KR20170122072A - The Prepared food of incision and injection machine - Google Patents

Abstract

According to the present invention, a seasoning injection pipe is formed on an inner circumferential surface of an injector body to cut a certain portion of cooking food and to inject an additive. A predetermined additive is formed to be injected into a cut portion. In order to couple a cut opening panel on the outer circumferential surface, cutting panel coupling grooves are formed in plural positions. A cutting hole having a blade on one end is mounted. A downward movement adjustment unit is formed at a predetermined position of an operation bar to perform a simultaneous and independent incision work. In addition, a support weight block is installed, and thus a simultaneous and separate incision work is performed. Even though a solid material such as a bone having a different height is present when a plurality of seasoning injectors are moved downward to be cut, it is possible to individually cut and stop a blade without any difficulty. An individual additive can be injected. A known transfer means is provided to repeatedly cut cooking food at predetermined intervals and to inject additives. In addition, the cooking time of a cook can be reduced, and the same operating function is ensured regardless of the size of food. Hygienic cooking is possible compared to the characteristics of cooking requiring efforts. Also, the present invention has an effect of enabling a user to feel a soft food and good flavor texture.

Description

Technical Field [0001] The present invention relates to an automatic incision apparatus and an automatic incision apparatus,

The present invention relates to a cutter and an injector for forming an incision in a food and for adding additives such as sauce to the incision, and more particularly, The formed incision panel is formed in a plurality of directions and is easily incised at a plurality of positions so that the additive can be easily injected into the incised site to create an environment in which the taster can easily soften the cooked food and chew the food, And an insert injector having a plurality of positions for raising the texture effect of the taster by the injected additive.

[0003] Conventional cooking methods use a mechanism such as an esophagus in which cooked meat is thick and thick meat (including all foods and food to be cooked, hereinafter referred to as "cooked food "), And the additive was added to the outer surface of the cooked food or between the formed sheaths and cooked by baking, frying, steam or the like. As a result, the cooker consumes a large amount of cooking time for forming the sheath, and the injection of the additives can not be uniformly injected into the inside of the cooked food or a plurality of positions. When the baking is carried out, There is a problem in that the additive on the surface rubs.

In addition, when baked, steamed and steamed, the bulbs (roots such as sweet potatoes, carrots, and potatoes) were burnt and thickened due to their thick volume, there was a problem that the inside was not ripe even when the surface was burned or scraped.

In addition, the patent application "2019890006581, meat spice dispenser" means that a syringe with a plurality of injection needles is mounted on one lift panel, and when the injection needle is fed into the meat, the seasoning supplied from the feeder is injected into the meat Respectively.

Such a structure has a problem in that the injected additive is difficult to spread over a wide range because there is no incision part cut in a plurality of directions, and there is no effect of a large number of cuts on the processed food,

In meat such as chicken, pork, beef, and duck which contains solid matter such as some bones, when the injection needle touches the site where the bone is located, the tip of the injection needle is damaged, It is not possible to apply the automatic injector because the injector structure having a structure in which a plurality of injection needles are mounted can not be applied because the other injection needles can not be inserted in the direction of the injection needle. At the same time, the problem of pre-treatment which can make many spice injector structures occurred. Especially, in a foodservice company that supplies a large amount of cooked food to customers, there arises a problem of cost and time of pre-processing of high-priced chefs. In one embodiment, it is necessary to keep the chicken wings, chicken wings, An inevitable problem occurred.

The present invention relates to a food processing method and a food processing method, in which a plurality of cutouts are formed in a plurality of positions of a cooked food so as to spread the additives evenly, and the downward movement is stopped due to the incision structure, The bone-free surrounding incision is continuously lowered and incised, and the sensor of the additive feeder stops the addition and injection of the additive when it ascends. In addition to the incisions at many positions, additives such as seasonings, sauces, edible oil, (Hereinafter referred to as "additives") are injected into the molten food, and the processed food is aged to create an environment in which the tastemaker can softly feel the ingested cooked food and easily chew food, The injected additives increase the effect of the food taste of the tastemaster and provide easy digestion in the stomach, .

In order to achieve the above-mentioned object,

The engaging portion 102 is formed on one side of the edge of the engaging groove 109 which is connected to the injection pipe 106 on the inner circumferential surface of the upper one side for engaging with the lower engaging portion 314 of the operation bar 310, The incision portion expansion portion 104 is formed on the outer circumferential surface of the tube 106 and the first and second incision panels 304 and 305 are formed at the plurality of positions of the extension portion 104 A coupling bolt coupling hole 105 is formed at a predetermined position on the outer circumferential surface of the incision body 101 and a plurality of coupling bolts 107 for fixing the first and second incision panels 304 and 305 are formed, Spheres 100;

The blade 304-2 is formed at the edge of the outer circumferential surface of the integral type first incision panel 304 of the "C" type which is laterally joined to the coupling groove 305-1 of the second incision panel 305, A first incision panel 304 having a fitting groove 304-1 formed on its outer surface;

A blade 305-2 is formed at the edge of the outer circumferential surface of the integral type second incision panel 305 having a "C" shape and vertically joined to the coupling groove 304-1 of the first incision panel 304, A second incision panel 305 having a fitting groove 305-1 formed on its inner surface;

(3-1, 3-2, 3-3, or 3-4, hereinafter referred to as "multiple directions") about the additive injection tube 106 A plurality of directional incision panels 304, 305, and 307 for coupling the "inc" integral incision panels 304, 305, 307 to the incision body 101;

An insertion hole 102 is formed in the inner circumferential surface of the upper end of the incision body body 101 in which an operation bar (refer to FIG. 4) 310 and a known insertion hole 102 for coupling to the insertion portion 201 of the syringe 200 are formed. (100) to an engaging portion (201) of a known syringe (200).

In addition, to implement the mechanism for repeatedly performing automatic incision and automatic additive supply for incision and injection of the incision tool 300 and injection tube 306 structure

A backward coupling hole 671-1 is formed at a plurality of upper fixed positions and a backward bracket 671 is formed at a predetermined position of the backward coupling hole 671-1 and the cylinder receiving hole 400- An upper plate 700 forming a coupling hole 400-3 of the cylinder flange 400-2 at the edge of the receiving hole 400-1;

The operation bar receiving hole 702-1 is formed at a predetermined number of positions, the hanger shaft coupling hole 752 is formed at a plurality of predetermined positions of the edge, the rod shaft receiving hole 753 is formed at a plurality of predetermined positions of the edge, A hanger panel (702) which forms a mediastine receiving hole (754) at a plurality of edge regular positions;

The operation bar receiving hole 703-1 is formed at a predetermined number of positions, the hanger shaft coupling hole 782-1 is formed at a predetermined number of positions, and the hanger panel 702 is separated from the hanger panel 702 by a predetermined distance, 702; a guide panel 703;

A hinge 670 which supports the upper plate 700, the lower plate 701, and the hanger panel 702 by mutually supporting them;

The upper and lower ends of the hanger panel 702 and the guide panel 703 are provided with engaging portions 781 and 782 and the guide panel 703 is separated from the hanger panel 702 A hanger shaft 780 which is hung on the hinge shaft 702 so as to be operated simultaneously with the hinge shaft 780 in the up and down operation;

An operation bar head 311 having a coupling portion 311-1 formed at the lower center portion thereof;

A coupling hole 310-1 is formed at an end of the operation bar 310 and a receiving hole 312-1 and a supporting pin coupling hole 312-2 are formed at a predetermined position, And a joining portion 314 formed at a lower end of the operation bar 310;

An elastic support spring 30 formed on an outer circumferential surface of the operation bar 310;

A pressure adjusting coupling bolt 318 and an elastic support spring 40 and a ball bearing support 351 and a ball bearing 352 are provided on one side of the upper and lower working pressure regulating portions 313, The support shaft 356 and the roller 357 opposed to the seesaw support 355 are formed in the guide 355. The support shaft 356 is supported by the support shaft 356 and the support pin 353, An upward and downward working pressure regulating portion 313 formed on one side of the edge of the operation bar receiving hole 731 formed at a plurality of positions of the panel 703;

A coupling groove 316 is formed on one side of the upper end and a hollow portion 309 penetrating through the injection pipe 306 is connected to the lower end coupling portion 314 of the operation bar 310, The additive injection pipe 306 forms the incision site extension portion 303 on the outer circumferential surface and the first and second incisions 308 are formed at a plurality of positions on the outer circumferential surface of the extension portion 303, The panels 304 and 305 are formed with the coupling grooves 304-1 and 305-1 and the coupling bolt coupling hole 302 is formed at a predetermined position on the outer circumferential surface of the incision body 301 and the first and second incision panels 304 , And a plurality of coupling bolts (302-1) for fixing the coupling bolts (305);

