ES2401262A2 - Fishnet-hoisting machine - Google Patents

Abstract

A net pull 10 including a net platform 13 mounted on a hull 11 of a purse-seine vessel via a mounting unit 12; and cantilevered rollers 15 to 17 first to third placed on the platform 13 for network, and subjected to rotation by a source 14 of rotary drive. The mounting unit 12 includes a pivot 22 and a storage mechanism 24 pivotably mounted on the pivot 22 to store the netting platform 13 under cover 19 by operating a hydraulic storage cylinder 23; rollers 15 to 17 first to third have parallel axes, the axes of rollers 15 and 17 first and third having an opening angle of 70-150 degrees with respect to the axis of second roller 16. (Machine-translation by Google Translate, not legally binding)

Description

Network hacker.

OBJECT OF THE INVENTION

The purpose of the present invention patent is to present a new net tug to pull a fishing net thrown from a purse-seine boat.

BACKGROUND OF THE INVENTION

It is highly required for a purse-seine boat (net fishing vessel) to pull a net as quickly as possible, because an increased efficiency in net haul allows a successive net pitch when a fish catch at one time is Small, the rapid evacuation of a fishing area when the weather conditions suddenly change and a reduction in the operating costs of the boat and fuels. At present, a network hacker 101 is commonly used that includes a V-shaped drum net hacker 100, as shown in FIG. 9. However, in the network hacker 101, a network 102 easily slides from the V-shaped drum net hacker 100 during network hacking, which causes minor damage to a main network 103. In addition, the network 102 is wrapped around a groove with a V-shaped cross section, and thus the V-shaped drum net 100 can not pull the entire network 102 from the buoys 104 to the plumbs 105 to a uniform speed In FIG. 9, reference numbers 106, 107 and 108 indicate a mounting unit, a side cover of the V-shaped drum net hacker 100 and a guide roller, respectively. The guide roller 108 increases the amount of the net 102 to be wrapped around the V-shaped drum net 100, and guides the net to be released from the V-shaped drum net 100.

In view of the above problems, for example, patent documents 1-4 disclose a hauler 116 of nets for fishing by netting as shown in FIG. 10. The net hacker 116 is mounted on the side of the stern of a purse seiner 109. Using a rotating mechanism, the net hacker 116 is adjusted to an address in which the buoys 111 of a net 110 are collected to an optimum angle with respect to a direction in which the net 110 is collected. In addition, the hacker 116 of networks controls the hauling speed of buoys 111 and plumbs 114 by feeding the network 110 around two S-shaped rollers 112, 113, on the other hand, the network hacker 116 collects a main network 115 with a uniform tension, thereby preventing minor damage to the main network 115 and allowing the main network 115 to be uniformly pulled. In FIG. 10, reference numbers 117 and 118 indicate a quia roller and an end support, respectively. The guide roller 117 guides the net 110 to the roller 112. The end support 118 rotatably supports the rollers 112, 113 and the guide roller 117 in a cantilever manner.

Patent Document 5, for example, discloses a winch (net pull) 141 for a fishing net and the like, as shown in FIG. 11 (A). The winch 141 is mounted on one side in a master frame part 119 of a purse-seine ship. Capstan 141 includes three rollers 120-122 with parallel shafts. The rollers 120-122 are rotatably placed straight in a common support section 123. Adjacent rollers 120-122 rotate in opposite directions (i.e., rollers 120, 122 rotate in the same direction, but roller 121 rotates in the opposite direction). As shown in FIG. 11 (B), the common support section 123 is tiltable from a first portion in which the rollers 120-122 are fixed in an approximately horizontal direction to a second position in which the rollers 120-122 are fixed in an approximately direction vertical. On the other hand, the winch 141 coils a net around the three rollers 120-122, and distributes and balances the pulling force of the rollers 120-122 loaded on a main net, thereby preventing damage to the main net.

