KR20170129407A - laver drying machine - Google Patents

Abstract

The present invention relates to a laver drying machine in which a main transfer chain transferring a laver drying screen hanger while being driven in a first unit intermittent transfer cycle for repeatedly moving and stopping by a main driving part is installed on a frame to be circulated in an endless track. The laver drying machine comprises: a sub-transfer chain installed in a frame to be circulated to a molding position of a molding part along an independent circulation track separated from a transfer track of a main transfer chain; a sub-driving part for driving the sub-transfer chain to perform an intermittent transfer motion while repeatedly moving and stopping in a second unit intermittent transfer cycle to which a second movement time and a second stop time, which are differently set from a first movement time and a first stop time applied to the first unit intermittent transfer cycle of the main transfer chain, are applied; and an track switching part for switching the track from the main transfer chain to the sub-transfer chain to transfer a plurality of laver drying screen hangers to the molding part, and switching the transfer track of the laver drying screen hangers to be transferred by the main transfer chain when reaching a return position after passing through the molding part. The first stop time applied to the first unit intermittent transfer cycle is set shorter than the second stop time applied to the second unit intermittent transfer cycle, the first movement time of the main transfer chain is applied to move the laver drying screen hangers, and a second average transfer speed applied to the sub-transfer chain with respect to a first average transfer speed, which is the average transfer speed of the main transfer chain, is set such that the laver drying screen hangers are returned to the return position of the main transfer chain by the track switching part after being transferred to the sub-transfer chain.

Description

Laver drying machine}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a bleaching dryer, and more particularly, to a bleaching dryer capable of increasing a forming time of bleaching in a production cycle.

Generally, dried seaweed is prepared by slicing dried seaweed collected from a farm, mixing it with water, forming it thinly spread on the shell, drying it, and then separating the dried seaweed from the shell.

In recent years, Haitai dryers, which automate the production process of dried laver, have been used in order to reduce labor force and increase productivity.

Such a dryer is disclosed in Korean Registered Utility Model No. 20-0295361, Domestic Registered Utility Model No. 20-0255590, Domestic Patent No. 2003-0023222, Domestic Registered Utility Model No. 20-0277920, Domestic Registered Utility Model No. 20- 292229, and the like.

The above-described disposable dryers are adapted to move to a drying place after forming and dewatering, while conveying the drying hanger to the horizontal transportation chain for transporting to an endless track in an intermittent moving manner in which the drying hanger is pulled and stopped repeatedly. Is determined by the feed rate of the horizontal feed chain. However, when the feeding speed of the horizontal transfer chain is increased to increase the production speed of the steam, the time allocated to molding, dewatering and drying is reduced, resulting in defective molding, and a problem of deteriorating the quality of the product do. Further, in order to extend the shortage of dewatering and drying time, there arises a problem that the equipment of the dryer must be expanded in accordance with the increase of the conveying speed of the horizontal conveying chain.

The inventor of the present invention has proposed, in Korean Patent No. 10-0775673, a Haitai dryer capable of extending the stop time applied to the improvement of the above-mentioned problems.

On the other hand, there is a continuing need for a method for increasing the quality of the drying steam and the durability of the apparatus while extending the time period applicable to the molding.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a rinsing dryer capable of increasing the quality of the drying steam and the durability of the equipment while extending the time allocated to molding.

In order to achieve the above-mentioned object, the rinse-ladle dryer according to the present invention is driven by a first unit intermittent transfer cycle for repeating movement and stop by a main drive unit, and a main transfer chain for transferring an open- And a drying unit for drying the dehydrated sea-bed, a drying unit for drying the dehydrated sea-bed, a drying unit for drying the dehydrated sea-bed, A sub transferring chain installed on the frame to circulate to a forming position of the forming unit along an independent circulating track separated from a transferring track of the main transferring chain; A second unit intermittent feeding cycle to which a second moving time and a second stopping time different from the first moving time and the first stopping time applied to the first unit intermittent feeding cycle of the main transport chain are applied, A sub-driving unit for driving the sub-transporting chain so as to perform intermittent feeding motion; A plurality of said hangers are adapted to switch the trajectory from said main transport chain to said sub transport chain to be transported to said forming section and to be transported by said main transport chain upon reaching a return position after passing through said forming section, Wherein the first stop time applied to the first unit intermittent transfer cycle is set to be shorter than the second stop time applied to the second unit intermittent transfer cycle, Wherein the first moving time period applied to the first unit intermittent feeding cycle of the main transport chain is applied so that a plurality of rack hanger can be moved, and the first average transport speed of the main transport chain, The second average conveying speed applied to the conveying chain is controlled by the orbiting switching part after the developing rack is transferred to the sub conveying chain, Is set to be returned to the return position of the main transport chain.