A blade 304-2 is formed on the edge of the outer circumferential surface of the integral type first incision panel 304 having a "C" shape and laterally joined to the coupling groove 304-1 of the first incision panel 304, A first incision panel 304 having a fitting groove 304-3 formed on its outer surface;

A blade 305-2 is formed at the edge of the outer circumferential surface of the integral type second incision panel 305 having a "C" shape and vertically joined to the coupling groove 305-1 of the second incision panel 305, A second incision panel 305 having an insertion groove 305-3 formed in its inner surface;

4-1, 4-2, 4-3, or a plurality of directions, including incision in a plurality of directions, hereinafter referred to as "multiple directions") about the additive injection tube 306 A plurality of directional incision panels 304, 305, and 307 for joining the "U" shaped integral incision panels 304, 305, 307 to the incision body 101 for installation;

A through hole 326 is formed at a plurality of edges of the guide bar 325 and 322 so as to be installed at a predetermined position on the lower end of the outer circumferential surface of the incision body 301 and a coupling hole 327 formed at the center thereof is formed A fixed transfer station 323;

A fluid type flange 321 formed with a plurality of engaging holes 324 for engaging one side of the guide bars 325 and 322 at predetermined positions of the edges and having a cutting panel receiving hole 392 at the center thereof;

The one side is accommodated in the through hole 326 of the fixed type flange 323 and has a stopper 328 formed at the upper end and a plurality of guide bars 325 formed at the lower edge thereof with the engaging portion 325-1. ;

A sensor guide bar 322 formed with a guide guide 322-2 in the form of a dashed line at the upper edge thereof and an engaging portion 322-1 formed at a predetermined position on the lower edge thereof;

An elastic support spring (60) positioned on an outer circumferential surface of the incision panel (304, 305);

A known limit switch 317 located at a predetermined position on the outer circumferential surface of the incision body 301 and formed at a position where one side of the roller 317-1 contacts the sensor guide bar 322;

The device for repeatedly cutting and injecting and feeding the processed food 1000 by an electric signal interlocked with the limit switch 317 and the drive motor of the solenoid valve 319 and the known conveyor belt 1005 " Automatic cutting of the processed food 1000 by the known forward, backward, left and right direction transfer device "see Fig. 8" structure, automatic injection of the additive 90 and movement and stopping of the transfer device .

An operation bar head 411 having an engaging bolt 411-1 formed at an end of the operation bar 410 according to the present invention is formed and the upper and lower operation pressure regulators 413 And a hole 414 for receiving the pressure adjusting coupling bolt 418 and a hole 416 for receiving the ball bearing 415 are formed on one side of the inner surface of the receiving hole 412, An operation bar 410 having a coupling part 410-1 formed at a lower end thereof;

A ball bearing 417, a resilient support spring 40 and a pressure regulating bolt 418 in this order are provided on one side in this order to be installed inside the receiving hole 412 in order of upward and downward working pressures An adjusting unit 413;

The upper and lower operating pressure regulating portions 413 are formed in the upper and lower operating pressure regulating portions 413 so that the operating bar 410 formed at a plurality of positions on the guide panel 730 has the receiving holes 731, And forming the ball bearing 415 support portion 419.

In addition, the operation bar 500 according to the present invention may have a head 511 formed integrally with the lower end of the operation bar coupling bolt 511-1 at an end thereof, and a curved protrusion 511- An operation bar 500 having an engaging portion 501 formed at a lower end thereof,

A reception hole (731) for the operation bar (500) formed at a plurality of positions of the guide panel (703);

A roller 515 having a shaft shaft 515-1 formed at the center left and right sides thereof;

A shaft shaft 515-1 receiving hole 514-1 is formed on the left and right side edges of the receiving hole 731 and a guide protrusion 512 is formed on the left and right outer surfaces, A left and right flow brackets 514 having a shaft shaft 513 integrally formed with the pressure intensity adjusting portion 513-1 of the elastic support spring 70;

A guide block 516 having guide projections 511 receiving grooves 516-1 facing each other on the left and right sides;

A support bracket 518 having a shaft 513 receiving hole 517 formed on one side thereof;

And forming an elastic support spring (70) to be engaged with the outer circumferential surface of the shaft (513).

The first and second weight supporting blocks 620 and 620-1 are formed at a plurality of positions on the upper plate 700 according to the present invention. -1, a cylinder rear engagement hole 700-2, an upper plate 700 formed with a rearward engagement hole 670-1 and a bracket engagement hole 67-1 at a plurality of predetermined positions of the edge, respectively.

A hinge 650 for supporting and supporting the upper plate 700 and the lower plate 701 and the hanger panel 750;

A hanger panel 750 having the operation bar receiving hole 751, the rod side coupling hole 753, the hanger shaft receiving hole 652, the rearward receiving hole 690, and the guide posterior combining hole 754 formed at the above- );

A guide panel 760 in which the operation bar receiving hole 761 and the hanger shaft receiving hole 672 are formed at the plurality of positions;

A hanger shaft 780 having the engaging portions 781 and 782 at the upper and lower ends thereof;

An operation bar 600 having a first weight block coupling hole 612 at an upper end thereof, an additive supply pipe receiving hole 614 at a central portion thereof, and a connection socket coupling hole 613 at a lower end thereof;

An additive supply pipe 680 having an engaging portion 681 at the lower end and an engaging portion 682 at the upper end;

A weight supporting first block 620 having a weight supporting second block coupling hole 622 at the upper end thereof, a working bar coupling portion 621 at the lower end thereof, and a supply pipe receiving hole 623 at the center thereof;

In the case where additional weight is required by forming the coupling hole 622-1 at the upper end, the weight supporting first block coupling portion 621-1 at the lower end, and the supply pipe receiving hole 623-1 at the central portion, A second weight support block 620-1 to be added to an upper portion of the first block 620;

A connection socket 630 having an operating bar engaging portion 631 at the upper end, an additive supply hole 633 at the central portion, and a solenoid valve engaging portion 602 at the lower end;

A known solenoid valve 601 in which a connection socket coupling hole 602 is formed at the upper end side and a coupling hole 603 is formed at the lower end side and an additive supply hole 604 is formed at the center thereof;

A cut portion extension 655 at the outer circumferential surface of the additive injection tube 654 and first and second cut panel engagement grooves 606 and 607 at a plurality of positions on the outer circumferential surface of the extension portion, An incision body 651 having a plurality of coupling bolts for fixing the coupling bolt coupling hole 656 and the first and second incision panels 604 and 605 at predetermined positions on the outer circumferential surface of the upper part of the primary body 651;

A first cutting panel 604 having a "c" shape and laterally joined to the first cutting panel 604 coupling groove 604-1 has a blade 604-2 at the periphery of the outer periphery thereof, A first incision panel 604 having a fitting groove 604-3 formed therein;

A blade 605-2 is formed at the edge of the outer circumferential surface of the integral type second incision panel 605 having a "C" shape and vertically joined to the coupling groove 605-1 of the second incision panel 605, A second incision panel 305 forming a fitting groove 605-3;

A fixation flange 624 having a guide bar through hole 624-2 and a coupling hole 624-1 formed at the center thereof at a plurality of positions on the peripheral edge of the incision body body 651;

A fluid type flange 625 having a plurality of guide bar coupling holes 625-1 at a predetermined position of the edge and a cutting panel receiving hole 625-2 at a central portion thereof;

The one side is accommodated in the through hole 624-2 of the fixed type flange 624 and is provided with a plurality of guide bars 629-1 having a stopper 629-2 at the upper end and a coupling portion 629-1 at the lower edge, );

A sensor guide bar 628 in which a guide guide 628-2 in the form of a hat is formed on the upper edge, and an engaging portion 628-1 is formed in the lower edge;

An elastic support spring (60) positioned on an outer circumferential surface of the cutting panel (626, 627);

A known limit switch 617 is provided at a predetermined position on the outer circumferential surface of the incision body body 651 and at a position where one side of the roller 617-1 abuts against the inclined surface of the guide 628-2 of the sensor guide bar 628, );

The device for repeatedly cutting and injecting and feeding the processed food 1000 by means of an electric signal interlocked with the limit switch 617 and the drive motor of the solenoid valve 601 and the known conveyor belt 1005 " Automatic cutting of the processed food 1000 by the known "forward, backward, leftward and rightward feeder" see FIG. 8 structure, automatic injection of the additive 90, and movement and stop of the feeder .