In FIG. 11 (A) and 11 (B), reference numbers 124, 125, 126 indicate end plates attached to respective ends of the rollers 120, 121, 122, respectively. The end plates 124, 125, 126 guide a movement of the network. Reference numbers 127, 128 indicate legs. The legs 127, 128 support the common support section 123 on the side in the part 119 of the master frame. Reference numbers 129, 130, 131 indicate rotary shafts of rollers 120, 121, 122. Reference numbers 132, 133, 134 indicate gears attached to respective proximal sides of rotary shafts 129, 130, 131. The adjacent gears 132, 133, 134 engage with each other. A reference number 135 indicates a motor, a motor shaft of which is coupled to the proximal side of the rotary shaft 129. A reference number 136 indicates a support for common support section 123. A reference number 137 indicates a bolt. Bolt 137 attaches bracket 136 to leg 128 in a swinging manner. A reference number 138 indicates a cylinder pivotally attached to leg 128. A reference number 139 indicates a mounting bolt. The mounting bolt 139 holds the cylinder 138 to the leg 128 in a tilting manner. A reference number 140 indicates a piston rod of the cylinder 138. A reference number 142 indicates a connecting bolt for the piston rod 140 and the support 136.

Prior art documents:

Patent Document 1: Japanese Unexamined Patent Application Publication No. 62-40233.

Patent Document 2: Japanese Unexamined Patent Application Publication No. 62-130634.

Patent Document 3: Japanese Unexamined Patent Application Publication No. 62-130635.

Patent Document 4: Japanese Unexamined Patent Application Publication No. 62-130636.

Patent Document 5: Japanese Examined Patent Application Publication No. 50-33956.

Using the turning mechanism, the net hacker 116 for fishing by netting in Patent Documents 1-4 coils the net 110 around the two S-shaped rollers 112, 113, which, however, cannot apply to the main network 115 a sufficient retention force to pull the network 110. Thus, the main network 115 slides from the rollers 112, 113, and the main network 115 is damaged.

The winch 141 for the fishing net and the like of Patent Document 5 does not have the rotating mechanism and therefore cannot wind the net safely around the rollers 120-122 if the directions in which the net is changed are changed. pick up and eject. Accordingly, the net slides from the rollers 120-122, which causes wear and damage of the main net. On the other hand, the winch 141 cannot properly adjust either the positions of the roller 120, around which the pulled net is wound in the first place, nor the common support section 123 to the direction in which the net is collected. As a result, the net collected in the common support section 123 slides and twists, and the twisted net is wound sequentially around the rollers 121,

122. The twisted net descended through a pulley (not illustrated) needs to be unwound before spreading on a network stacking platform, which decreases the efficiency of the network hauling.

DESCRIPTION OF THE INVENTION

The present invention has been made in view of the foregoing circumstances and is intended to provide a network hauler that can operate to pull a net while preventing twisting (twisting) and sliding of the net even when the directions are changed in which the network is collected and expelled.

To achieve the above objective, the present invention provides a network hauler that includes a first and third net platform and rollers, the net platform tiltingly mounted on the hull of a purse-seine boat through a mounting unit, the rollers first to third respectively cantilever and located directly on the network platform with spaces between the rollers, the first to third rollers rotated by means of a rotary drive source, pulling the net from the network hauler while winding the net sequentially around the rollers first , second and third, the network hauler characterized in that: the mounting unit includes a pivot and a storage mechanism, the pivot mounted through a base for the mounting unit on a part of the helmet located under the cover, having the pivot a rotating mechanism inside the pivot, the storage mechanism pivotally mounted on the pivo te, by storing the storage mechanism the network platform device in a specific angular position under the cover by operating a hydraulic storage cylinder; the rollers having first to third parallel axes, the axes of the first and third rollers having an opening angle of 70 to 150 degrees with respect to the axis of the second roller, when viewed from an axial direction of the first to third rollers; and a network guide provided at the end of the network platform on which the first roller is located and the network is collected, the network guide changing an angle of the network guide around the end of the network platform by operating a hydraulic angle adjustment cylinder.

