KR20120011537A - Soup close adherence and transfer device - Google Patents

Abstract

PURPOSE: A tight transfer apparatus for soup packages is provided to prevent the shaking of soup packages and sealing parts caused by vibration during high-speed transfer by tightly contacting both sides of the soup packages and sealing parts. CONSTITUTION: A tight transfer apparatus for soup packages comprises a power generator(210) which is installed in a main body, a power transmission(211) which transmits the power of the power generator, and a feeding unit(200) which tightly contacts both sides of soup packages with the power transmitted through the power transmission and transfers the soup packages. The feeding unit comprises a driving supply unit which drives a driving supply belt(224) with the power transmitted through the power transmission, a driven supply unit(240) which transfers soup packages and sealing parts using a driven supply belt cooperated with the driving supply belt, and a gap regulating unit(260) which regulates the interval between the driving and driven supply units to provide optimal transfer friction to the soup packages and sealing parts.

Description

SOUP CLOSE ADHERENCE AND TRANSFER DEVICE}

The present invention relates to a soup contact transport apparatus, and more particularly, a soup contact transport apparatus for smoothly performing soup transport without flowing or fuzzing because the soup is continuously and closely adhered to each other so that the soup is continuously fed. It is about.

In general, ramen noodles are instant dried foods with powder soup added to the noodle soup fried in oil after steaming noodles.They have more nutrients per unit weight than juicy foods, and because they are fried foods, they are about 500kcal per 120g. It is a high calorie food.

These kinds of ramen are packed with noodles and soup in a bag so that consumers can put the soup in a pot and boil it directly. have.

In this way, the soup is dried and seasoned in a plastic bag, and each one of the soups is put in a bag. The noodle is completed because the soup is individually cut and fed to the noodle noodles while the ramen is transported and packed. .

In general, one soup is prepared by putting one seasoning into each unit into a long bag and heat-sealing the joint to form a sealing portion, and the soup is continuously supplied in a long state. The sealing part is cut from the sealing part with a cutter, and the separate soups are supplied to the ramen one by one.

The above-mentioned invention means the background art of the technical field to which the present invention belongs, and does not mean the prior art.

Conventionally, the soup feeder which continuously cuts the continuously fed soup by unit and supplies it to the ramen conveyed to the conveyor is provided with a soup and a sealing part at a low speed, so that the soup and the seal may not be properly held without both sides. There was no problem in the conveyance of the ring portion.

However, in the case of developing a high speed soup feeder, which is an improvement over the conventional low speed soup feeder, the soup and the sealing part which are fed at high speed are closely adhered to both sides, and if not held in a stable manner, the soup and the sealing part are shaken by the vibration caused by the high speed feed. There is a problem that the transfer operation does not proceed smoothly.

Thus, there is a need for improvement.

The present invention closely adheres to both sides of the soup and the sealing portion to be transported at high speed to hold the stable stably to prevent shaking due to the vibration caused by the high-speed feed so that the soup tightly conveying device for smoothly performing the transfer operation of the soup and the sealing portion The purpose is to provide.

In addition, the object of the present invention, when transferring the soup and the sealing portion, it is an object to provide a soup close contact transport apparatus having a pulling force by pulling the coarse feed belt and the fed belt.

In addition, an object of the present invention is to provide a soup contact transportation device for adjusting the tension of the main feed belt and the feed belt to be in close contact with the soup and the sealing portion.

In addition, an object of the present invention is to provide a soup contact transportation apparatus for efficiently adjusting the position of the mark sensor in front, rear, left and right according to the position of the mark portion of the soup and the sealing portion of various sizes to be transferred.

In order to achieve the above object, the soup contact transport apparatus according to an embodiment of the present invention is installed in the main body portion, the power generating unit for generating power; A power transmission unit for transmitting power of the power generation unit; And a feeding part for closely contacting and transporting a plurality of soups connected to the sealing part with power received from the power transmission part on both sides, wherein the feeding part receives the power of the power transmission part to drive the main feed belt. A main supply unit installed at the main unit; A driven supply part spaced apart from the main feed supply belt and configured to transfer the soup and the sealing part together with the main supply belt to the driven supply belt driven by the power transmission unit; It characterized in that it comprises a spacing control unit for providing an optimum conveying friction force to the soup and the sealing portion by adjusting the close contact between the main feed supply and the driven supply.

In addition, the power generating unit is preferably a motor or a servo motor.

The power transmission unit may include a belt configured to transmit power by the power generation unit; A driven pulley engaged with the belt to drive a first driving roller and a first driven roller, respectively; It is preferable to include a tension roller having a tension adjusting member for adjusting the tension of the belt.

In addition, the main supply unit, the first main roller is driven by the driven pulley, driving the main supply belt; A second main roller installed spaced apart from the first main roller and rotated by the main feeding belt; A pair of driving plates on which the first and second driving rollers are installed; It is preferred that the moving plate is provided with a moving tension portion for adjusting the tension of the moving feed belt.

In addition, the coarse tension portion, and a tension roller for providing a tension to the coarse feed belt; A guide hole formed in the main plate to guide the roller shaft rotatably supporting the tension roller; An operation member for urging the roller shaft to move in the guide hole; It is preferable to include a fixed body fixed to the main plate so that the operating member is screwed to move.

The driven supply unit may include: a first driven roller driven by the driven pulley and driving the driven supply belt; A second driven roller installed spaced apart from the first driven roller and rotated by the driven supply belt; A pair of driven plates on which the first and second driven rollers are installed; A driven roller provided at the driven plate to drive a driven supply belt; It is preferable to include a driven tension unit which is installed in the second driven roller to provide a tension to the driven supply belt.