Further, a known proximity sensor 317-2 for controlling the "ON, OFF" operation for injecting the additive 90, which is located at a predetermined position on the outer circumferential surface of the incision body body 301;

The solenoid valve 402 of the proximity sensor 317-2 and the solenoid valve 319 and the known upper and lower operating cylinders 400 and the drive motor of the known conveyor belt 1005 are turned ON and OFF 12 "for transferring the cut and injected food product 1000 repeatedly by means of an electric signal interlocked with the switch 750 for transferring the processed food 1000, or by means of a known front, rear, left, Automatically cutting the processed food 1000 and automatically injecting the additive 90, and moving and stopping the transfer device.

In addition, the present invention relates to a cutting tool, which includes cutting panel engaging grooves 251 and 252, a plurality of engaging bolt engaging holes 253 at a plurality of positions on the edge, and a plurality of engaging bolts 255), an incision body (201) having a coupling hole (254) formed on a side of an upper end of the body (201) of the incision;

A first incision panel 260 having a blade 260-1 formed at the outer peripheral surface of the first incision panel 260 and an outer surface fitting groove 260-2 formed at the center of the blade edge;

A second incision panel 261 having a blade 261-1 formed at the outer circumferential surface of the second incision panel 261 and a fitting groove 261-2 formed at an inner side surface of the blade center portion;

An integrated incision panel 260 or 260 for coupling the first and second incision panels 260 and 261 in a plurality of directions crossing each other is formed by forming a incision 200 coupled to the incision body 201, And a simple incision of the food (1000).

In addition, it is also possible to form a known transverse conveying means (conveyor belt, LM guide and drive motor) structure for repeatedly executing a plurality of incisions and a large amount of additive injection according to the present invention, (The upper and lower actuating devices can use various devices of a power transmission device such as a ball screw, a rack gear, and a chain in addition to a cylinder type, hereinafter referred to as "cylinder"), , A proximity sensor, a solo reed valve, etc.), and is constituted by a mechanism that operates continuously and repeatedly, and is not limited to only cooking food, and is characterized by having the same effect on industrial products or industrial products .

The present invention has a problem in that it can not penetrate deeply into the inside of a conventional form in which the surface of a cooked food is covered with an additive such as sauce,

Because of the structure of the present invention, the inside of the deep cooked food is cut into a large thickness and the inside of the deep cooked food is cut in a plurality of directions, so that the soft nature of the meat is formed, and the additives are injected through the cut- It is easy to mature evenly after incision of cooked foods and additives, quick aging effect is generated,

In addition, since a large amount of water is repeatedly cut away at a predetermined interval, the position of the incision and the addition of the additives are uniformly distributed.

In addition, the above-mentioned conditions are formed to improve the texture of the processed food consumers, and the effect of facilitating the processing of the processed foods of the elderly, boys and girls with poor teeth,

In addition, as described above, the processed food which is prematurely aged due to the additives distributed evenly inside the processed food proceeds partly in the extinguished state, so that it has an effect of assisting digestion in the gastrointestinal tract of the ingrediant.

In order to achieve the above object, the upper and lower pressure actuation adjusting portions and the supporting weight blocks are formed at predetermined positions of the operation bar formed in the injector, so that the plurality of the sterilizing injectors are operated downward simultaneously to form solid materials such as bones, The incision opening of the abutted portion is stopped and the incision opening that has not yet abutted is continuously lowered to perform the simultaneous descent and simultaneous incision operation independently of the multiple incision openings independently of the blade, The present invention also provides a structure in which an additive injection or stop means is independently formed at the time of operation so that the processing operation can be easily performed in any environment of the processed food. Through the above means, the cooking time of the cooker can be shortened, , The hand of the cooker is placed in the cooked food. Due to the structure comes out of the reach brought a hygienic cooking possible effects.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an exploded perspective view and an assembled perspective view showing the structure of an incision port and an additive injector of a processed food according to the present invention; FIG.
FIG. 2 is a perspective view for explaining the structure of an incision port and an additive injector of a processed food according to the present invention in a known hand syringe. FIG.
Fig. 3 is a bottom view of a cutting mouth of the processed food according to the present invention and a part of the structure of the additive injector. Fig.
4 is a longitudinal sectional view showing an incision structure by an upper and a lower operating pressure adjusting section of an automatic incision and automatic additive injector structure of a processed food according to the present invention.
FIG. 5 is an exploded perspective view of a cutting mouth and an additive injector structure of a processed food according to the present invention. FIG.
6 is an electrical signal sequence and assembled perspective view of the cutout and additive injector structure of the processed food according to the present invention.
7 is a longitudinal sectional view showing a procedure of moving down the cutting order of the incision opening and the additive injector structure of the processed food according to the present invention.
FIG. 8 is a longitudinal sectional view showing a procedure of upward movement of a cutting tool and an additive injector structure of a processed food according to the present invention. FIG.
9 is a partial perspective view of a cutting tool and an additive injector structure of a processed food according to the present invention combined with a known feed mechanism (conveyor belt).
10 is a partial perspective view of a cutting tool and an additive injector structure of a processed food according to the present invention combined with a known feed mechanism.
11 is a partial perspective view showing an upper and a lower operating pressure regulating section of a cutout of the processed food and an additive injector structure according to the present invention.
12 is a partial perspective view showing the upper and lower operating pressure regulating portions of the cutout of the processed food and the additive injector structure according to the present invention.
13 is a longitudinal sectional view showing an incision structure by a support weight block structure of an automatic incision and automatic addition injection structure of processed food according to the present invention.
FIG. 14 is a partially perspective view showing a proximity sensor structure of a processed food cutter and an additive injector structure according to the present invention. FIG.
Fig. 15 is an exploded perspective view and an assembly view showing a cutting mouth structure of a processed food according to the present invention; Fig.

The terms or words used in the present description and claims are intended to mean that they conform to the technical idea of the present invention on the basis that the inventor can properly define the concept of the term in order to explain its invention in the best way possible Should be interpreted as a concept.

Throughout the specification, when an element is referred to as "including" an element, it is meant to include not only excluding but also excluding other elements, Hardware, and software.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, the structure of an embodiment of a cutting and injecting machine for a cooked food according to the present invention will be described in detail with reference to the drawings.

Fig. 1 shows the processed food incision and additive injector of the present invention separated from each other,

Figure 2 shows the processed food incision and additive injector of the present invention in combination with a known injection device,

Fig. 3 is a bottom view of the processed food incision and additive injector according to the present invention.

The incision opening 100 is connected to the injection tube 106 on the inner circumferential surface of the upper end side for coupling with the engaging portion 201 of the known injector 200 or the lower end engaging portion 314 of the operation bar 310 And a coupling portion 102 is formed at the edge of the coupling groove 109 so as to be coupled to a known syringe coupling portion 201. In addition, The first and second incision panels 304 and 305 are formed at a plurality of positions on the outer circumferential surface of the expansion part 104 so as to easily inject the additive at the time of injecting the additive, Thereby preventing the first and second incision panels 304 and 305 from rocking and forming a coupling bolt coupling hole 105 at a predetermined position on the outer circumferential surface of the incision body body 101 And the first and second incision panels 304 and 305 are mounted with a plurality of coupling bolts 107.

The first incision panel 304 is connected to the edge of the outer circumferential surface of the integral first incision panel 304 of the "C" shape so as to be transversely joined to the engaging groove 305-1 of the second incision panel 305, 2, and a fitting groove 304-1 is formed at one side of the edge of the blade edge to interlock with the second cutting panel 305 to prevent the left and right swinging.

The second incision panel 305 is connected to the edge of the outer circumferential surface of the integral second incision panel 305 of the "C" form so as to vertically engage with the engaging groove 304-1 of the first incision panel 304, And a fitting groove 305-1 is formed at one side of the blade at the center of the blade to interlock with the first cutting panel 304 to prevent the left and right swinging.

The multiple directional cutting panels 304, 305, and 307 are arranged in a plurality of directions (see FIGS. 3-1, 3-2, 3-3, or 3-4) (Or may be combined by a method such as welding by constituting a stand-alone cut-out panel) to the cut-out portion body 101, And dissecting the cut form of the processed food into the form of a release form according to the type of the processed food.