In the network hauler according to the present invention, it is preferable that the net hacker be as defined in claim 1, characterized in that the network guide includes: a fixed axis having both ends fixed to the end of the platform for net; a channel rotatably attached to the fixed axis; a movable guide having both ends fixed to respective sides of the channel, the movable guide having a curved section in a center of the movable guide, the movable guide having a straight guide section next to the first roller; a reinforcement that connects a middle portion of the channel and the curved section; and a projection provided in the curved section or the guide section next to the curved section, preventing the projection that the network passing through the guide section is detached from the guide section.

Preferably, the fixed axis is stored within a cut formed at the end of the network platform; and the channel guides a part of the network when the mobile guide is separated from a surface of the network platform.

In the network hauler according to the present invention, it is possible that the first to third rollers include first to third gears on respective proximal sides, the first to third gears having the same outer diameter and the same number of teeth, engaging each other the first and second gears, the second and third gears engaging with each other; and a fourth gear rotatably driven by the rotary drive source coupled with any one of the first to third gears.

In the network hauler according to the present invention, it is possible that the first to third rollers include first to third gears on respective proximal sides, the first to third gears having the same outer diameter and the same number of teeth, engaging each other the first and second gears, the second and third gears engaging with each other; and a plurality of fourth gears rotatably driven by the rotary drive source are coupled with any one of the first to third gears.

In the network hauler according to the present invention, it is possible that the first to third rollers include first to third gears on respective proximal sides, the first to third gears having the same outer diameter and the same number of teeth, engaging each other the first and second gears, the second and third gears engaging with each other; and one or more fourth gears rotatably driven by the rotary drive source are coupled with any two or more of the first to third gears.

In the network hauler according to the present invention, the mounting unit includes the storage mechanism that allows the network platform in the specific angular position to be stored under the cover. Thus, the network hacker can be stored, for example, under the work deck during the network pitch, which improves the efficiency in the network pitch.

Since the net platform is tilting and rotating, even when the direction in which the net is collected in the purse-seine vessel is changed during the hacking of the net, the axial direction of the first roller, around which the net is wound in First, it can be adjusted to an optimal angle with respect to the direction in which the net is collected. Accordingly, the collected net is safely wrapped around the first roller.

The first to third rollers have parallel shafts. When viewed from the axial direction of the first to third rollers, the opening angle between the axes of the first and third rollers is 70-150 degrees with respect to the axis of the second roller. Thus, even if the axial direction of the first roller is adjusted to the optimum angle with respect to the direction in which the net is collected, the net that passes through the first roller can be narrowly wound around the second and third rollers. In this sense, the net does not slide from the rollers first to third, which prevents wear and damage of the main net (i.e., an area of the net except buoys and plumbs).

The network guide is provided at the end of the network platform on which the first roller is located and the network is collected. The network guide can change its angle around the end of the network platform. By rotating the network guide around the end of the network platform according to the tilted and rotated network platform, the plumbs and a part of the main network connected to them can move over the network guide and subsequently over the platform for network Here, (a) a torsion angle 81 (twist angle) of a part of the pulled net (the plumbs and a part of the main net connected to them) that moves over the net guide while the direction is changed of movement and (b) a torsion angle 82 of a part of the network moving from the network guide over the network platform while changing the direction of movement are less than (c) a torsion angle 8T of a part of the pulled network that moves directly over the network platform while changing the direction of movement. Therefore, the sliding amounts S1 and S2 of a part of the network on the network guide and on the network platform, respectively, can be reduced. On the other hand, the network that moves over the network platform is less twisted or hardly twisted.

By adjusting the rotation position of the network guide, the end of the network guide can be maintained in a direction perpendicular to the direction of movement of a part of the network. When moving over the network guide, a part of the network is curved and changes the direction of movement of the network, thereby preventing it from twisting and sliding on the network guide. As a result, the network that moves over the network platform is twisted much less.