The driven tension unit may further include: a roller shaft configured to rotatably support the second driven roller to provide tension; A guide hole formed in the driven plate to guide the roller shaft; An operation member for urging the roller shaft to move in the guide hole; It is preferable to include a fixed body fixed to the driven plate so that the operating member is screwed to move.

In addition, it is preferable that the operation member is further provided with a position fixing member for fixing the position because the screw is fastened to the fixed body.

In addition, the spacing control unit, the cylinder is installed on any one side of the driven plate and the driven plate; A fixing member fixed to the shaft of the cylinder; A screw adjusting shaft screwed to the fixing member to adjust a gap; One end is fixed to the end of the screw adjustment shaft, the other end is preferably hooked to the hook portion provided on any other side of the driving plate and the driven plate to include a spring to provide an elastic force.

In addition, the feeding portion is further provided with a width adjusting portion to adjust the width of the soup continuously supplied by the sealing portion, the width adjusting portion is fixed to the main body portion, the support slot is formed; A guide roller coupled to the adjustment slot to move left and right to guide both sides of the soup and the sealing portion; It is preferable to include a tightening member that is tightened or released to adjust the position of the guide roller.

In addition, it is preferable that the inlet or outlet portion of the feeding unit is further provided with a mark detection sensor unit for controlling the time to cut the sealing portion in the cutting unit by detecting the mark portion displayed on the sealing portion.

The mark sensor detecting unit may further include: a mark detecting sensor detecting the mark unit; A support for supporting the mark detection sensor; A first fixing body supporting the first support and slidably coupled to the first support; A connecting rod having one end coupled to the first fixing body so as to slide in a vertical direction of the support body; A second fixing body to which the other end of the connecting rod is slidably coupled; A fixing member coupled to the second fixing body and installed on the main body such that the second fixing body slides in a direction perpendicular to the connecting rod; It is preferable to include a plurality of fastening members fastened to the first and second fixing bodies to press or separate the support, the connecting rod, the fixing member.

As described above, the soup contact and transport apparatus according to the present invention is in close contact with both sides of the soup and the sealing portion to be transported at high speed to hold it stably to prevent shaking due to the vibration caused by the high-speed transfer of the soup and the sealing portion transfer Work can be done smoothly.

In addition, the soup contact transport apparatus according to the present invention, when transferring the soup and the sealing portion, it is possible to effectively provide a close contact force by pulling the feeding belt and the feed belt to each other.

In addition, the soup contact transport apparatus according to the present invention can adjust the tension of the main feed belt and the feed belt to be transported in close contact with the soup and the sealing.

In addition, the soup contact and transport apparatus according to the present invention can efficiently adjust the position of the mark detection sensor in front, rear, left and right according to the position of the mark portion of the soup and the sealing portion of various sizes to be transferred.

1 is a front view of a high speed soup feeder having a soup contact transport apparatus according to an embodiment of the present invention.
Figure 2 is a front view of the thickness detector of the high speed soup feeder according to an embodiment of the present invention.
Figure 3 is a perspective view of the feeding unit of the soup contact transport apparatus according to an embodiment of the present invention.
Figure 4 is an enlarged perspective view of the feeding tension portion feeding portion in FIG.
5 is an enlarged perspective view of a driven tension portion of the feeding portion in FIG.
Figure 6 is a perspective view of the width adjusting portion and the position adjusting portion according to an embodiment of the present invention.
Figure 7 is an enlarged perspective view of the width adjusting portion and the position adjusting portion according to an embodiment of the present invention.
8 is a front view of the feeding unit of the high speed soup feeder according to an embodiment of the present invention.
Figure 9 is a front view of the cutting portion of the high speed soup feeder according to an embodiment of the present invention.
Figure 10 is a front view showing the suction pull portion and the soup feed portion of the high speed soup feeder according to an embodiment of the present invention.
Figure 11 is a state of use of the high speed soup feeder having a soup contact transport apparatus according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described a soup contact transport apparatus according to an embodiment of the present invention.

In this process, the thicknesses of the lines and the sizes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, terms to be described below are terms defined in consideration of functions in the present invention, which may vary according to the intention or convention of a user or an operator. Therefore, definitions of these terms should be made based on the contents throughout the specification.

Before explaining the soup contact transport apparatus according to the present invention, a high-speed soup feeder having a soup contact transport apparatus will be described first.

1 is a front view of a high speed soup feeder having a soup contacting apparatus according to an embodiment of the present invention, FIG. 2 is a front view of a thickness detector of a high speed soup feeder according to an embodiment of the present invention, and FIG. Front view of the cutting portion of the high speed soup feeder according to an embodiment of the present invention, Figure 10 is a front view showing the suction and the portion of the feed portion of the high speed soup feeder according to an embodiment of the present invention, Figure 11 is an embodiment of the present invention It is a state of use of the high speed soup feeder provided with the soup closely_feeding apparatus which concerns on the example.

1 and 2 and 9 to 11, a high speed soup feeder according to a preferred embodiment of the present invention, a plurality of seals are provided in the main body portion 4, and transported by the entry roller 40 It is supplied from the supply roller 50 and the supply roller 50 which are rotated by the rotational shaft 54 so as to supply a plurality of soups 30 connected to the ring portion 32, and fed by the feeding unit 200. Among the soup 30 and the sealing part 32, the soup 30 passes and the sealing part 32 cuts with the rotating cutter 340, and the sealing part 32 by the cutting part 300 Of the suction puller 400 and the suction puller 400, which provide tension by pulling the soup 30 and the sealing part 32 by vacuum suction transfer before cutting the sealing part 32 for accurate cutting of The soup 30 is disposed to be in close contact with the lower side and is sucked by the suction puller 400, and the seal 30 is cut by the cutter 340. It comprises a seupeuyi sent 450 to sequentially supply accurately in the noodles.

The supply roller 50 has a release prevention jaw 52 protruding to both sides to prevent the soup 30 to be transferred is separated.