Figure 4 also shows the automatic cutting of the processed food of the present invention and the automatic feed adder and support mechanism, automatic operation mechanism, and known transport mechanism,

Figure 5 is a perspective view of an incision for injecting an additive of the present invention,

Fig. 6 is a perspective view of the processed food incision and additive injector according to the present invention,

Fig. 7 shows a procedure in which the processed food cutter of the present invention cuts and drops the processed food,

Figure 8 shows the sequence in which the incision is raised with the addition of the additive of the present invention,

9 shows a processed food incision and additive injector of the present invention and a known feed mechanism,

Fig. 10 shows a processed food incision and additive injector of the present invention and a known feed mechanism.

The guide panel 703 according to the present invention has the operation bar receiving holes 703-1 formed at a plurality of positions to engage the operation bar 310 so that the operation bar 310 is rotated A hanger shaft coupling hole 782-1 is formed at a plurality of predetermined positions to engage the hanger shaft side coupling portion 782 to separate the hanger panel 702 from the hanger panel 702 So that the hanger panel 702 is caught.

The hanger 670 supports the upper plate 700, the lower plate 701, and the hanger panel 702 to mutually support each other.

The hanger shaft 780 is provided with engaging portions 781 and 782 at upper and lower ends so that the means for separating the hanger panel 702 from the guide panel 703 and the guide panel 703 are separated from the hanger panel 702 so as to operate simultaneously in a state of being separated from each other during the up and down operation.

The operation bar 310 is formed with an upward and downward working pressure regulating portion accommodating hole 312-1 formed with a supporting pin engaging hole 312-2 at a predetermined position of the body 312 and a resilient supporting spring 30 The head 311 engaging portion 311-1 is coupled to the end engaging hole 310-1 on the operation bar 310 while the engaging portion 314 is engaged with the engaging portion 314 on the lower end, The body 311 of the operation bar 310 is coupled to the receiving hole 702-1 formed at a plurality of positions of the hanger panel 702 so that the head 311 is mastically mounted do,

The upper and lower working pressure regulating portions 313 are coupled to the upper and lower working pressure regulating portion accommodating holes 312-1 of the operation bar 310 at predetermined positions, The support pins 353 are formed by aligning the support pin receiving holes 354 formed in advance with the support pin engagement holes 312-2 formed in advance by inserting the support pins 353, The support pin shaft 353 is coupled so as not to protrude from the outer surface of the body 312 and then the ball bearing 352, the ball bearing support 351, the elastic support spring 40, and the pressure adjusting coupling bolt 318 And a means for adjusting the pressure of the resilient support spring 40 by regulating the pressure regulating engagement bolt 318 by a tightening and releasing operation and having a roller shaft shaft 356 opposed to the seesupport 355 The roller 357 is formed on one side of the guide panel 703 at a certain position, Down operation pressure regulating unit 313 which serves to press the processed food 1000 to be incised when it is lowered and has the means of a downward working pressure regulating unit 313 when it comes into contact with a solid material such as bone 1001, The guide panel 703 has means for releasing the downward pressure and means for holding the incision port 300 upward when the guide panel 703 is upward. At this time, a plurality of incisions 300 are lowered while hung on the hanger panel 702. In the solid material portion such as the bones 1001, the incision tool 300 is operated individually by the rotation operation of the seesupport 355 And a downward working pressure regulating unit 313. The pressure regulating unit 313 includes a pressure regulating unit 313,

The elastic support spring 30 hits the rotation supporting seesupport 355 in a clockwise direction about the support pin 353 formed on the guide panel 703 in the upward operation of the hanger panel 703, When the upper surface of the head 311 coupled to the operation bar 310 is abutted on the lower surface of the plate 700, the support pin 353 is pivoted about the axis of the elastic support spring 40 The support pin 353 rotates counterclockwise by the rotation of the support pin 353 due to the pressure higher than the pressure strength so that the upward pressure is released and the cutter 300 drops and the head 311 is caught on the upper surface of the hanger panel 702. At this time, it was configured to buffer the drop impact.

The cut mouth body 301 is formed with an engagement groove 316 on the upper side and a hollow portion 309 penetrating the additive injection pipe 306 to be engaged with the lower end engagement portion 314 of the operation bar 310. [ The additive pipe coupling hole 315 is formed on one side of the fixed position so that the solenoid valve 319 is coupled to form the injection and stop structure of the additive 90 and the additive injection pipe 306 is formed A cutting section extension section 303 is formed on the outer circumferential surface to provide a proper injection means at the time of injecting the additive 90 and the first and second incision panels 304 and 305 ) Engagement grooves 304-1 and 305-1 are formed so as to prevent the left and right swinging after mounting the first and second incision panels 304 and 305. In addition, A plurality of coupling bolts 3 for fixing the first and second incision panels 304 and 305 are formed by forming the coupling holes 302 to prevent the first and second incision panels 304 and 305 from being mounted and removed, 02-1).

The first incision panel 304 is formed integrally with the coupling groove 304-1 so as to be transversely coupled to the first incision panel 304 and the blade 304-2 is formed at the edge of the outer periphery of the first incision panel 304 And an outer side fitting groove 304-3 is formed at the center of the edge of the blade 304-2 so as to form a rigid structure together with the second cutting panel 305. [

The second incision panel 305 is formed with a blade 305-2 at the edge of the outer circumference of the integral second incision panel 305 of the "C" shape so as to be vertically coupled to the coupling groove 305-1, 305-2 and the first incision panel 304 to form a rigid structure.

The multi-directional incision panels 304, 305 and 307 are integrally formed with the single-piece incision panels 304, 305, and 307 in a plurality of directions about the additive injection tube 306, 301) and cut in a plurality of directions at the time of cutting the processed food (1000) so that the additive (90) can uniformly permeate the inside of the processed food (1000).

The fixed flange 323 has through holes 326 formed at a plurality of positions of the edges so as to be installed at a predetermined position below the outer circumference of the incision body 301, A through hole 326-1 for receiving the sensor guide bar 322 is formed in at least one through hole of the guide bar through hole 326 formed at a plurality of positions on the edge of the outer circumferential surface, So that the fluidized flanges 321 coupled to the bars 325 and 322 can be easily operated up and down.

The fluid type flange 321 is located on the outer circumferential surface of the first and second incision panels 304 and 305 and has a cutting panel receiving hole 329 formed at the center thereof and has guide bars 325 and 322 at predetermined positions. Thereby forming a coupling hole 324. The cut pieces of the processed food 1000 and the cut pieces of the processed food 1000 can be separated from each other by the cutter panels 304 and 305 which are inserted into the processed food 1000 together with the elastic support springs 60 by engaging the guide bars 325 and 322, And means for controlling the phenomenon of coming up to the vehicle.

One end of the guide bar 325 is received in the through hole 326 of the stationary rear flange 323 and the engaging portion 325 for engaging the stopper 328 is formed at the upper end and the engaging portion 325 -1) so that one end of the guide bar 325 is fixed to the coupling hole 324 of the fluid type flange 321.

The sensor guide bar 322 is formed with a guiding guide 322-2 in the form of a dashed line at its upper edge and one side is received in the through hole 326 of the fixed rear flange 323 and a stopper 328- 1) a stopper 328-1 formed with a coupling bolt 328-2 on one side by forming a coupling hole 322-1 is coupled to a predetermined position on the sensor guide bar 322 and a coupling portion And one end of the guide bar 322 is fixedly coupled to the coupling hole 324 of the fluid type flange 321.

The elastic support spring 60 is disposed on the outer circumferential surface of the cutting panels 304 and 305 to support the fluid type flange 321 to cut the processed food in the processed food 1000, And means for controlling the phenomenon that the main body 1000 is lifted upward.

The limit switch 317 is located at a predetermined position on the outer circumferential surface of the incision ball body 301 and is formed at a position where one side of the roller 317-1 abuts on the guide guide 322-2 of the sensor guide bar 322, And a mechanism for repeatedly injecting the additive (90) by an electric signal correlated with a solenoid valve (402) controlling the lifting operation of the operating cylinder (400).

7, " or a known forward, backward, leftward and rightward feed device "see Fig. 8" in the form of a conveyor belt 1005, 1000), and automatically injecting and stopping the additive (90).

If the incision and the step of injecting the additives are performed in the order of the above-described structure,

The rod side engaging portion 401 moves down while the rod side engaging portion 401 of the cylinder 400 is engaged with the hanger panel 702 at a predetermined position and the hanger panel 702 moves downward The end head 311 is lifted and lowered together with the elastic support spring 30 so that all of the incision openings 300 are simultaneously lowered to the upper surface of the processed food 1000 in a state of being attached, The guide panel 703 is continuously lowered together with the hanger panel 702 so that the operation of the guide panel 703 is stopped at a predetermined number of positions One side of the roller 357 formed on one side of the bar receiving hole 703-1 reaches one side of the seesaw support 355 in the left-turned state.

