably disposed in the cutting unit 500 It is composed of a rotating blade assembly 130 composed of, and a front end fixing unit 140 for fixing and releasing the front end of the earthen membrane (B).

The detailed configuration of the conveying unit 120, the rotating blade assembly 130, and the front end fixing unit 140 will be described later.

The dice dicing unit 200 of the present embodiment, which is disposed below the slicing unit 100, includes a plurality of horizontal blades 211 so that the same eye shape as the cross-sectional shape of the fresh dip can be formed. The vertical blade 212 is composed of a fixed blade assembly 210 of the assembled configuration, and a pressing unit 220 for forcibly passing through the non-stick film B toward the fixed blade assembly 210.

The fixed blade assembly 210 is mounted on the outer surface of the front plate 510 of the cutting part 500 in which the discharge hole is formed on the lower side.

The pressing unit 220, the pressing block 221 to push the non-stick film (B) toward the fixed blade assembly 210, and the rotational movement of the motor 222 is converted into a linear movement of the link rod to press the pressing block 221 One end of the link rod is configured with a link mechanism 223 coupled to the pressing block 221 to reciprocate in the front-rear direction.

In this embodiment, the link mechanism 223 is composed of two link rods and a coupling port connecting between the two link rods, and among these link rods, the front end of the front link rod is of the pressing block 221. It is connected to the rear side, and the rear end of the rear side link rod is connected to the eccentric member 224 coupled to the rotating shaft of the motor 222. However, a structure other than this structure, for example, the eccentric member 223 and the pressing block 221 may be connected by only one link rod, or may be configured by connecting three or more link rods.

7 is a view showing the configuration of the dice cut 200 in more detail, FIG. 7 (a) is a three-dimensional view seen from the front side with the cutting unit 500 installed, and FIG. 7 (b) is the cutting unit 500 ) Is a three-dimensional view seen from the rear side with omission.

An installation hole 540 for mounting the rotating blade assembly 130 is formed in the center of the upper region of the cutting part 500, and a connection hole 550 communicating with the front end part of the slicing part 100 is formed in the vicinity thereof. ) Is formed, and a discharge hole communicating with the front end portion of the dice 200 is formed in the lower region of the cutting portion 500 so as to be positioned below the connection hole 550.

The fixed blade assembly 210 is a structure in which a plurality of vertical blades 212 and a plurality of horizontal blades 211 are assembled in a lattice form, and the non-stick (B) partially passes through the vertical blades 212 first, and then horizontally. To pass the blade 211, the blade edge of the vertical blade 212 and the blade edge of the horizontal blade 211 are shifted. For example, when the vertical blade 212 and the horizontal blade 211 are of the same standard, the edge of the horizontal blade 211 is positioned a few millimeters to several centimeters more forward than the edge of the vertical blade 212.

The front end portion of the cylindrical pressure block 221 constituting the pressing unit 220 is the same as the vertical blade 212 and the horizontal blade 211, the vertical blade groove 221A and the horizontal blade groove (221B) is formed. These grooves 221A and 221B are formed to a depth that does not interfere with the vertical blade 212 and the horizontal blade 211.

The configuration of the link mechanism 223 which pushes the pressing block 221 toward the fixed blade assembly 210 is as follows.

As shown in FIG. 7, the rear end of the pressing block 221 is fixed with a bolt at the front end of the coupling block 228, and one end of the link rod 226B is connected to the rear end of the coupling block 228. have. Further, the other end of the link rod 226B is connected to the eccentric shaft portion of the motor 225. The motor 225 is installed on the slide block 227 that reciprocates in the front-rear direction along the guide rod 229. One end of the other link rod 226A is connected to the slide block 227, and the other end of the link rod 226A is connected to the eccentric member 224 installed on the other motor 222 side.

8 is a picture for explaining the operating principle in which the conveying unit 120 of the slicing unit 100 according to an embodiment of the present invention is automatically transported in the front-rear direction, a screw shaft disposed under the trough 110 It is a picture taken in the vicinity of.

6 and 8, the conveying unit 120 of one embodiment is installed in the front-rear direction in the lower section of the housing 400 and the motor 121 disposed in the lower section of the housing 400. As a power transmission mechanism connecting the screw shaft 122, the motor 121 and the screw shaft 122, a timing mechanism composed of a timing belt and a pair of pulleys, and a conveying block assembly through which the screw shaft 122 passes (123), and the spike mechanism 124 coupled to the upper one side of the transport block assembly 123 so as to be located on the trough 110 side, and a lever partially fixed to the transport block assembly 123 to enable seesaw movement ( 125), and when the user does not press the semi-circular ring portion is coupled to the screw portion of the screw shaft 122, and when the user presses the semi-circular ring portion of the screw shaft 122 so as to be separated from the screw portion of the lever 125 Sly coupled to one end (126), the slide 126 and the spring 127, both ends of which are respectively connected to the transport block assembly 123, and the screw shaft 122 are interposed between the left and right sides of the transport block assembly 123, respectively. It consists of slide rods installed in the front-rear direction.