In addition, the body portion 4 is further provided with a thickness detector 100 to detect and detect the thicknesses of the soup 30 and the sealing portion 32 which are continuously supplied before the soup contacting and transporting device A enters.

And, as shown in Figure 2, the thickness detection unit 100, the fixed frame 120 is fixed to one side to the main body portion 4, and is coupled to the fixed frame 120 by the height adjustment unit 180 Third and fourth rotatable shafts 144 and 152 rotatably coupled to the movable frame 120 and the rotating shaft 142 of the movable frame 120 and coupled to the end portions; First and second support members 140 and 150, which are opened or closed by the movement of the soup 30 and the sealing part 32 by the fourth rollers 146 and 154, and the first and second support members. Sensor unit for detecting the thickness of the elastic portion 160 to provide an elastic force to the 140, 150, and the first and second support (140, 150), respectively, is opened or retracted when entering the soup 30 It comprises 170.

And, the height adjustment unit 180, the protrusion 112 is formed to protrude on the fixed frame 110; The body is rotatably installed on the protrusion 112, the screw shaft 191 rotates up and down by the screw portion 211 of the moving frame 120 and the body coupled to the fitting protrusion 188 of the screw shaft 191. It includes a height adjusting handle 184 to rotate the portion 186, and the support portion 114 formed on the fixing frame 110 to support the end of the screw shaft 191.

The sensor unit 170 may include: a sensor 171 installed on the first support 140 and having a sensor groove 172; A sensing protrusion 182 inserted into the sensor groove 172, a moving shaft 182 which is screwed with the sensing protrusion 182 to move the zigzag protrusion 182 forward and backward, and the moving shaft 182 is supported to rotate. And a fixed body 174 fixed to the second support 150 and a handle 176 for rotating the moving shaft 182; Installed on the outer periphery of the moving shaft 182, it comprises a spring 180 for pushing the sensing protrusion 182.

The sensor groove 172 is formed of a “U” shaped groove to rotate the handle 176 to rotate the moving shaft 178 so that the sensing protrusion 182 screwed together is moved horizontally, from which the sensing protrusion 182 is formed. Is moved from the sensor groove 172 to adjust the sensing position of the sensor 171 according to the opening degree of the first and second support (140, 150).

That is, the third and fourth rollers 146 and 154 that are rotatably fixed to the end portions of the first and second support members 140 and 150 by the third and fourth pivot shafts 144 and 152. By adjusting the amount of opening of the first and second supporters 140 and 150 by the thickness of the soup 30 passing through it can be detected by setting the thickness of the soup 30 arbitrarily.

The elastic part 160 includes a support plate 165 fixed to the first support 140, a locking member 161 screwed to the support plate 165, and a handle 167, and a locking member 161. It is hung on the end of, the other end is caught by the support member 164 fixed to the second support 150 includes a spring 162 to provide elastic resilience to the first and second support (140, 150) It is done by

Since the locking member 161 is screwed and fastened to the support plate 165, the nut member 168 for controlling the movement of the locking member 161 is provided.

Then, the thickness detection unit 100, when the soup 30 is transported, is further provided with a blood detection unit 130 for detecting the empty blood without contents.

The blood detection unit 130, the first roller 124 is rotatably coupled to the first rotating shaft 122 is installed on the moving frame 120, and the guide member horizontally guided to the moving frame 120 ( One end of the second roller 134 is installed in close contact with the first roller 124 and the fixing protrusion 194 protruding from the guide member 131 so as to be rotatable to the second rotating shaft 132 installed on the 131. Is fixed, the other end is fixed to the fixed frame 110, the spring 192 to closely contact the second roller 134 to the first roller 124, and the first and second rollers (124, 134) It comprises a blood detection sensor 136 for detecting the presence of the soup passing through.

The sealing part 32 and the soup 30 which have passed through the thickness detecting part 100 pass through the feeding part 200 before entering the cutting part 300, but are in close contact with the soup feeding device A including the feeding part 200 (A). ) Will be omitted in detail.

As shown in FIGS. 8 and 9, the cutting part 300 pulls a pair of pulls installed on the fixed frame 310 to pull the side sealing part 36 of the soup 30 from the suction pulling part 400. The roller 328, 329, the power generating member 320 for providing power to the power transmission member 322 for transmitting the rotational force to the pull roller 328, the soup 30 pulled from the pull roller 328 and A plurality of cutters 340 for cutting the sealing portion 32 among the sealing portion 32 are provided with at least one pair of the rollers 336 and 344, and to transmit the rotational force to the polygonal roller 336 It includes a power generating member 330 for providing power to the power transmission member 332.

The side sealing portion 36 of the soup 30 refers to a sealed portion for sealing the soup bag on the left or right side of the soup 30 rather than the sealing portion 32 connected up and down in the soup 30.

Thus, the left and right widths (plate thickness) of the pair of pull rollers 328 and 329 will be only about 5-10 mm. Most preferably about 8mm, it is preferable to form a knurling part in order to improve the frictional force with the side sealing part 36 in the outer peripheral surface.

Pressing unit 350 for pressing the pull roller 329 and the polygon roller 344 of any one of the pair such that the pair of pull roller 328, 329 and the polygonal roller 336, 344 is in close contact with each other It is further provided.

The power transmission member 332 is axially coupled to the drive pulley 324 that is axially coupled to the power generating member 320, the drive motor, the drive belt 325 to which the drive pulley 324 is wound, and the pull roller 328. Includes a driven pulley 326.

A pull roller 328 is provided with a driving gear not shown in the shaft, and is coupled to another pull roller 329 to the driving gear, and a driven gear of the same size as the driving gear is engaged and rotated so that the pair of pull rollers is rotated. (328) 329 can be driven to face each other at the same speed.