In the network hauler according to the present invention, the network guide may include: the fixed axis having both ends fixed to the end of the network platform; the channel rotatably attached to the fixed axis; the movable guide having both ends fixed to the respective sides of the channel, the movable guide having the curved section in the center of the movable guide, the movable guide having the straight guide section next to the first roller; the reinforcement connecting the middle portion of the channel and the curved section. This configuration allows the straight guide section to be stably maintained in a direction perpendicular to a part of the pulled net, by adjusting the angle of rotation of the mobile guide with respect to the end of the net platform (fixed axis). In addition, the projection is provided in the curved section or the guide section near the curved section, preventing a part of the network passing through the guide section from detaching from the guide section. Even when the network platform is spun excessively by mistake, the projection can effectively guide a part of the network to the network platform from the guide member of the network guide.

It is possible that the fixed axis is stored within a cut formed at the end of the network platform; and the channel guides a part of the network when the mobile guide is separated from a surface of the network platform. This configuration allows the channel to be positioned in a direction perpendicular to the direction of movement of a part of the pulled network, and therefore the network is directed smoothly over the surface of the network platform without twisting.

In the network hauler according to the present invention, it is possible that the first to third rollers include first to third gears on respective proximal sides, the first to third gears having the same outer diameter and the same number of teeth, engaging each other the first and second gears, the second and third gears engaging with each other; and a fourth gear rotatably driven by the rotary drive source is coupled with any one of the first to third gears. This configuration allows the first to third rollers to rotate simultaneously at the same circumferential speed.

In the network hauler according to the present invention, it is possible that the first to third rollers include the first to third gears on the respective proximal sides, the first to third gears having the same outer diameter and the same number of teeth, coupling the first and second gears together, the second and third gears engaging each other; and the plurality of fourth gears rotatably driven by the rotary drive source are coupled with any one of the first to third gears. This configuration allows the first to third rollers to rotate simultaneously at the same circumferential speed with great rotational force (torque), and retain the net with an improved retention force.

In the network hauler according to the present invention, it is possible that the first to third rollers include the first to third gears on the respective proximal sides, the first to third gears having the same outer diameter and the same number of teeth, coupling the first and second gears together, the second and third gears engaging each other; and one or more of the fourth gears rotatably driven by the rotary drive source are coupled with any two of the first to third gears. This configuration allows the first to third rollers to rotate simultaneously at the same circumferential speed with great rotational force, and retain the net with an improved retention force. For this reason, the network hacker is applicable to maintain a larger network

DESCRIPTION OF THE DRAWINGS.

To complement the description that is being made, and in order to help a better understanding of the features of the invention, this description is attached, as an integral part thereof, a figure in which, for illustrative purposes and not limiting, the following has been represented:

FIG. 1 is an elevation view of a network hauler that maintains a network platform in a horizontal position according to an embodiment of the present invention.

FIG. 2 is a side view of the network hauler that keeps the network platform in the horizontal position.

FIG. 3 is an explanatory view of the first to third rollers and a guide for the network in the network hacker.

FIG. 4 is an explanatory view of the second roller in the network hacker.

FIG. 5 is an elevation view of the network hauler with the tilted network platform.

FIG. 6 is an elevation view of the network hacker stored under a cover.

FIG. 7 is a plan view that shows how the network hauler pulls a network.

FIG. 8 (A), 8 (B), 8 (C) are explanatory views showing the operation of the network guide.

FIG. 9 is an explanatory view of a network hauler according to conventional technique.

FIG. 10 is an explanatory view of a network hauler according to the conventional technique.

FIG. 11 (A), 11 (B) are explanatory views of a net hacker (winch) according to conventional technique.

PREFERRED EMBODIMENT OF THE INVENTION.

Referring to the accompanying drawings, an embodiment of the present invention is described for a better understanding.