At this time, when one side of the roller 357 presses the one side of the seesaw support 355 and is pushed downward, the pressure of the seesaw support 355 in the left-turn state due to the pressure strength of the elastic support spring 40, The knife edges 304-1 and 305-1 formed at the lower end of the cutting mouth 300 to be lowered cut the processed food 1000 and the lowering operation is performed. At the same time, the roller 317-1 of the limit switch 317 comes into contact with the guide guide 322-2 of the sensor guide bar 322 so that the power of the primary (A) is in the "+" state and the solenoid valve 319 When the guide panel 703 is continuously contacted with the solid material such as the bone 1001 in the descending order and the blades 304-1 and 305-1 come in contact with the power line B, One side of the roller 357 coupled to the guide panel 703 presses down on one side of the seesaw support 355 so that a pressure higher than the strength of the resilient support spring 40 is applied to the seesaw support 355 The incision tool 300 is released from the downward pressure state of the guide panel 703 and is rotated in the same direction as the bone 1001 The incision opening 300 where the blades 304-1 and 305-1 are in contact with the solid material, the guide panel 703 is continuously lowered in the state where the lowering pressure is not applied The second and third incision openings 300, which are not in contact with the solid material such as the bone 1001, are lowered, the processed food 1000 is cut off, the hanger panel 702 B - 1 (-) "of the solenoid valve 601 of the additive supply device is changed to the upward operation signal when the power source" C (-) "of the solenoid valve 402 of the cylinder 400 changes to the upward operation signal in the upward operation. The solenoid valve 601 is opened so that the additive 90 is injected into the cooked food 1000 and the hanger panel 750 is operated upward. At this time, the incision tool 300 is in a stopped state, and the seesaw support 355 in the right rotation state of the upward and downward operation adjustment part 313, which is one side of the roller 357 of the guide panel 703, And the upward operation is performed through the seesaw support 355 in the right turn state of the upward and downward operation adjustment portion 313 which has been sequentially lowered downward so that the roller 317 of the limit switch 317 A (+) "of the limit switch 317 is cut off when the guide 317-1 of the sensor guide bar 322 is out of the guide 322-2 of the sensor guide bar 322, The operation bar 310 which is operated upward continuously together with the operation bar 310 maintains the pressure strength of the elastic support spring 40 when the upper surface of the head 311 comes into contact with the lower surface of the upper plate 700, The seesaw support 355 in the right turning state, which is raised upward, The seesaw support 355 from the roller 357 is released from pressure and the incision orifice 300 which is mounted on one side of the roller 357 and is actuated upward, And the head 311 coupled to the operation bar 310 is seated on the hanger panel 702 smoothly and is ready to be operated again for the first time, The mechanism is repeatedly operated by an automatic feeding device that repeatedly punches, cuts, and injects the desired interval by feeding the preset interval. By reducing the cooking time and reducing the cooking cost, the foodstuff texture, softness, and additives It is an incision and injection structure that is distributed evenly inside the processed food and focuses on hygiene.

11 is a partially enlarged view of the upper and lower pressure regulating portions of the processed food cutter of the present invention.

The operation bar 410 according to the present invention is provided with an operation bar head 411 formed with an engagement bolt 411-1 at an upper end thereof and is operable to be operated to a receiving hole 702-1 formed at a plurality of positions of the hanger panel 702 The head 311 is coupled to the body 312 of the bar 310 to form a receiving hole 412 for engaging the upper and lower operating pressure regulating portions 413 at a predetermined position of the operating bar 410 At this time, the pressure adjusting coupling bolt 418 coupling hole 414 is formed on one side of the inner surface of the receiving hole 412 so that the pressing strength of the elastic supporting spring 40 is made strong and weak with the pressure adjusting coupling bolt 418 Adjust it.

The engaging portion 410-1 is formed at the lower end of the operation bar 410 to engage the incision body 301. [

The upper and lower working pressure regulating portions 413 are respectively provided with a ball bearing 415, a ball bearing support 417, an elastic supporting spring 40, a pressure regulating coupling bolt And the hanger panel 702 is operated in the upward and downward directions to release and raise the operation bar 310 from the downward pressure of the operation bar 310 when the operation bar 310 is operated up and down.

The supporting portion 419 is provided at the upper and lower corners of one side of the receiving hole 731 of the operating bar 410 formed at a plurality of positions of the guide panel 730 so as to oppose the upper and lower operating pressure adjusting portions 413, So that the left and right operation of the ball bearing 415 is smoothly operated.

12 is a partially enlarged view of the upper and lower pressure regulating portions of the processed food cutter of the present invention.

The operation bar 500 according to the present invention has the engagement hole 510-1 formed at the upper end thereof so as to engage with the operation bar head 511 formed with the engagement bolt 511-1, The operation bar 510 is coupled to the formed receiving hole 702-1 so that the head 511 is moored and fixed and the upper and lower operating pressure adjusting portions 513 are fixed to the operating bar 510 at a predetermined position, Shaped projections 516 protruding in one shape toward one side at a predetermined position on the outer circumferential surface,

The upper and lower operating pressure adjusting portions 513 are located on one side of the receiving hole 731 formed at a plurality of positions of the guide panel 703 so as to face the curved protrusions 516, 515-1 are formed on the shaft 515-1 of the shaft 515-1 at the left and right edges to form guide projections 512 on the left and right outer surfaces, And a bracket 514 integrally formed with a shaft 513 to which a regulating portion 513-1 for adjusting the pressure intensity of the elastic support spring 70 is coupled to one side of the guide panel 703, And acts to release the lowering pressure of the operating bar 500 and the releasing and upward operating pressure of the operating bar 500 when the operating bar 500 is operated up and down. The guide block 516 having the guide protrusions 511 receiving grooves 516-1 formed at the left and right sides of the guide blocks 516-1 and 515-2 is prevented from coming off when the roller 515 protruding from the shaft 515-1 is operated to the left and right, And the support bracket 518 in which the shaft 513 receiving hole 517 is formed on one side supports the left and right operation of the shaft 513. [

The receiving hole 731 is formed at a plurality of positions of the guide panel 703 so as to form an operation bar receiving hole 731 so that the operation bar 500 serves as a guide when the operation bar 500 is operated up and down, (500).

Fig. 13 shows the processed food incision and additive injector of the present invention in a state where they are coupled to each other.

The upper plate 700 according to the present invention is formed with first and second weight supporting block receiving holes 730 formed at a plurality of positions so that the operating bar 600 penetrates during the upper and lower operation, The rod shaft receiving hole 700-1 is formed to accommodate the rod shaft 400-1 and the flange connecting hole 700-2 is formed at a predetermined position of the rod shaft receiving hole 700-1 And the cylinder 400 is coupled to the bracket coupling hole 670-1 so that the bracket coupling hole 671-1 is formed at a certain position on the edge of the coupling hole 670-1 So that the follower 670 is coupled to the upper plate 700 at a predetermined position together with the follower bracket 671.

The hanger 650 supports the upper plate 700, the lower plate 701, and the hanger panel 750 by mutually supporting them.

The hanger panel 750 may have a plurality of operation bar receiving holes 751 formed at a plurality of positions so that the weight supporting first block 620 and the operation bar 600 are coupled to the receiving hole 751, The hanger shaft 780 is coupled to the engaging hole 752 so that the hanger shaft 780 is engaged with the engaging hole 752. The hanger shaft 780 is engaged with the engaging hole 752, And a rod-side engagement hole 753 is formed at a plurality of predetermined positions so that the hanger panel 750 is held after the rod-side engagement portion 400-2 is engaged and operated to move up and down. The hanger panel 750 is formed with the guide posterior receiving hole 754 at a plurality of predetermined positions so that the hanger panel 750 is engaged with the guide posterior ridge 691 So as to prevent the hanger panel 750 from rocking.

The guide panel 760 is provided with an operation bar receiving hole 761 at a plurality of positions so that the operation bar 600 is engaged so that the operation bar 600 is pivoted left and right when the operation bar 600 is individually operated up and down And a hanger shaft accommodating hole 672 is formed at a plurality of predetermined positions so that the hanger shaft 750 and the hanger shaft 780 are spaced apart from each other by a predetermined distance.

The hanger shaft 780 has engaging portions 781 and 782 formed at upper and lower ends so that the means for separating the hanger panel 750 from the guide panel 760 and the guide panel 760 can be separated from the hanger panel 750 so as to operate simultaneously in a state in which they are spaced apart from each other in the upward and downward movement.