The cutter 340 is preferably installed in the protrusion groove 338 of the polygonal roller 336, and the cutter support member 346 on which the cutter 340 is supported by the protrusion groove 345 of the polygonal roller 344 is installed. It is desirable to be. Of course, the installation position can also be configured in reverse.

Most preferably, three cutters 340 are installed.

Since the space between the cutter 340 and the cutter 340 is formed so that the soup 30 can be moved, the suction of the suction pull unit 400 positioned immediately before the cutter 340 cuts the sealing portion 32. The soup 30 is sucked and transported by the belt 432 to pull the sealing part 32 to provide tension to the cutting part 32 to facilitate cutting.

 In this state, the cutter 340 located next to the three cutters rotates repeatedly to cut the sealing portion 32 pulled downwards while being rotated, and simultaneously with the suction transfer of the suction belt 432 described below. The bottom surface of the cut soup 30 is sequentially supplied to the lower side through the soup feed belt 456 of the soup feeder 450.

In addition, the contact portion which is connected to any one of the pair of polygonal rollers (336, 344) and presses the soup (30) which is moved to the lower side before the sealing portion 32 is cut by the suction pull unit 400 ( 360 is further provided.

The close contact portion 360 is formed by a belt 361 driven by the pulley 365 of the polygonal roller 344, a pressure roller 362 driven by the belt 361, and a pressure roller 362. It includes an adhesive brush 364 for pushing the soup 30 is cut and transported to the suction pull unit 400 to facilitate the adsorption.

The suction puller 400 is installed at the main body 4 and is connected to the belt member 414 and the driven pulley 422 driven by the power generating member 412 to drive the driven pulley 422. The air suction hole 434 is connected to the first belt feed roller 430 and integrally connected and driven, and the soup 30 driven by the first belt feed roller 430 and cut and transported by the cutting unit 300. An air adsorption belt 432 for adsorption and transport to the air; The air suction belt 432 is driven to the outside and includes an air suction member 440 provided with an air suction hole 436 to suck air into the air suction hole 434.

The air adsorption member 440 is rounded in an arc shape at the bottom surface, and the soup 30 cut through the air adsorption hole 434 formed in the adsorption belt 432 is vacuum-absorbed at the bottom of the air adsorption member 440. A plurality of air intake openings 43 communicating with the air adsorption holes 434 moving to be formed in the arc center direction.

The belt member 414 may further include a tension control member 416 for adjusting the tension by using the height of the roller in contact with the inner surface or the outer surface of the belt member 414.

The suction belt 432 may be further provided with a tension adjusting member 433 to adjust the tension by using a roller in contact with the suction belt 432.

The soup feeder 450 is moved in close contact with the lower side of the suction puller 400, and is sucked by the suction puller 400, and then sequentially and accurately supplies the soup to which the soup is cut by the cutter 340. .

The soup feed unit 150 is disposed to have a set distance from the first driven pulley 422 and is integrally connected to the second driven pulley 452 and the second driven pulley 452 wound and driven by the belt member 414. And the second belt feed roller 454 and the second belt feed roller 454 are rotated in an endless track by rotating in a direction opposite to the rotational direction of the first belt feed roller 430. And a soup feed belt 456 that closely moves the soup 30 at a speed corresponding to that of the suction belt 432 in a state of supporting the bottom of the soup to be sucked and transported to the 432.

The soup feed belt 456 of the soup feeder 450 is configured to be driven by receiving the power of the belt member 414 which is rotated by the power generating unit 412 which drives the suction belt 432, but separately if necessary. It is provided with a drive means of the suction pull unit 400 may be configured to separate the driving force.

The first belt feed roller 430 and the second belt feed roller 454 are equal in radius and circumferential distance so that the moving speeds of the adsorption belt 432 and the soup feed belt 456 facing each other are the same.

If the moving speeds of the suction belt 432 and the soup feed belt 456 are different from each other, frictional forces will be generated on the side of the soup 30 that is closely adhered or sucked and moved therebetween.

The bottom surface of the soup feed belt 456 is provided with a tension control roller 460 that can adjust the tension of the soup feed belt 456 by adjusting the height.

As such, the bottom surface of the soup 30 which is sucked and transported by the suction belt 432 is transported in a state in which the soup supply belt 456 is stably supported.

And, even if the suction belt 432 is wound upward in the first belt feed roller 430, the soup 30 is moved along the soup feed belt 456 to the auxiliary roller 458, and the soup feed belt (B) Since the 456 is wound downward from the auxiliary roller 458 and is freely dropped, it is accurately contained in the ramen 20 placed by the adsorption and transport member 12 transported along the conveyor 10, thereby increasing the drop accuracy.

Hereinafter, look at the configuration of the soup contact transport apparatus (A) according to an embodiment of the present invention applied to a high speed soup feeder.

Figure 3 is a perspective view of the feeding unit of the soup tight contact apparatus according to an embodiment of the present invention, Figure 4 is an enlarged perspective view of the driving tension portion of the feeding portion in Figure 3, Figure 5 is an enlarged perspective view of the driven tension portion of the feeding portion in Figure 3 6 is a perspective view of the width adjusting portion and the position adjusting portion according to an embodiment of the present invention, Figure 7 is an enlarged perspective view of the width adjusting portion and the position adjusting portion according to an embodiment of the present invention, Figure 8 is a view of the present invention Front view of the feeding unit according to an embodiment.

Soup contact transporting device (A) of the present invention can be applied to a variety of soup production apparatus as well as the high speed soup feeder presented in an embodiment in FIG.