Wherein the first stop time applied to the main transport chain is 1/3 to 1/6 of the first unit intermittent transport cycle and the second stop time of the sub transport chain is one / 2.

More preferably, the first unit intermittent feed cycle and the second unit intermittent feed cycle are applied at the same time, and the first average feed rate and the second average feed rate are applied in the same manner.

According to an aspect of the present invention, the main drive unit includes a main drive index connected to a drive shaft of a drive sprocket for driving the main transport chain and having at least one first interference piece along a circumferential direction; Is rotated by the power transmitted from the main motor through the reduction gear, and interferes with the first interference piece for a time corresponding to the first transfer time in the first unit intermittent transfer cycle along the circumferential direction to rotate the main drive index Driving sub-drive sprocket for driving the sub-transport chain and having at least one second interference piece formed along a circumferential direction thereof; And is configured to rotate by the power transmitted from the main motor and to rotate the sub-drive index by interfering with the second interference piece for a time corresponding to a second transfer time in the second unit intermittent transfer cycle along the circumferential direction And a second cam portion.

As described above, according to the dryer of the present invention, the molding time in the Kim production cycle is increased to reduce the defective molding, and the hanging rack transferred by the main horizontal transfer chain after molding has a time allocated to the transfer section The conveying speed can be lowered, thereby improving the quality of the dried product and the durability of the equipment.

FIG. 1 is a schematic view of a bleach dryer according to the present invention,
FIG. 2 is an enlarged perspective view of the intermittent drive section applied to the main drive section of FIG. 1,
Fig. 3 is a front view of the intermittently driven portion of Fig. 2,
FIG. 4 is a graph showing a comparison of stopping and moving times applied to the intermittent driving of the main driver and the sub-driver of FIG. 1. FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a bleach dryer according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic view of a bleach dryer according to the present invention; FIG.

1, the bleed dryer 100 includes a frame 110, a forming unit 120, a dewatering unit 130, a drying unit 140, a separating unit 150, a track switching unit 160, (210) and a sub-driver (220).

The forming part 120 is formed by feeding a deflocculant that has been cut into an open shoe (not shown) mounted on the opening hanger 102 and loosened in water.

The forming unit 120 is installed such that the first molding machine 121 and the second molding machine 123 are spaced apart from each other along the conveying direction of the sub conveying chain 180.

The first and second molding machines 121 and 123 can be simultaneously engaged and molded. Each of the first and second molding machines 121 and 123 includes a storage passage capable of discharging the defrosted body through the air outlet by opening and closing a valve, a rectangular shaped molding plate lifted and lowered from the lower portion of the storage cylinder, And a rubber bucket is provided. The cockpit hook 102 is conveyed along the forming line between the rubber bucket and the forming plate.

Each of the first molding machine 121 and the second molding machine 123 is provided with a plurality of molding units 122 corresponding to the number of openings mounted on the hanging hanger 102 along a direction perpendicular to the conveying direction of the main horizontal conveyance chain 170 Are arrayed.

The dewatering unit 130 is configured to feed the sub conveyance chain 180 so that the dewatering unit that is formed on the tray hanger 102 conveyed by the sub conveyance chain 180 via the forming unit 120 can be unloaded. Is provided after the forming part 120 on the basis of the direction of the forming part 120.

The dewatering unit 130 has a dewatering unit 131 composed of a lower dewatering plate 131a and an upper dewatering plate 131b provided so as to face each other so as to be separated from each other in mutual contact with each other along the transport direction of the subhorizontal transport chain 180 There are two spaced apart.