As shown in FIG. 1 and 2, a network hacker 10 according to an embodiment of the present invention includes a platform 13 for net and rollers 15, 16, and 17 first, second and third. The network platform 13 is pivotally mounted on a hull 11 of a purse-seine ship with a mounting unit 12. The rollers 15 to 17 first to third are cantilevered and placed straight (that is, in an upright position) on the platform 13 for network with spaces. The rollers 15 to 17 first to third are rotated by a hydraulic motor 14, an example of rotary drive sources. The network pull 10 pulls a net 18 (see FIG. 7) while winding the net 18 around the rollers 15 to 17 first to third sequentially. Detailed descriptions will be given later.

The mounting unit 12 includes a pivot 22 and a storage mechanism 24. The pivot 22 is placed on a part (that is, one side at the stern) of the hull 11 under a cover (work deck) 19 with a base 20 for the mounting unit. The pivot 22 has a turning mechanism 21 therein. The storage mechanism 24 is pivotally attached to the pivot 22. The storage mechanism 24 operates hydraulic storage cylinders 23 to store the network platform 13 located in a specific angular position (eg, a horizontal position) under the cover 19.

The turning mechanism 21 includes an alignment bearing (not illustrated), a rotation support 25, a hydraulic motor 25a, a rotation immobilization member (not illustrated) and a protector (protective frame)

26. The alignment bearing is placed on a frame (not illustrated) of the pivot 22. A proximal side of the rotating support 25 is rotatably located right in the frame through the alignment bearing, while a distal side thereof projects. right from the pivot 22. The hydraulic motor 25a, an example of the rotary drive sources, is connected to the proximal side of the rotating support 25 through a power transmitter means (not shown) having gears. The rotation immobilization member is placed in the frame, and immobilizes the rotation of the rotation support 25. The protector 26 is attached to the rotation support 25 such that the protector 26 covers an upper end and the sides of the rotation support 25 projecting upwardly from the pivot 22. The protector 26 rotates together with the rotation support 25 .

The storage mechanism 24 includes a mobile section 28 that is U-shaped or U-shaped with square corners and the hydraulic storage cylinders 23. The mobile section 28 covers one side of the protector 26 inserted from an opening of the mobile section 28. A lower part on a closed side of the mobile section 28 is rotatably attached to a lower part of the protector 26 by means of a mounting bolt 27. The mobile section 28 has a pair of walls 29, 30 on both sides of the opening. In front of the walls 29, 30, a mounting stand 31 is attached to the guard 26. The hydraulic storage cylinders 23 are fixed on respective sides of the mounting stand 31 by mounting brackets 34, so that the shafts of the stems 33 of piston, whose front ends are respectively attached to the walls 29, 30 by means of retaining bolts 32, are directed downwards.

Reference numbers 35, 36 indicate immobilization bolts. The locking bolts 35, 36 are attached to an upper part on the opening side of the movable section 28. In order to keep the mobile section 28 vertically in the protector 26, the front ends of the locking bolts 35, 36 are inserted into retaining holes 37 (see FIG. 6) formed in an upper part of the protector 26.

A platform 38 for the network platform is attached to an upper side of the mobile section 28. The first to third rollers 15 to 17 placed straight on the network platform 13 have parallel axes. When viewed from an axial direction of the rollers 15 to 17 first to third, an opening angle of the axes of the first and third rollers 15 and 17 with respect to the axis of the second roller 16 has a lower limit of 70 degrees (preferably 80 degrees, more preferably 85 degrees and even more preferably 88 degrees) and an upper limit of 150 degrees (preferably 120 degrees, more preferably 100 degrees and even more preferably 95 degrees). On a lower surface of the network platform 13, for example, a first assembly 39 is placed vertically downwards at a midpoint of a line A that connects the centers of the first and third rollers 15 and 17. An anterior end of the first assembly 39 is pivotally attached to one side of the platform 38 of the network platform by a first connecting bolt 40. Furthermore, on the lower surface of the netting platform 13, a second assembly 41 is placed vertically downward at a point on the extended line beyond the third roller 17. To the second assembly 41, an anterior end of a rod 44 is attached of piston of a tilting cylinder 43 by means of a second connecting bolt 45. The tilting cylinder 43 is rotatably connected to the other side of the platform 38 of the netting platform by means of a bolt 42.