Soup contact transport apparatus (A) according to an embodiment of the present invention, is installed in the main body portion 4, the power generating unit 210 for generating power; A power transmission unit 211 transmitting power of the power generation unit 210; And a feeding part 200 which is in close contact with the soup 30 which is connected to the sealing part 32 by the power transmitted from the power transmission part 211 and stably transported. Feeding unit 200, the main power supply unit 220 is installed in the main body portion 4 to receive the power by the power transmission unit 211 to drive the main supply belt 224; Installed to be spaced apart from the main feed belt 224, to transfer the soup 30 and the sealing unit 32 with the main feed belt 224 to the driven feed belt 254 driven by the power transmission unit 211. Driven supply unit 240; It includes a spacing adjuster 260 to adjust the close contact between the main feeder 220 and the driven feeder 240 to provide the optimum transport friction force to the soup 30 and the sealing portion (32).

The power generating unit 210 is preferably a motor or a servo motor.

The power transmission unit 211 includes a belt 212 for transmitting power by the power generation unit 210; Driven pulleys 217 and 218 engaged with the belt 212 to drive the first driving roller 222 and the first driven roller 242 in opposite directions, respectively; It includes a tension roller 214 having a tension adjusting member 216 for adjusting the tension of the belt (212).

The main feed belt 224 and the driven feed belt 254 is preferably a timing belt.

The main feeder 220 includes a first main roller 222 which is driven by the driven pulley 217 and drives the main feeder belt 224; A second main roller 226 installed spaced apart from the first main roller 222 and rotated by the main feeding belt 224; A pair of coarse plate 226 in which the first and second coarse rollers 222 and 226 are installed; The moving plate 226 is provided with a moving tension unit 230 for adjusting the tension of the moving feed belt 224.

And, the tension tension unit 230, and the tension roller 232 to provide a tension to the coarse feed belt 224; A guide hole 233 formed in the pivot plate 226 to guide the roller shaft 234 rotatably supporting the tension roller 232; An operation member 238 for pressing the roller shaft 234 to move in the guide hole 233; The operating member 238 includes a fixture 236 fixed to the driving plate 226 to be screwed and moved.

The driven supply unit 240 is driven by the driven pulley 218 and is spaced apart from the first driven roller 242 and the first driven roller 242 that drives the driven supply belt 254. A pair of driven plates 244 on which the second driven roller 252 rotated by the belt 254, the first and second driven rollers 242, 252 are installed, and the driven plate 244 are provided. And a driven roller 253 for driving the driven supply belt 254 and a driven tension unit 250 installed in the second driven roller to provide tension to the driven supply belt 254.

The driven tension unit 250 may include a roller shaft 251 for rotatably supporting the second driven roller 252 to provide tension, and a guide hole formed in the driven plate 244 to guide the roller shaft 251. 249, an actuating member 246 that presses the roller shaft 251 to move in the guide hole 249, and a fixture 248 fixed to the driven plate 244 so that the actuating member 246 is screwed and moved. It characterized by including).

Guide holes 233 and 249 are formed in an open state to one side.

The actuating members 238 and 246 are further provided with position fixing members 237 and 247 to be screwed and tightly adhered to the fixing bodies 236 and 248. Position fixing member 237, 247 is a nut, it is preferably fastened to the operating member 238, 246, which is a screw member to control the movement.

The gap adjusting unit 260 may include a cylinder 262 provided on one side of the driving plate 226 and the driven plate 244, a fixing member 266 fixed to the shaft 264 of the cylinder 262, The screw adjusting shaft 265 is screwed to the fixing member 266 to adjust the spacing, one end is fixed to the end of the screw adjusting shaft 265, the other end of the driving plate 226 and the driven plate 244 The first driven roller 217 is provided on the first driven roller 217 so that the driven supply unit 240 is rotated by the spring 268 that is caught by the hook portion 269 fixed to the other side and provides the elastic force and the cylinder 262 is pulled. The rotating shaft 241 is included.

The driven supply unit 249 further includes a rotation preventing unit 202 to limit the range of rotation when rotating around the rotation shaft 241.

The anti-rotation unit 202 includes an anti-rotation protrusion 208 which rotates together according to the rotation of the rotation shaft 241; It characterized in that it comprises a rotation preventing member 204 for guiding the rotation of the anti-rotation protrusion 208, and forming a rotation preventing hole 206 to limit the rotation.

The feeding part 200 further includes a width adjusting part 270 to adjust the width of the soup 30 continuously supplied by the sealing part 32.

The width adjusting part 270 is fixed to the main body 4, the support 274 in which the adjusting slot 276 is formed, and is coupled to be moved left and right in the adjusting slot 276 so that the soup 30 and the sealing portion ( 32, guide rollers 272 for guiding both sides of the guide roller, characterized in that it comprises a fastening member 277 is tightened or released to adjust the position of the guide roller (272).

In the inlet or outlet portion of the feeding unit 220, the mark detection sensor for controlling the time to cut the sealing portion 32 in the cutting unit 300 by detecting the mark portion 34 displayed on the sealing portion 32 The unit 280 is further provided.

The mark sensor detecting unit 280 slides the mark detecting sensor 278 for detecting the mark 34, the support 281 supporting the mark detecting sensor 278, and the first support 281. A first fixing body 282 movably coupled, a connecting rod 284 having one end coupled to the first fixing body 282 so as to slide in a vertical direction of the support 281, and the other end of the connecting rod 284 slides. The second fixing body 286 that is movably coupled to the second fixing body 286, the second fixing body 286 is installed in the main body portion 4 so that the slide in the vertical direction to the connecting rod 284 A plurality of fastening members fastened to the first and second fixing bodies 282 and 286 to press or separate the fixing member 288, the support 281, the connecting rod 284, and the fixing member 288. 290) characterized in that it comprises a.