The operation bar 600 includes a first weight block coupling hole 612 formed at an upper end thereof to join the weight supporting first block 620 and an additive supply pipe receiving hole 614 formed at the center thereof, And the connection socket 630 is formed in the lower end of the supply pipe 680 so that the connection socket 630 is engaged with the connection socket 630 so that the connection socket 630 is operated up and down.

The additive supply pipe 680 has an engaging portion 681 formed at a lower end thereof and is coupled to a solenoid valve 601. A coupling portion 682 is formed at an upper end of the additive supply pipe 680 to engage with the supply hose 91 And means for transferring the additive 90 supplied from the external additive hopper.

The weight supporting first block 620 is formed with an engaging hole 622 to engage with the weight supporting second block 620-1 on the upper end side, And a supply pipe receiving hole 623 is formed at a central portion thereof to insert the additive supply pipe 680. [

The weight-bearing second block 620-1 is provided with a coupling hole 622-1 on the upper end side and a first block coupling portion 621- 1, and a supply pipe receiving hole 623-1 is formed at the center to insert the additive supply pipe 680. In a situation where additional weight is required depending on the type of the processed food 1000, And a means for cutting the meat inside of the processed food 1000 into weight-bearing first and second blocks by adding or removing it on the block 620.

The connection socket 630 has an engaging portion 631 formed on the upper side thereof. And the engagement portion 632 is formed on the lower end side. So as to be coupled to the solenoid valve 601.

The known solenoid valve 601 is formed with a coupling socket hole 602 on the upper end side and is coupled to one side of the coupling socket 630 and a coupling hole 603 is formed on the lower side of the coupling socket 630, And an additive supply hole 604 is formed at the center of the body 651 so as to supply and block the additive 90.

The incision body body 651 is provided with an engaging portion 651 on the upper end side to be connected to the solenoid valve 601 and an additive injection tube 654 is formed at a predetermined position on the inner surface, The incision portion expansion portion 655 is formed on the outer circumferential surface on which the first and second incision panel assemblies 65 and 65 are formed so that the additive 90 is injected at the time of injection, The grooves 626-1 and 627-1 are formed to prevent the left and right swinging after mounting the first and second incision panels 626 and 627 and to prevent the swinging motion of the coupling bolt A plurality of coupling bolts 302 (not shown) for fixing the first and second incision panels 626 and 627 are formed by forming the coupling holes 656 to prevent the first and second incision panels 626 and 627 from being attached and detached, -1).

The first incision panel 626 is formed integrally with the coupling groove 626-1 so as to be transversely joined to the coupling groove 626-1 and formed with a blade 626-2 at the outer peripheral surface of the first incision panel 626 And an outer side fitting groove 626-3 is formed at the center of the edge of the blade 626-2 to form a rigid structure together with the second cutting panel 627. [

The second incision panel 627 is formed integrally with the coupling groove 627-1 so as to be vertically coupled to the second incision panel 627 and a blade 627-2 is formed at the edge of the outer circumference of the second incision panel 627 And a fitting groove 627-3 is formed in the inner surface of the central part of the blade 627-2 to form a rigid structure together with the first incision panel 626. [

The fixation flange 624 is formed at a predetermined position below the outer circumferential surface of the incision body body 651 and has a coupling hole 624-1 formed at the center thereof with a screw thread to be engaged with a predetermined position on the outer circumferential surface of the incision body 651 And the guide bar through holes 624-2 are formed at a plurality of positions of the edge constant so that the guide bars 629 and 628 are operated to move upward and downward after the guide bars 629 and 628 are engaged.

The fluid type flange 625 is positioned on the outer circumferential surface of the first and second incision panels 626 and 627 and has a cutting panel receiving hole 625-2 formed at the center thereof. 625-1 coupled to the guide bar engaging portions 629-1 and 628-1 and the incision panels 626 and 627 worn inside the processed food 1000 together with the elastic support springs 60, And means for controlling the phenomenon that the main body 1000 is lifted upward.

One side of the guide bar 629 is accommodated in the through hole 624-2 of the stationary rear flange 624 and an engaging portion 629-3 for engaging the stopper 629-2 is formed at the upper end, The flange 629-1 is formed at the edge of the flange 625-1 so that one side of the guide bar engaging portion 629-1 is engaged with the engaging hole 625-1 of the fluid flange 625, And supports the upward and downward movement of the fluid type flange 625. As shown in Fig.

One side of the sensor guide bar 628 is accommodated in the through hole 624-2 of the stationary rear flange 624 and a guide guide 628-2 in the form of a dashed line is formed on the upper edge of the sensor guide bar 628. The limit switch 601 And the roller 617-1 of the cylinder control solenoid valve 1001 can smoothly contact the roller 617-1 of the cylinder control solenoid valve 1001. In conjunction with the limit switch 601 and the drive unit of the cylinder control solenoid valve and the combine belt 1005, Stopper engagement holes 322-4 are formed at an upper fixed position and a stopper 628-3 having a coupling bolt formed on one side thereof is coupled to a predetermined position above the sensor guide bar 628, 628 is formed at the lower edge of the flange 625 and one end of the sensor guide bar 628 is fixedly engaged with the coupling hole 625-1 of the fluid flange 625. [ So that the fluidized flange 625 is moved to one side of the upper surface of the fixed flange 624 Respectively.

The elastic support spring 60 is disposed on the outer circumferential surface of the cutting panels 626 and 627 and supports the movable flange 625 to cut the processed foods 626 and 627, And means for controlling the phenomenon that the main body 1000 is lifted upward.

The limit switch 601 is located at a predetermined position on the outer circumferential surface of the incision ball body 651 and is formed at a position where one side of the roller 617-1 abuts against the guide guide 628-2 of the sensor guide bar 628, The solenoid valve 402 for controlling the lifting operation of the cylinder 400 and the driving part of the conveyor belt 1005 are repeatedly cut through the interlocking electrical signal and the additive 90 And a mechanism for injecting the liquid.

If the incision and the step of injecting the additives are performed in the order of the above-described structure,

The rod side engaging portion 402 descends while the rod side engaging portion 402 of the cylinder 400 is coupled to the hanger panel 750 at a predetermined position, The supporting first block 620 or the weight supporting second block 620-1 is mounted and descended so that all of the incision openings 650 cut the processed food 1000 in the state of being mounted on the hanger panel 750 And the roller 617-1 of the limit switch 617 is in contact with the guide guide 628-2 of the sensor guide bar 628 so that the power of the primary A becomes "+" (+) Connected to the power line B of the solenoid valve 319 and connected to one side of the solid material such as the bone 1001 in descending order by one side of the blades 626-2 and 627-2 650 are not in contact with the solid material such as the bone 1001 while the other incision openings 650 are continuously incised and lowered until the solid material such as the bone 1001 comes in contact with the bone 1001 ) The blade (626-2, 627-2) in such a solid material is surface abuts stop the fall.

(-) "of the solenoid valve 402 of the cylinder 400 is changed to the upward operation signal when the hanger panel 750 is in the upward operation after the predetermined lowering operation, the solenoid valve The solenoid valve 601 is opened so that the additive 90 is injected into the cooked food 1000 and the hanger panel 750 is operated upward do. The weight supporting first block 620 coupled to the actuating bar 600 moves upward and downward (the plurality of actuating bars are individually held at different elevations) by the hanger panel 750 upwardly, (+) Of the limit switch 617 when the roller 617-1 of the limit switch 617 is out of the guide guide 628-2 of the sensor guide bar 628, The operation of the operation bar 600 is continued until the predetermined time elapses and the operation of the operation bar 600 is completed. Is a mechanism mechanism that repeatedly feeds the desired interval by repeatedly punching, cutting, and injecting the desired interval by feeding the preset interval, and has a mechanism structure in which the cooking time is shortened and the cooking cost is reduced, Reoum, the additive is evenly distributed at the same time as soon incision and implanted structure oriented to focus on hygiene within the processed food.

14 shows an automatic operation structure by the proximity sensor according to the present invention.

The proximity sensor 317-2 is positioned at a predetermined position on the outer circumferential surface of the incision body 301 so that the incision tool 300 is operated downward to cut the processed food 1000, When the electrical signal of the processed food 1000 arrives at a predetermined position of the processed food 1000, the electric power is converted into the connected state in the "0N" state, but the electric signal is not connected to the solenoid valve 319 until the secondary signal When the downward operation of the upper and lower operating cylinders 400 is stopped at a certain position and the solenoid valves 402 of the upper and lower operating cylinders 400 are changed to the "0N" When the proximity sensor 317-2 is spaced a certain distance from the processed food 1000 during the upward upward operation, the electrical signal of the nood valve 319 is changed to "ON " (317-2) is changed from the "0N" state to the "OFF & ON "and" OFF "of an electrical signal having a structure formed to be upwardly operated to a predetermined position and ready for a downward operation again.