9 is a three-dimensional view showing the configuration of the spike mechanism 124 according to an embodiment in more detail, a spike plate 128A provided with a plurality of pins, and a handle coupled to the rear side of the spike plate 128A ( 128B), and a fixed block 129A through which a portion of the handle 128B is penetrated so as to be moved in the front-rear direction and the rod protrudes on both sides, and the fixed block 129A is fixed to be moved in the vertical direction It consists of a support block 129B through which both sides of the block 129A are penetrated, and the support block 129B is fixed to one side of the transport block assembly 123.

10A is a cross-sectional view showing the internal structure of the spike mechanism 124 shown in FIG. 9, depending on whether the handle 128B is operated, the latch portions are fixed or released from each other, so that the spike plate 128A is moved forward and backward. It can be moved slightly.

10B is a cross-sectional view taken along the line ⅠⅠ-ⅠⅠ in FIG. 9, since the transport block assembly 123 has a configuration in which a spring 123A is disposed between the front block and the rear block, when cutting into pieces, the rotating blade 131 Within the blade thickness range, the front end block is movable in the front-rear direction within a predetermined range with respect to the rear end block. According to this configuration, the spike mechanism 124 mounted on the left side of the front end block of the conveying block assembly 123 has a length of spring corresponding to half the thickness of the rotating blade 131 when cutting the raw material A. Since it is retracted while compressing (123A), the cutting resistance received by the rotating blade 131 is reduced.

11 is a three-dimensional view showing the structure of a rotating blade assembly 130 according to an embodiment of the present invention, a motor 132, a rotating blade 131 mounted on a rotating shaft of the motor 132, and an ejector bar 133 ), The ejector bar 133 may be omitted.

However, since the ejector bar 133 has a function of pushing the non-stick (B) to be easily discharged from the front end side of the slicing unit 100 to the front end side of the slicing unit 200, the rotating blade 131 and It is preferable to arrange them at intervals of approximately 90 °.

Next, with reference to FIGS. 12 to 14, the configuration of the front end fixing unit 140 of the slicing unit 100 will be described.

12 is a three-dimensional view showing a state in which the front end fixing unit 140 according to an embodiment is installed on the outer surface side of the front plate 510 of the cutting unit 500, and FIG. 14 shows the front end fixing unit 140 in front of the front plate. It is a sectional view of the state attached to 510. In addition, FIG. 13 is a three-dimensional view showing only the front end fixing unit 140 separately, and FIG. 13 (a) is a three-dimensional view seen from the front side, and FIG. 13 (b) is a three-dimensional view seen from the rear side.

As shown in these drawings, the front end fixing unit 140 of one embodiment is disposed on the rear side of the front plate 510 and has a plurality of pin holes and a contact plate 143 and a contact plate 143. The spike plate 142 and the spike plate 142 are disposed on the front side of the front plate 510 and provided with a plurality of pins that can emerge through the pin holes of the contact plate 143 so as to be in the corresponding position of the front plate ( It consists of two solenoids (141A, 141B) that are in close contact with or detached from the front plate (510), and a spring (144) interposed between the front plate (510) and the contact plate (143).

Here, reference numeral 560 is a discharge hole, in the form overlapping with the discharge hole 560, the fixed blade assembly 210 is installed on the outer surface side of the front plate 510.

Next, with reference to FIGS. 15 to 17, a detailed configuration of the cutting unit 500 according to an embodiment will be described.

Among the attached drawings, FIG. 15 is a photograph of the right side of the cutting unit 500 according to an embodiment, and FIG. 16 is a photograph of a part of the front side of the back plate 520 of the cutting unit 500 , FIG. 17 is a photograph of a main portion of the rear side of the front plate 510 of the cutting portion 500.

As can be understood by these drawings and FIG. 5, the cutting part 500 according to an embodiment includes a back plate 520 fixed to the front side of the front plate of the housing 400 and a front side of the back plate 520. The front plate 510 is disposed on, and the hinge 530 installed on the left side of the front plate 510 and the back plate 520, and is installed on the right side of the front plate 510 and the back plate 520. It consists of a structure having a fastener 570 and a moving path 580 that is concavely formed at a predetermined depth on the rear side of the front plate 510.

At least a rotating blade 131 is rotatably mounted on the front side of the rear plate 520, and preferably, an ejector bar to be described later is installed together with the rotating blade 131.