The sensor 171 of the thickness detecting unit 100 is a sensor for detecting the thickness of the soup 30 at the time when the soup 30 enters, and the mark detecting sensor 278 is the mark unit 34 displayed on the sealing unit 32. As the sensor for detecting the, when the seal portion 30 of the soup 30 has a mark portion 34, the sensor 171 of the thickness detecting unit 100 is not used, the mark detection sensor 278 is operated The cutting position of the sealing portion 32 is controlled.

That is, the sensor 171 of the thickness detecting unit 100 operates only when there is no mark 34 in the sealing unit 32. Of course, since such operation is not determined, the user may optionally select and use the mark 34 regardless of the presence or absence of the mark 34.

In all of these operations, since the user inputs a signal to the operation unit 6 in advance, the pull roller 328 and the polygon roller 336 are respectively driven so that the cutter 340 of the cutting unit 300 is positioned at the sealing unit 32. The power generating members 320 and 330 are controlled using detection signals selected from the sensor 171 and the mark detection sensor 278 of the thickness detecting unit 100.

Hereinafter, on the basis of the accompanying drawings to look at the action of the high speed soup feeder having a soup contact transport apparatus according to an embodiment of the present invention.

As shown in FIG. 1 and FIG. 11, first, the soup 30 connected by the sealing part 32 is transferred to the supply roller 50 through the entry roller 40.

The supply roller 50 has a separation prevention jaw 52 for preventing the separation of the soup 30 is formed, the separation is prevented soup 30 is moved to the thickness detection unit (100).

As shown in FIG. 2, the use state of the thickness detector 100 will be described.

Since the soup 30 and the sealing part 32 alternately move the first and second moving rollers 124 and 134 of the thickness detecting part 100, the guide member 131 moves to the left and right with respect to the moving frame 120. The guide member 131 spread by the spring 192 fixed to the fixing protrusion 194 and the fixing frame 110 is returned to its original position.

On the other hand, when the soup 30 and the sealing part 32 alternately moves while the portion of the soup that does not contain the soup 30 is generated, the blood capsule sensor 136 detects that there is no thickness of the soup 30 The controller generates an alarm signal or stops the high speed soup feeder in the large controller provided in the operation unit 6.

If the soup without the soup 30 is supplied to the ramen 20 as it is, consumers can buy the ramen without soup, there is a fear that mass production of defective products can be solved.

When the soup 30 passes through the first and second rollers 124 and 134, the soup and the sealing part 32 pass through the third and fourth rollers 146 and 154. The second support 140, 150 is opened based on the rotation shaft 142, and when the sealing part 32 passes, the first and second support 140, 150 are hardly opened.

That is, when the soup 30 passes through the third and fourth rollers 146 and 154, the first and second support members 140 and 150 are opened due to the thickness of the soup 30. The sensor 171 installed on the second support 140 or 150 detects the moving state of the sensing protrusion 182 to detect a state where the soup 30 passes.

At this time, when the thickness of the soup 30 is detected, the power generating member 330 for driving the polygonal roller 366 to match the cutting position of the sealing portion 32 of the cutter 340 installed in the subsequent polygonal roller 366 Will be controlled. The thickness sensing unit 100 is to be used in advance to set the presence or absence of the mark portion 34 to the operation unit 6 in advance before the work to be used only when there is no mark portion 34 in the sealing portion (32).

And, if you want to adjust the height of the first, second, third, fourth roller 124, 134, 146, 154 to rotate the height adjustment handle 184 in the desired direction, integrally coupled The screw shaft 191 is rotated from the protrusion 112 so that the moving frame 120 coupled with the screw portion 211 moves up and down with respect to the fixed frame 110 to adjust the height.

Then, the soup 30 and the sealing part 32 which passed the thickness detection part 100 are conveyed below by the soup | stick contact conveyance apparatus A. FIG.

On the other hand, let's look at the state of use of the soup contact transport apparatus (A) according to the present invention.

As shown in Figures 3 to 8, the soup 30 and the sealing portion 32 is transferred to the lower side by the main feed belt 224 and the driven feed belt 254.

The driven supply belt 224 and the driven supply belt 254 drive the belt 212 by the power generating unit 210 to rotate the driven pulleys 218 and 219, and the driven pulleys 218 and 219. The first driving roller 222 and the first driven roller 242 integrally fixed thereto are driven by rotating in opposite directions.

Meanwhile, the second main roller 228 and the second driven roller 252 installed spaced downward from the first main roller 222 and the first driven roller 242 rotate together, and the main feed belt 224 and the driven belt are rotated together. The supply belt 254 is driven.

The cylinder 262 of the gap adjusting part 260 is installed in the coarse plates 226 on both sides of the coarse feed belt 224, and the shaft 264 of the cylinder 262 is fixed to the fixing member 266. The spring 268 connected to the fixing member 266 is installed to be hooked to the hook portion 269 of the driven plate 244 provided on both sides of the driven supply belt 254.

That is, when the shaft 264 of the cylinder 264 is pulled by operating, the spring 268 is also pulled together while the driven supply unit 240 is pulled relative to the pivot shaft 241, and the main feed belt 224 The soup 30 and the sealing part 32 moving between the driven supply belts 254 are brought into close contact with each other.

When the thickness of the soup 30 moving between the main feed belt 224 and the driven feed belt 254 is slightly thick, the spring 30 is slightly elastically opened or pulled and the soup 30 and the sealing portion 32 The thickness error due to the movement of) is corrected.

On the other hand, if you want to adjust the tension of the coarse feed belt 224, tighten or loosen the operation member 238 screwed to the fixture 236 installed on the side of the two pivoting plate 226, the fixture 226 ) Is moved forward and backward, and the end of the operation member 238 is to push or pull the roller shaft 234 supporting the tension roller 232 to adjust the tension of the tension roller 232 .

And, if you want to adjust the tension of the driven supply belt 234, by tightening or loosening the operating member 246 screwed to the fixture 248 installed on the lower side of the two driven plate 244, the fixture 248 ) Is moved forward and backward, and the end of the operating member 246 pushes or pulls the roller shaft 251 supporting the second driven roller 252, so that the tension of the second driven roller 252 Will be adjusted.