It is needless to say that the number of application of the dewatering unit 131 may be different from the illustrated example.

The drying unit 140 receives the dryer hanger 102 mounted on the main transfer chain 170 via the dewatering unit 130 and can dry the dewatering by the hot air.

The separating unit 150 is capable of separating the dried seaweed from the open space mounted on the hanging hanger 102 which has entered the conveying path of the main conveyance chain 170 via the drying unit 140.

A switching device 190 is provided between the separating part 150 and the forming part 120 disposed on the conveying track of the main conveying chain 170 so that the opening hook 102 can be reversed.

The main transport chain 170 is installed on the frame 110 so as to circulate in an endless track so as to be able to transport the hangar hanger 102.

The main transfer chain 170 is configured to circulate the hung hanger lowered from the dewatering unit 130 by the orbit switching unit 160 through the drying unit 140, the separation unit 150, and the deployment switching unit 190 .

U-shaped interference holes 172 having receiving grooves are coupled to the chain links of the main transport chain 170 at predetermined intervals so that the both end portions of the mounting bracket 102 can enter and retract at a certain depth.

The sub conveyance chain 180 is installed to be able to circulate along an independent circulation orbit separate from the conveyance trajectory of the main horizontal conveyance chain 170.

The feeding trajectory of the sub conveyance chain 180 can orbit the forming position of the forming part 120 and the dehydrating position of the dehydrating part 130.

The track switching unit 160 switches the trajectory from the main transport chain 170 to the sub transport chain 180 so that a plurality of the hangers 102 are simultaneously transported to the forming unit 120, The feeding trajectory of the hangar hanger 102 is switched so as to be conveyed by the main conveyance chain 170 when it reaches the return position after passing through the dewatering section 130.

The track switching unit 160 includes an elevator 162 for simultaneously raising and lowering two adjacent hanging hangers 102 into orbit of the sub conveyance chain 180 and two hangers 102 via a dewatering unit 130. [ And a descender 262 that descends simultaneously into the orbit of the main conveyance transfer chain 170. [

Reference numeral 165 denotes a conveying guide rail, and reference numeral 261 denotes an auxiliary supporting unit.

As described above, the detailed structure of the forming unit 120, the dewatering unit 130, the drying unit 140, the separating unit 150, and the orbit switching unit 160 is the same as that of the above-mentioned Korean Patent No. 10-0775673 And detailed description thereof will be omitted.

The main driving unit 210 drives the main transport chain 170 in a first unit intermittent transport cycle for repeating moving and stopping.

That is, the first unit intermittent transporting cycle of the main transport chain 170 includes a first transport time at which the main transport chain 170 is moved and a first stop time at which the main transport chain 170 stops.

The sub-driving unit 220 is connected to the sub-driving unit 220, the sub-driving unit 220, and the sub-driving unit 220. The sub-driving unit 220 includes a first unit movement period and a second movement period, The sub conveyance chain 180 is driven so as to perform intermittent conveyance movement while repeating movement and stop in the conveyance period.

Here, the first stop time to be applied to the first unit intermittent feed cycle is set to be shorter than the second stop time applied to the second unit intermittent feed cycle, and the first average feed, which is the average feed speed of the main feed chain 170, The second average conveying speed applied to the sub conveying chain 180 with respect to the speed is determined by the return of the main conveying chain 170 by the orbit switching portion 160 after the developing hook 102 is conveyed to the sub conveying chain 180 Position to be returned to.

Here, the first average conveying speed of the main conveying chain 170 is a value obtained by dividing the distance that the main conveying chain 170 has moved during the first unit intermittent conveying period, and the second average conveying speed of the sub conveying chain 180 Is the value obtained by dividing the distance traveled by the sub-transport chain 180 during the second unit intermittent transport period.

Preferably, the first stop time applied to the main transfer chain 170 is applied to 1/3 to 1/6 of the first unit intermittent transfer cycle.

Also, the second stop time of the sub-transport chain 180 is applied as a half of the second unit intermittent feed cycle.