The fastener 570 is a structure that includes a knob of a screw tightening / unscrewing type that can be rotated in a horizontal state, and preferably, two are installed at regular intervals in the vertical direction on the right side of the cutting part 500.

The front end side of the slicing unit 100 and the slicing unit 200 is connected to the moving path 580, while the discharge hole 560 extends to the lower end side. In the case of this embodiment, the moving path 580 is formed in a vertical channel form so that the stubble B can vertically fall from the front end side of the slicing unit 100 to the front end side of the slicing unit 200. have.

However, the movement path 580 may have a shape other than a vertical channel shape, for example, an inclined channel shape in which the mud block B can move along an inclined surface.

In the radish processing apparatus of one embodiment configured as described above, when processing raw radish (A) into raw radish (C), each part of the radish processing apparatus operates as follows.

Of the accompanying drawings, FIG. 18, which has not been described previously, shows the remaining portion of the raw radish (A) that is cut off at least once by cutting the raw radish (A) or the raw radish (B) into the trough 100 of the slice 100. It is a schematic diagram showing a state in which the remaining portion of the raw radish (A) descends within the trough 110 and comes into contact with the inner surface of the trough 110 as it is sequentially sliced over this time difference.

As shown in FIG. 19, the raw radish (A) has the thickest approximately middle portion in the longitudinal direction, and becomes thinner toward both ends.

2, 5, and 9 of the present embodiment, the spike mechanism 124 of the conveying unit 120 for conveying forward toward the front side while fixing the rear end of the raw radish A, as shown in FIGS. The fixed block 129A is assembled so as to be movable in the vertical direction with respect to the support block 129B. The descending in the trough 110 is made by gravity (ie, the weight of the rest of the raw material A).

When the raw radish (A) or the rest of the raw radish (A) is transferred forward in the trough 110, it may be different when cutting the first stub (B) and cutting the stub (B) continuously. have. Specifically, in the initial state in which the raw material radish (A) is only introduced into the trough 110, as shown in FIGS. 6 and 8, the lever 125 installed in the transport block assembly 123 After the user manipulates (for example, by pressing down), the slide 126 provided at the end of the lever 125 is lifted (i.e., separated) from the threaded portion of the screw shaft 122. , Grasp the handle 128B of the conveying unit 120 by hand and apply force to the front side to move the conveying unit 120 quickly.

On the other hand, when continuously cutting the stub (B) with a time difference, no force is applied to the lever 125, so that the slide 126 is applied to the screw portion of the screw shaft 122 by the action of the spring 127. By being coupled, when the screw shaft 122 is rotated by the motor 121, the transfer unit 120 is transferred to the front side in connection with the rotation of the motor 121.

As shown in FIG. 9 and the like, when fixing the rear end of the raw material radish (A) to the conveying unit 120, hold the handle 128B connected to the rear side of the spike plate 128A having multiple pins by hand and move it to the front side. It is enough to push and pins to be stuck in the rear end of the raw material radish (A).

Next, the shear of the raw radish (A) or the shear of the rest of the raw radish (A) is fixed to the shear fixing unit 140. In detail, the shear fixing unit 140 of one embodiment is provided with a contact plate 143 in which a plurality of pin holes are formed, and a plurality of pins that can emerge through the pin holes of the contact plate 143. The spike plate 142, the solenoids 141A, 141B pushing or pulling the spike plate 142 in the front-rear direction, and the rotating blade 131 smoothly cut the stub B when cutting the stub (B). In order to be able to cut, the contact plate 143 is composed of a spring 144 that is pushed to the front side within the range of the blade thickness of the rotating blade 131 or is reversible.

As described above, in a state where the raw radish (A) or the rest of the raw radish (A) is fixed between the spike plate 142 of the front end fixing unit 140 and the spike plate 128A of the conveying unit 120, the rotating blade When the (131) cuts the non-stick (B), the contact plate (143) in contact with the front (front) of the non-stick (B) is movable in the front-rear direction within the blade thickness range of the rotating blade (131) Therefore, the cutting resistance received by the rotating blade 131 is reduced.

When the cut of the soil-free membrane B is completed, the spike plate 142 is separated from the soil-free membrane B by the operation of either solenoid 141A or 141B, and the soil-free membrane B is self-weighted. It falls to the dice slicing part 200.

On the other hand, mucus may be present on the cut surface of the mud-free membrane B. This mucous substance causes trouble when the mud-free membrane B falls only to its own weight. However, this obstacle may be solved, for example, by the ejector bar 133 provided in the rotating blade assembly 130 shown in FIG. 11.

As the non-shrunk B discharged from the slicing unit 100 is illustrated in FIG. 17 and the like, along the moving path 580 formed on the rear side of the front plate 510 of the cutting unit 500, the slicing unit ( 200).