Since actuating members 238 and 246 tighten the position fixing member 247 serving as a nut, the actuating members 238 and 246 fix the positions of the fixing members 226 and 248.

6 and 7, guide rollers for guiding the width portions of the soup 30 and the sealing portion 32 are provided at the lower portions of the second driving roller 228 and the second driven roller 252. 272) is installed, the pair of guide rollers 272 to loosen the tightening member (277) to move to the adjustment slot 276 of the support 274 to adjust the spacing and then tighten the tightening member (277) again Adjust the interval.

On the other hand, the mark detection sensor 278 is installed between the pair of guide rollers 272, if there is a mark portion 34 in the sealing portion 32, it detects and follows the pull roller 329 and the multiple rollers By controlling the power generating members 320 and 330 driving the 336, respectively, the position of the cutter 340 installed in the polygonal roller 336 is controlled to be accurately positioned in the middle of the sealing portion 32.

The mark detection sensor 278 of the mark detection sensor unit 280 performs the same role as the sensor 171 of the thickness detection unit 100, and the mark detection when the mark unit 34 is present in the sealing part 32. When the sensor 278 is cited, and the mark part 34 is not present, the sensor 171 of the thickness detecting part 100 is used.

Whether the mark sensor 278 and the sensor 171 of the thickness detecting part 100 are used by the operator visually determines whether the mark part 34 is present in the sealing part 32 of the soup 30, Since a signal is input to the operation part 6, it can select and use it.

The mark detection sensor 278 has a change in the width of the soup 30 and the sealing part 32 due to the fluctuations in the width of the soup 30 and the sealing part 32. It should be moved back and forth, left and right.

On the other hand, look at the movement state of the mark detection sensor 278.

First, looking at the left and right movement of the mark detection sensor 278, by releasing the fastening member 290 provided on the lower side of the first fixing body 282 for fixing the support 281 to move the support 281 to the left and right Alternatively, after releasing the fastening member 290 fastened to the second fixing body 286 to move the second fixing body 286 to the left and right to adjust the left and right positions of the mark detection sensor 278 Tighten the loosened fastening member 290 again to adjust the left and right positions of the mark detection sensor 278.

Then, looking at the forward and backward movement of the mark detection sensor 278, at least one of the fastening member 290 fastened to the upper side of the first fixing body 282 and the lower side of the second fixing body 286 by releasing the connecting rod ( 284) is selectively moved from the first and second fixing bodies 282 and 286 to adjust the front and rear positions of the mark detection sensor 278, and then tightens the loosened fastening member 290 again. The front and rear positions of the sensor 278 are adjusted.

Meanwhile, as shown in FIG. 9, the use state of the cutting part 300 will be described.

The soup 30 and the sealing part 32 which passed the mark detection sensor 278 are the drive pulley 324 which is the power transmission member 322 driven by the power generating member 322, the belt 325 and the driven pulley ( 326 drives the pull rollers 328 and 329 to pull and transport the side portions of the sealing portion 32.

In order to provide the frictional force of the pull rollers 328 and 329, the surface is provided with a knurling protrusion.

The soup 30 and the sealing part 32 which are moved by the pulling force of the pulling rollers 328 and 329 are the drive gear 333 and the first driven gear 334 driven by the power generating part 330. And the multiple rollers 336 and 344 are rotated while facing each other by the second driven gear 342 and support the cutter 340 and the cutter 340 respectively installed in the three protruding grooves 338 and 345. As the cutter support member 346 is rotated, three sealing parts 32 are cut in one rotation.

That is, in the related art, since the cutter operates by cutting once every day, cutting is delayed, whereas the present invention is made in a rotating manner, and thus cutting is performed at a high speed according to the rotational speed.

Since the cutter 340 uses a wave shaped cutter formed as a sawtooth, the cutting portion of the sealing portion 32 is cut into a saw blade shape so that when the user opens the soup 30, the saw blade groove portion is cut off. The soup 30 is then cut well to provide convenience to the consumer.

And, the soup 30 just before the cutting is made of the suction belt 432 by the adhesive brush 364 of the contact roller 362 rotated by the pulley 365 and the belt 261 of the polygon roller 344. It adheres well to the surface and serves to help the sealing portion 32 to be pulled tight. Of course, the soup 30 made of the cutting of the sealing portion 32 also serves to help the vacuum adsorption.

As shown in FIGS. 10 and 11, the soup 360 closely contacted by the contact brush 364 is formed by the adsorption hole of the adsorption belt 432 by the air sucked into the inlet 436 of the adsorption member 440. It is adsorbed by 434 and is transported downward in accordance with the movement of the adsorption belt 432.

The first belt transfer roller 430 driving the suction belt 432 is rotated by the power of the power generating member 412 and the driven pulley 422 which is rotated by the power transmission of the belt member 414. do.

On the other hand, the bottom surface of the suction puller 400 is provided with a soup conveying portion 450, in a state that the soup supply belt 456 supports the bottom surface of the soup 432 to be transported to the lower side by the suction belt 432. It feeds at the same speed as the suction belt 432.

Then, when the soup feed belt 456 is rotated and the soup 30 is no longer supported by the auxiliary belt 458, the soup 30 is no longer supported, so that the soup falls down by its own weight and is transported along the conveyor 10. The ramen 20 placed in the member 12 is placed and transferred to a subsequent packaging process.

The soup feed belt 456 of the soup feeder 450 is configured to be driven by receiving the power of the belt member 414 which is rotated by the power generating unit 412 which drives the suction belt 432, but separately if necessary. It is provided with a drive means of the suction pull unit 400 may be configured to separate the driving force.