In addition, the first unit intermittent transfer cycle and the second unit intermittent transfer cycle have the same time, and the first average transfer rate and the second average transfer rate are applied equally.

The main driver 210 applied in consideration of these conditions will be described with reference to FIGS. 2 to 4. FIG. 4, the dotted line is the intermittent drive pattern of the main transport chain 170, and the solid line is the drive pattern for the sub transport chain 180. [

The main drive unit 210 intermittently receives rotational power generated in the main motor 241 and can intermittently rotate the drive sprocket 212 that drives the main transfer chain 170. [

The main drive unit 210 includes a main drive index 214 connected to the drive shaft of the drive sprocket 212 through a power transmission member and having at least one first interference piece 214a formed along the circumferential direction, The first interference piece 214a is rotated by the power transmitted through the reduction gear 243 and interfered with the first interference piece 214a for a time corresponding to the first transfer time a1 in the first unit intermittent transfer cycle T1 along the circumferential direction Thereby forming the first cam portion 217 formed to be able to rotate the main drive index 214. [

The main driving index 214 includes a first index portion 215 having six first interference pieces 214a spaced apart from each other at equal angles along the circumferential direction and a second index piece 215 having a first interference piece And the second index portion 216 in which six first interference pieces 214a are equally spaced from each other at an angle offset from the arrangement direction of the first interference pieces 214a.

The first cam portion 217 is formed with an arc-shaped portion 218a (219a) formed to protrude with respect to a certain angle region along the circumferential direction so as to enter and interfere with the space between the first interference pieces 214a 1 and the second cams 218 and 219 are disposed so as to be able to enter the first and second index portions 215 and 216 in an opposed manner.

The main driving part 210 rotates the rotation axis 217a of the first cam part 217 by an angle of 270 degrees with respect to the main index 214 when the rotation axis 217a rotates 360 degrees,

The sub-driving unit 220 includes a sub-driving index 224 connected to the driving shaft of the sub-driving sprocket 222 for driving the sub-transport chain 180 and having six second interference pieces 224a formed along the circumferential direction, , Interferes with the second interference piece 224a for a time corresponding to the second transfer time a2 in the second unit intermittent transfer cycle T2 along the circumferential direction by the power transmitted from the main motor 241 And a second cam portion 227 formed so as to rotate the sub-drive index 224.

The second cam portion 227 rotates the rotation axis 217a of the second cam portion 227 by 180 degrees with respect to the sub-drive index 214 when the rotation shaft 217a rotates 360 degrees, .

The second cam portion 227 may be formed by adjusting the occupied area to 180 degrees when rotating 360 degrees with respect to the sub-driving index 214 of the above-described entrance arc portion.

The angle by which the first cam portion 217 rotates the rotation shaft 217a and the angle by which the second cam portion 227 rotates the rotation shaft 217a may be applied corresponding to the stop and transfer time to be applied.

The main transport chain 170 is intermittently transported to the first intermittent transport cycle T1 having the first transport time a1 and the first stop time b1 by the main drive unit 210 and the sub drive unit 220 , The sub conveyance chain 180 is intermittently conveyed to the first intermittent conveyance period T2 having the second conveyance time a2 and the second rest time b2.

In addition, the main transport chain 170 is constructed so that the two hangers 102 can be moved during the first transport time a1.

Here, when the first and second intermittent transfer cycles T1 and T2 are equally applied for 4 seconds, the first transfer time a1 is 3 seconds. The first stop time b1 is 1 second and the second transfer time a2. And the second stop time b2 may be set to be 2 seconds.

In this case, the sub-transport chain 180 advances for two arcs hangers 102 for two seconds.

According to this driving mechanism, when the first intermittent transporting cycle T1 is 4 seconds, the main transporting chain 170 repeatedly advances 3 seconds, 1 second, 3 seconds, and 1 second. Further, the second intermittent transporting cycle is 4 seconds, and the sub transporting chain 180 repeats 2 seconds forward, 2 seconds stop, 2 seconds forward, and 2 seconds stop.