Fig. 15 shows the processed food cut-outs of the present invention in a state where they are coupled to each other.

The incision body body 201 according to the present invention has the engaging grooves 251 and 252 formed to engage the incision panels 260 and 261 and the engaging bolt engaging holes 253 formed at many positions on the edges, A plurality of coupling bolts 255 are connected to the upper and lower operating members 260 and 261 and a coupling hole 254 is formed on one side of the upper end of the incising member body 201 to be coupled to the upper and lower operating bars.

The first and second incision panels 260 and 261 are formed with a first incision panel 260 coupled to the coupling groove 251 in a transverse shape and a blade 260-1 is formed on one side of the edge of the outer periphery, A first incision panel 260 having an outer side fitting groove 260-2 formed at the edge of the blade edge and a second incision panel 260 coupled to the coupling groove 252 of the second incision panel 261 A second cutting panel 261 having a fitting groove 261-2 formed on the inner side surface thereof is formed at a central portion of the blade to form a second cutting panel 261 in a plurality of directions The incision 200 is formed in the incision body 201 to apply the additive to the surface of the processed food 1000 so that the inside of the processed food 1000 is covered with the integrated incision panel 260, And a means for dissecting to evenly penetrate.

Incision --------- 300, incision body --- 301,
Operation bar --------- 310 Up / down operation pressure regulator - 313,
Head 311 incision panel joining groove 304-1, 305-1
Additive injection tube ----- 306, extension part ------ 303,
A fitting groove --- 304-3, 305, a fixed type transferring-323,
Flow type rearrangement --- 321, guide bar - 325,
Sensor guide bar ------ 322, Elastic support spring --- 60
Operation bar ----- 310, Operation bar head --- 311,
Hanger panel ---------- 702, guide panel ------ 703
Upper plate, ----- 700, blade ----------- 304-2, 305-2

Claims (7)