By repeatedly passing through this process, the soup 30 and the sealing part 32 are continuously supplied, and the sealing part 32 is cut at high speed to supply the soup 30 at high speed, thereby improving productivity unlike the conventional art.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is merely exemplary, and those skilled in the art to which the art belongs can make various modifications and other equivalent embodiments therefrom. I will understand.

Therefore, the true technical protection scope of the present invention will be defined by the claims below.

A: Soup close contact device 4: Body part
20: Ramen 30: Soup
32: sealing part 34: mark part
100: thickness detection unit 110: fixed frame
112: protrusion 120: moving frame
124: first roller 130: blood detection unit
134: second roller 136: blood detection sensor
140: first support 142: rotation axis
146: third roller 150: second support
154: fourth roller 160: elastic portion
162: spring 164: support member
165: support plate 170: sensor
200: feeding part 202: anti-rotation part
204: anti-rotation member 210: power generating unit
211: power transmission unit 220: main power supply unit
224: copper supply belt 226: copper plate
232: tension roller 240: driven supply
244: driven plate 254: driven supply belt
250: main tension part 260: spacing control part
270: driven tension unit 280: position adjustment unit
281 support 282,286 first and second support
300: cutting unit 310: fixed frame
320,330: Power generating member 322,332: Power transmitting member
328,329: Moving roller 336,344: Multi-angle roller
360: close contact 361: belt
262: adhesion roller 400: suction pull
414: belt member 430: first belt feed roller
440: adsorption member 450: soup transfer unit
4454: second belt feed roller 456: soup feed belt
458: auxiliary roller 460: tension control roller

Claims (11)

A power generation unit installed in the main body and generating power;
A power transmission unit for transmitting power of the power generation unit; And
It includes a feeding unit for feeding a plurality of soups connected to the sealing portion in close contact on both sides by the power received from the power transmission unit,
The feeding part
A main fuel supply unit installed in the main body to drive the main power supply belt by receiving the power of the power transmission unit;
A driven supply part spaced apart from the main feed supply belt and configured to transfer the soup and the sealing part together with the main supply belt to the driven supply belt driven by the power transmission unit;
And a spacing controller for controlling the close contact between the main feed part and the driven supply part to provide an optimum conveying friction force to the soup and the sealing part.
The method of claim 1,
The power generating unit is a soup contact transport apparatus, characterized in that the motor or servo motor.
The method of claim 1,
The power transmission unit, and the belt for transmitting power by the power generating unit;
A driven pulley engaged with the belt to drive a first driving roller and a first driven roller, respectively;
Soup contact and transport apparatus comprising a tension roller having a tension adjusting member for adjusting the tension of the belt.
The method of claim 1,
The main supply unit, the first main roller is driven by the driven pulley, and drives the main supply belt;
A second main roller installed spaced apart from the first main roller and rotated by the main feeding belt;
A pair of driving plates on which the first and second driving rollers are installed;
Soup contact transport apparatus characterized in that it comprises a coarse tension portion provided on the coarse plate to adjust the tension of the coarse feed belt.
The method of claim 4, wherein
The main tension portion, and the tension roller for providing a tension to the main supply belt;
A guide hole formed in the main plate to guide the roller shaft rotatably supporting the tension roller;
An operation member for urging the roller shaft to move in the guide hole;
And a fixing body fixed to the main plate so that the operating member is screwed and moved.
The method of claim 1,
The driven supply unit includes: a first driven roller driven by the driven pulley and driving the driven supply belt;
A second driven roller installed spaced apart from the first driven roller and rotated by the driven supply belt;
A pair of driven plates on which the first and second driven rollers are installed;
A driven roller provided at the driven plate to drive a driven supply belt;
And a driven tension unit installed at the second driven roller to provide tension to the driven supply belt.
The method according to claim 6,
The driven tension unit may include: a roller shaft supporting the second driven roller rotatably to provide tension;
A guide hole formed in the driven plate to guide the roller shaft;
An operation member for urging the roller shaft to move in the guide hole;
And a fixed body fixed to the driven plate so that the operating member is screwed and moved.
The method of claim 1,
The gap adjusting unit, the cylinder is installed on any one side of the driven plate and the driven plate;
A fixing member fixed to the shaft of the cylinder;
A screw adjusting shaft screwed to the fixing member to adjust a gap;
A spring having one end fixed to an end of the screw adjustment shaft, the other end being hooked to a hook portion provided on any other side of the driving plate and the driven plate to provide an elastic force;
And a rotating shaft provided in the first driven roller to rotate the driven supply part by the pulling action of the cylinder.
The method of claim 1,
The feeding portion is further provided with a width adjusting portion to adjust the width of the soup continuously supplied by the sealing portion,
The width adjusting unit is fixed to the main body, the support is formed with a slot for adjustment;
A guide roller coupled to the adjustment slot to move left and right to guide both sides of the soup and the sealing portion;
Soup contact transport apparatus comprising a tightening member that is tightened or released to adjust the position of the guide roller.
The method according to claim 1 or 9,
And a mark detection sensor part further configured to detect a mark part displayed on the sealing part and control a time for cutting the sealing part in the cutting part in the inlet or discharge part of the feeding part.
The method of claim 10,
The mark sensor detection unit, a mark detection sensor for detecting the mark;
A support for supporting the mark detection sensor;
A first fixing body supporting the first support and slidably coupled to the first support;
A connecting rod having one end coupled to the first fixing body so as to slide in a vertical direction of the support body;
A second fixing body to which the other end of the connecting rod is slidably coupled;
A fixing member coupled to the second fixing body and installed on the main body such that the second fixing body slides in a direction perpendicular to the connecting rod;
And a plurality of fastening members fastened to the first and second fixing bodies to press or separate the support, the connecting rod, and the fixing member.

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