In this case, the two drive hooks 102 are moved from the main transfer chain 170 to the subordinate conveying chain 180 by the elevator 162 of the track switching unit 160 for one second, which is the first stopping time b1, Since the two transfer hooks 102 are transferred to the main transfer chain 170 for the remaining three seconds, the instantaneous transfer speed of the main transfer chain 170 is lower than the case of applying the two-second transfer time do.

Meanwhile, since the sub conveyance chain 180 performs the forming process for the two hangers 102 during the second stop time b2 for 2 seconds, it is possible to secure the time required for the forming, it is only necessary to transfer the hanging hanger 102 faster than the instantaneous transfer speed of the main transfer chain 170 for 2 seconds (a2).

Here, the reduction ratio between the main drive unit 210 and the sub-drive unit 220 may be determined so that the average transfer speed of the main transfer chain 170 and the sub-transfer chain 180 have an average transfer speed. Therefore, when the average of the first and second intermittent transport cycles is 4 seconds, the main transport chain 170 and the sub transport chain 180 transport the same distance.

It is needless to say that a sub-drive source for driving the sub-transport chain 180 may be provided separately from the main motor 241, unlike the illustrated example.

This bleed dryer 100 can sufficiently secure the time required for molding by the forming unit 120 and can transfer the lowering of the instantaneous feeding speed to the embankment after completion of molding and dehydration, It is possible to further suppress the quality of the produced steels.

110: frame 120: forming part
130: Dewatering unit 140: Drying unit
150: separator 160:
170: Main transport chain 180: Sub transport chain

Claims (5)

A main transferring chain which is driven by a first unit intermittent transferring cycle for repeatedly moving and stopping by a main driving unit and is provided so as to be circulated in an endless track on a frame for transferring a hanging hanger, And a drying unit for drying the dehydrated seawater, the drying unit comprising: a drying unit for drying the dehydrated seawater;
A sub transferring chain provided on the frame to circulate the molding section along a separate circulation path separated from the transfer trajectory of the main transferring chain;
A second unit intermittent feeding cycle to which a second moving time and a second stopping time different from the first moving time and the first stopping time applied to the first unit intermittent feeding cycle of the main transport chain are applied, A sub-driving unit for driving the sub-transporting chain so as to perform intermittent feeding motion;
A plurality of said hangers are adapted to switch the trajectory from said main transport chain to said sub transport chain to be transported to said forming section and to be transported by said main transport chain upon reaching a return position after passing through said forming section, And a trajectory switching unit for switching the trajectory,
The first stop time to be applied to the first unit intermittent feed cycle is set to be shorter than the second stop time applied to the second unit intermittent feed cycle, and the first unit intermittent feed cycle The first moving time being applied is such that a plurality of hangers can be moved and a second average conveying speed applied to the sub conveying chain for a first average conveying speed which is an average conveying speed of the main conveying chain, And is returned to the return position of the main transport chain by the orbit switching portion after the hook is transferred to the sub transport chain. The rinsing drier according to claim 1, wherein the first stop time applied to the main transport chain is 1/3 to 1/6 of the first unit intermittent transport cycle. The rinse-laid dryer according to claim 2, wherein the second stop time of the sub transport chain is one-half of the second unit intermittent feed cycle. 4. The method of claim 3, wherein the first unit intermittent feed cycle and the second unit intermittent feed cycle are the same time, and wherein the first average feed rate and the second average feed rate are the same. dryer. 2. The apparatus of claim 1, wherein the main driver
A main drive index connected to a drive shaft of a drive sprocket for driving the main transport chain and having at least one first interference piece along a circumferential direction;
Is rotated by the power transmitted from the main motor through the reduction gear, and interferes with the first interference piece for a time corresponding to the first transfer time in the first unit intermittent transfer cycle along the circumferential direction to rotate the main drive index And a first cam portion
The sub-
A sub-drive index connected to a drive shaft of a sub-drive sprocket for driving the sub-transport chain and having at least one second interference piece along a circumferential direction;
And is configured to rotate by the power transmitted from the main motor and to rotate the sub-drive index by interfering with the second interference piece for a time corresponding to a second transfer time in the second unit intermittent transfer cycle along the circumferential direction And a second cam portion that is provided on the second side of the second side surface.

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