The engaging portion 102 is formed on one side of the edge of the engaging groove 109 which is connected to the injection pipe 106 on the inner circumferential surface of the upper one side for engaging with the lower engaging portion 314 of the operation bar 310, The incision portion expansion portion 104 is formed on the outer circumferential surface of the tube 106 and the first and second incision panels 304 and 305 are formed at the plurality of positions of the extension portion 104 A coupling bolt coupling hole 105 is formed at a predetermined position on the outer circumferential surface of the incision body 101 and a plurality of coupling bolts 107 for fixing the first and second incision panels 304 and 305 are formed, Spheres 100;
The blade 304-2 is formed at the edge of the outer circumferential surface of the integral type first incision panel 304 of the "C" type which is laterally joined to the coupling groove 305-1 of the second incision panel 305, A first incision panel 304 having a fitting groove 304-1 formed on its outer surface;
A blade 305-2 is formed at the edge of the outer circumferential surface of the integral type second incision panel 305 having a "C" shape and vertically joined to the coupling groove 304-1 of the first incision panel 304, A second incision panel 305 having a fitting groove 305-1 formed on its inner surface;
(3-1, 3-2, 3-3, or 3-4, hereinafter referred to as "multiple directions") about the additive injection tube 106 A plurality of directional incision panels 304, 305, and 307 for coupling the "inc" integral incision panels 304, 305, 307 to the incision body 101;
An insertion hole 102 is formed in the inner circumferential surface of the upper end of the incision body body 101 in which an operation bar (refer to FIG. 4) 310 and a known insertion hole 102 for coupling to the insertion portion 201 of the syringe 200 are formed. (100) to an engaging portion (201) of a known syringe (200). ≪ RTI ID = 0.0 > 31. < / RTI > To perform the incision of the incision 300 and the injection tube 306 structure and the mechanism for repeatedly executing the automatic incision and automatic addition supply of the additive injection
A backward coupling hole 671-1 is formed at a plurality of upper fixed positions and a backward bracket 671 is formed at a predetermined position of the backward coupling hole 671-1 and the cylinder receiving hole 400- An upper plate 700 forming a coupling hole 400-3 of the cylinder flange 400-2 at the edge of the receiving hole 400-1;
The operation bar receiving hole 702-1 is formed at a predetermined number of positions, the hanger shaft coupling hole 752 is formed at a plurality of predetermined positions of the edge, the rod shaft receiving hole 753 is formed at a plurality of predetermined positions of the edge, A hanger panel (702) which forms a mediastine receiving hole (754) at a plurality of edge regular positions;
The operation bar receiving hole 703-1 is formed at a predetermined number of positions, the hanger shaft coupling hole 782-1 is formed at a predetermined number of positions, and the hanger panel 702 is separated from the hanger panel 702 by a predetermined distance, 702; a guide panel 703;
A hinge 670 which supports the upper plate 700, the lower plate 701, and the hanger panel 702 by mutually supporting them;
The upper and lower ends of the hanger panel 702 and the guide panel 703 are provided with engaging portions 781 and 782 and the guide panel 703 is separated from the hanger panel 702 A hanger shaft 780 which is hung on the hinge shaft 702 so as to be operated simultaneously with the hinge shaft 780 in the up and down operation;
An operation bar head 311 having a coupling portion 311-1 formed at the lower center portion thereof;
A coupling hole 310-1 is formed at an end of the operation bar 310 and a receiving hole 312-1 and a supporting pin coupling hole 312-2 are formed at a predetermined position, And a joining portion 314 formed at a lower end of the operation bar 310;
An elastic support spring 30 formed on an outer circumferential surface of the operation bar 310;
A pressure adjusting coupling bolt 318 and an elastic support spring 40 and a ball bearing support 351 and a ball bearing 352 are provided on one side of the upper and lower working pressure regulating portions 313, The support shaft 356 and the roller 357 opposed to the seesaw support 355 are formed in the guide 355. The support shaft 356 is supported by the support shaft 356 and the support pin 353, An upward and downward working pressure regulating portion 313 formed on one side of the edge of the operation bar receiving hole 731 formed at a plurality of positions of the panel 703;
A coupling groove 316 is formed on one side of the upper end and a hollow portion 309 penetrating through the injection pipe 306 is connected to the lower end coupling portion 314 of the operation bar 310, The additive injection pipe 306 forms the incision site extension portion 303 on the outer circumferential surface and the first and second incisions 308 are formed at a plurality of positions on the outer circumferential surface of the extension portion 303, The panels 304 and 305 are formed with the coupling grooves 304-1 and 305-1 and the coupling bolt coupling holes 302 are formed at predetermined positions on the outer circumferential surface of the incision body 301, (300) in which a plurality of coupling bolts (302-1) for fixing the coupling bolts (304, 305) are formed;
A blade 304-2 is formed on the edge of the outer circumferential surface of the integral type first incision panel 304 having a "C" shape and laterally joined to the coupling groove 304-1 of the first incision panel 304, A first incision panel 304 having a fitting groove 304-3 formed on its outer surface;
A blade 305-2 is formed at the edge of the outer circumferential surface of the integral type second incision panel 305 having a "C" shape and vertically joined to the coupling groove 305-1 of the second incision panel 305, A second incision panel 305 having an insertion groove 305-3 formed in its inner surface;
4-1, 4-2, 4-3, or a plurality of directions, including incision in a plurality of directions, hereinafter referred to as "multiple directions") about the additive injection tube 306 A plurality of directional incision panels 304, 305, and 307 for joining the "U" shaped integral incision panels 304, 305, 307 to the incision body 101 for installation;
A through hole 326 is formed at a plurality of edges of the guide bar 325 and 322 so as to be installed at a predetermined position on the lower end of the outer circumferential surface of the incision body 301 and a coupling hole 327 formed at the center thereof is formed A fixed transfer station 323;
A fluid type flange 321 formed with a plurality of engaging holes 324 for engaging one side of the guide bars 325 and 322 at predetermined positions of the edges and having a cutting panel receiving hole 392 at the center thereof;
The one side is accommodated in the through hole 326 of the fixed type flange 323 and has a stopper 328 formed at the upper end and a plurality of guide bars 325 formed at the lower edge thereof with the engaging portion 325-1. ;
A sensor guide bar 322 formed with a guide guide 322-2 in the form of a dashed line at the upper edge thereof and an engaging portion 322-1 formed at a predetermined position on the lower edge thereof;
An elastic support spring (60) positioned on an outer circumferential surface of the incision panel (304, 305);
A known limit switch 317 located at a predetermined position on the outer circumferential surface of the incision body 301 and formed at a position where one side of the roller 317-1 contacts the sensor guide bar 322;
The device for repeatedly cutting and injecting and feeding the processed food 1000 by an electric signal interlocked with the limit switch 317 and the drive motor of the solenoid valve 319 and the known conveyor belt 1005 " Automatic cutting of the processed food 1000 by the known forward, backward, left and right direction transfer device "see Fig. 8" structure, automatic injection of the additive 90 and movement and stopping of the transfer device Automatic incision and automatic injection device according to incision opening and injector of cooked food characterized by. 3. The method of claim 2,
The operation bar 410 is formed with an operation bar head 411 having an engaging bolt 411-1 formed at an end thereof on the operation bar 410. The operation bar 410 has an operation bar 410, The pressure adjusting coupling bolt 418 is formed at one side of the inner surface of the receiving hole 412 and the hole 416 is formed at the other side of the receiving hole 412, 410 < / RTI >
A ball bearing 417, a resilient support spring 40 and a pressure regulating bolt 418 in this order are provided on one side in this order to be installed inside the receiving hole 412 in order of upward and downward working pressures An adjusting unit 413;
The upper and lower operating pressure regulating portions 413 are formed in the upper and lower operating pressure regulating portions 413 so that the operating bar 410 formed at a plurality of positions on the guide panel 730 has the receiving holes 731, And forming a ball bearing (415) support (419). The automatic incision and automatic injector according to the incision and injector of the cooked food. 3. The method of claim 2,
A bar 511-1 integrally formed at the lower end of the operation bar 500 is formed at the end of the operation bar 500 and a curved protrusion 516 protruding in one side toward the one side is formed at a predetermined position on the outer circumferential surface An operation bar 500 having a coupling part 501 at a lower end thereof;
A reception hole (731) for the operation bar (500) formed at a plurality of positions of the guide panel (703);
A roller 515 having a shaft shaft 515-1 formed at the center left and right sides thereof;
A shaft shaft 515-1 receiving hole 514-1 is formed on the left and right side edges of the receiving hole 731 and a guide protrusion 512 is formed on the left and right outer surfaces, A left and right flow brackets 514 having a shaft shaft 513 integrally formed with the pressure intensity adjusting portion 513-1 of the elastic support spring 70;
A guide block 516 having guide projections 511 receiving grooves 516-1 facing each other on the left and right sides;
A support bracket 518 having a shaft 513 receiving hole 517 formed on one side thereof;
And an elastic support spring (70) coupled to an outer circumferential surface of the shaft (513) is formed on the outer surface of the shaft (513). 3. The method of claim 2,
A plurality of first and second weight supporting blocks 620 and 620-1 are formed at a plurality of positions of the upper plate 700 and a cylinder receiving hole 700-1 is formed at a predetermined position of the cylinder 400, A top plate 700 having a flange engaging hole 670-1 and a bracket engaging hole 67-1 at a plurality of positions of the edge constant;
A hinge 650 for supporting and supporting the upper plate 700 and the lower plate 701 and the hanger panel 750;
A hanger panel 750 having the operation bar receiving hole 751, the rod side coupling hole 753, the hanger shaft receiving hole 652, the rearward receiving hole 690, and the guide posterior combining hole 754 formed at the above- );
A guide panel 760 in which the operation bar receiving hole 761 and the hanger shaft receiving hole 672 are formed at the plurality of positions;
A hanger shaft 780 having the engaging portions 781 and 782 at the upper and lower ends thereof;
An operation bar 600 having a first weight block coupling hole 612 at an upper end thereof, an additive supply pipe receiving hole 614 at a central portion thereof, and a connection socket coupling hole 613 at a lower end thereof;
An additive supply pipe 680 having an engaging portion 681 at the lower end and an engaging portion 682 at the upper end;
A weight supporting first block 620 having a weight supporting second block coupling hole 622 at the upper end thereof, a working bar coupling portion 621 at the lower end thereof, and a supply pipe receiving hole 623 at the center thereof;
In the case where additional weight is required by forming the coupling hole 622-1 at the upper end, the weight supporting first block coupling portion 621-1 at the lower end, and the supply pipe receiving hole 623-1 at the central portion, A second weight support block 620-1 to be added to an upper portion of the first block 620;
A connection socket 630 having an operating bar engaging portion 631 at the upper end, an additive supply hole 633 at the central portion, and a solenoid valve engaging portion 602 at the lower end;
A known solenoid valve 601 in which a connection socket coupling hole 602 is formed at the upper end side and a coupling hole 603 is formed at the lower end side and an additive supply hole 604 is formed at the center thereof;
A cut portion extension 655 at the outer circumferential surface of the additive injection tube 654 and first and second cut panel engagement grooves 606 and 607 at a plurality of positions on the outer circumferential surface of the extension portion, An incision body 651 having a plurality of coupling bolts for fixing the coupling bolt coupling hole 656 and the first and second incision panels 604 and 605 at predetermined positions on the outer circumferential surface of the upper part of the primary body 651;
A first cutting panel 604 having a "c" shape and laterally joined to the first cutting panel 604 coupling groove 604-1 has a blade 604-2 at the periphery of the outer periphery thereof, A first incision panel 604 having a fitting groove 604-3 formed therein;
A blade 605-2 is formed at the edge of the outer circumferential surface of the integral type second incision panel 605 having a "C" shape and vertically joined to the coupling groove 605-1 of the second incision panel 605, A second incision panel 305 forming a fitting groove 605-3;
A fixation flange 624 having a guide bar through hole 624-2 and a coupling hole 624-1 formed at the center thereof at a plurality of positions on the peripheral edge of the incision body body 651;
A fluid type flange 625 having a plurality of guide bar coupling holes 625-1 at a predetermined position of the edge and a cutting panel receiving hole 625-2 at a central portion thereof;
The one side is accommodated in the through hole 624-2 of the fixed type flange 624 and is provided with a plurality of guide bars 629-1 having a stopper 629-2 at the upper end and a coupling portion 629-1 at the lower edge, );
A sensor guide bar 628 in which a guide guide 628-2 in the form of a hat is formed on the upper edge, and an engaging portion 628-1 is formed in the lower edge;
An elastic support spring (60) positioned on an outer circumferential surface of the cutting panel (626, 627);
A known limit switch 617 is provided at a predetermined position on the outer circumferential surface of the incision body body 651 and at a position where one side of the roller 617-1 abuts against the inclined surface of the guide 628-2 of the sensor guide bar 628, );
The device for repeatedly cutting and injecting and feeding the processed food 1000 by means of an electric signal interlocked with the limit switch 617 and the drive motor of the solenoid valve 601 and the known conveyor belt 1005 " Automatic cutting of the processed food 1000 by the known "forward, backward, leftward and rightward feeder" see FIG. 8 structure, automatic injection of the additive 90, and movement and stop of the feeder Automatic incision and automatic injection device according to incision opening and injector of cooked food. 3. The method of claim 2,
A known proximity sensor 317-2 located at a predetermined position on the outer circumferential surface of the incision body body 301 for controlling the "ON, OFF" operation for injecting the additive 90;
The solenoid valve 402 of the proximity sensor 317-2 and the solenoid valve 319 and the known upper and lower operating cylinders 400 and the drive motor of the known conveyor belt 1005 are turned ON and OFF 12 "for transferring the cut and injected food product 1000 repeatedly by means of an electric signal interlocked with the switch 750 for transferring the processed food 1000, or by means of a known front, rear, left, And automatic incision and automatic injection device according to the incision opening and injector of the cooked food, characterized in that the automatic introduction of the processed food (1000) and the automatic injection of the additive (90) 3. The method of claim 2,
A plurality of engaging bolts 255 for fixing the incision panels 260 and 261 and a plurality of engaging projections 260 for engaging the incision 200 body 201 An incision body 201 having an engaging hole 254 formed at an upper end thereof;
A first incision panel 260 having a blade 260-1 formed at the outer peripheral surface of the first incision panel 260 and an outer surface fitting groove 260-2 formed at the center of the blade edge;
A second incision panel 261 having a blade 261-1 formed at the outer circumferential surface of the second incision panel 261 and a fitting groove 261-2 formed at an inner side surface of the blade center portion;
An integrated incision panel 260 or 260 for coupling the first and second incision panels 260 and 261 in a plurality of directions crossing each other is formed by forming a incision 200 coupled to the incision body 201, And an automatic incision and automatic infusion device according to an incision opening and injector of a cooked food, characterized in that the food (1000) is simply incised.

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