According to the present embodiment, since the inner surface of the lower side of the moving path 580 and the inner surface of the front end portion of the dicing portion 200 are rounded curved surfaces, the stub (B) cut into a disk shape of a certain thickness is moved. It is placed in a form in contact with the inner surface of the lower side of the (580).

In other words, the center line in the vertical direction of the stubborn B is approximately coincident with the center line in the vertical direction of the movement path 580. When the raw pods (C) are processed in a state in which the center lines are coincident, the amount of occurrence of a patch such as a bad shape occurring near the shell of the non-stick film (B) is reduced.

As can be seen from Figures 4-7 and 17, the stubborn (B) is pushed to the front side by the pressing unit 220 is cut into a number of raw dices (C) while passing through the fixed blade assembly 210.

In this embodiment, when the stub (B) passes through the fixed blade assembly 210, it passes through the vertical blade 212 and then passes through the horizontal blade 211, so that no stub ( Compared to when B) passes while touching at the same time, the cutting resistance received by each cutting blade is reduced.

On the other hand, in the present embodiment, the link mechanism 223 for reciprocating the pressing block 221 of the pressing unit 220 by a predetermined stroke (stroke) consists of a configuration comprising two link rods (226A, 226B) , Of these link rods, the link rod 226B located on the front side has a shorter stroke distance than the link rod 226A located on the rear side. In other words, the front side link rod 226B oscillates during cutting of the raw pod, and the rear side link rod 226A is pressurized to forcibly pass the stub B out against the fixed blade assembly 210. Will do.

Although the embodiments exemplifying the technical spirit of the present invention have been described above with reference to the drawings, the present invention is not limited to the configuration and operation as described above, and without departing from the scope described in the specification, many of the present invention Those skilled in the art will be able to understand that changes and modifications of the system are possible. Accordingly, all such suitable changes and modifications and equivalents should also be considered within the scope of the present invention.

A: Raw radish
B: No cut
C: raw kkakdugi
100: cut into pieces
110: trough
120: conveying unit
121: motor
122: screw shaft
123: Transfer block assembly
123A: spring
124: spike mechanism
125: lever
126: slider
127: spring
128A: Spike plate
128B: Handle
129A: Fixed block
129B: Support block
130: rotating blade assembly
131: rotating blade
132: motor
133: ejector bar
140: shear fixing unit
141A, 141B: Solenoid
142: spike plate
143: contact plate
144: spring
200: diced dice
210: fixed blade assembly
211: horizontal blade
212: vertical blade
220: pressurization unit
221: Pressurized block
221A: Vertical groove
221B: Horizontal blade groove
222: motor
223: link mechanism
224: eccentric member
225: motor
226A, 226B: link rod
227: slide block
228: combining block
229: guide rod
300: control unit
400: housing
410: leveler
500: cutting part
510: front panel
520: back panel
530: hinge
540: mounting hole
550: connection hole
560: discharge hole
570: fastener
580: moving road

Claims (5)

As a radish processing device for cutting radish by cutting raw radish,
A housing in which driving means, electric and electronic elements and mechanical elements are installed;
A control unit disposed on an upper side of the housing;
It is controlled by the control unit, it is installed in two steps up and down in the housing and a slicing unit and cut into pieces;
The front end side of the slicing unit and the front end side of the slicing unit are disposed at the front of the housing to be in communication at the same time. A cutting portion formed with a moving path communicating the front end portion of the dice cut portion;
A radish processing device for dipping, characterized in that comprises a. The method according to claim 1,
The cutting machine for dipping, characterized in that the slicing unit is disposed above the slicing unit. The method according to claim 2,
The slicing unit,
A trough made of a part of the housing,
A transport unit installed to be movable in the front-rear direction within the trough to transport raw radish to the front side,
A rotating blade which is rotatably disposed in the cut portion and cuts a non-stick film of a certain thickness every rotation;
When cutting the first non-stick, the shear of the raw radish is fixed, and after the second, the shear of the remaining portion of the raw radish remaining in the trough is fixed. A non-processing device for dipping, characterized in that it comprises a shear fixing unit to release. The method according to claim 2 or claim 3,
The dices,
A fixed blade assembly in which a large number of raw dices are made when the non-stick is pressed and passed,
A non-processing device for dipping, comprising a pressing unit forcibly passing the non-soil to the fixed blade assembly. The method according to claim 4,
The cutting portion,
A rear plate fixed to the housing,
A front plate disposed in front of the rear plate,
A hinge installed on the same side of the front plate and the back plate,
And the fastener is installed on the other side of the same side of the front plate and the back plate,
It is provided with a movement path formed concave to a certain depth on the back of the front plate,
The moving furnace is a non-processing device for dipping, characterized in that the lower end of which is supported by contact with the earthen surface is made of an arc surface.

Images