On a top surface of the netting platform 13, a first guide bolt 46 is placed straight on a straight line B that connects a center of the second roller 16 and the midpoint of line A, but is located outward from the line A towards the end of the network platform 13. In addition, on the upper surface of the net platform 13, a second guide bolt 47 (see FIG. 3) is placed and located inwardly from the center of the line A (near the center of the second roller 16).

As shown in FIG. 3, the first to third rollers 15 to 17 having the same outer diameter include gears 48 to 50 first to third at the respective proximal ends. The first to third gears 48 to 50 have the same number of teeth. The first and second gears 48 and 49 engage each other. Also, the second and third gears 49 and 50 are coupled together. And, a fourth gear 51 rotatably driven by the hydraulic cylinder 14 is coupled with any one of the first to third gears 48 to 50, e.g. eg, the second gear 49.

As shown in FIG. 4, the second roller 16 (the same applies to the first and third rollers 15 and 17) includes a fixed shaft 53, the second gear 49, an internal tube 56, an external tube 61 and a rubber member 62. The fixed axis 53 is fixed straight on the network platform 13 by a fixing member 52 so that a proximal end of the fixed axis 53 penetrates the network platform 13. The second gear 49 is stored within the network platform 13, and rotatably and coaxially joined by a first bearing 54 to the fixing member 52 located in the network platform 13. The inner tube 56 coaxially covers an outer periphery of the fixed shaft 53. A proximal end of the inner tube 56 is fixed to the second gear 49, while a distal end thereof is rotatably attached to an upper end of the fixed shaft 53 with a second bearing 55. The outer tube 61 is supported by an upper relief 57 and a lower enhancement 58, formed respectively on an upper side and a lower side of the inner tube 56. The external tube 61 coaxially covers the fixed axis 53 projecting upward from the network platform 13. The rubber member 62 is attached to the outer tube 61. Here, an upper inner portion of the outer tube 61 is rotatably supported by the fixed shaft 53 through the upper enhancement 57. The upper enhancement 57 is linked to an assembly 59 attached to an inner surface of the outer tube 61. The lower end of the outer tube 61 engages with second ratchets 60a attached to an upper surface of the second gear 49 through first ratchets 60 circumferentially formed in a lower inner portion of the outer tube 61. The first ratchets 60 include portions that project downward, and the second ratchets 60a include portions recessed upwards. The first ratchets 60 and the second ratchets 60a form a coupling. With this structure, the rotational drive force of the fourth gear 51 generated by the hydraulic motor 14 is transmitted to the external tube 61 through the second gear 49, and thus the external tube 61 is rotatably driven.

The first to third rollers 15 to 17 respectively include annular caps 63, 63a, 63b at upper ends of the outer tubes 61 and the rubber members 62. On the other hand, the hydraulic motor 14 is fixed to the lower surface of the network platform 13 through an assembly 64, and the fourth gear 51 is connected to a motor shaft 65 of the hydraulic motor 14 projecting within the platform 13 for network.

As shown in FIG. 1 and 2, a first upper plate 66 is placed through a first head 67 (see FIG. 7) on an upper side of the cover 63 of the first roller 15 with a space. The first head 67 is fixed on the upper end of the axis 53 of the first roller 15. Also, a second upper plate 68 is placed through second and third heads 69, 70 (see FIGS. 4 and 7) on upper sides of the covers 63a, 63b of the rollers 16, 17 second and third with a space. The second and third heads 69, 70 are fixed on the upper ends of the fixed shafts 53 of the second and third rollers 16, 17. The adjacent ends of the first upper plate 66 and the second upper plate 68 are in contact with each other. These upper, first and second upper plates 66, 68 integrally cover the covers 63, 63a, 63b respectively connected to the rollers 15, 16, 17 first, second from above.

When viewed from above, the first upper plate 66 placed on the upper side of the cover 63 projects to the end of the net platform 13 where the first and third rollers 15 and 17 are placed. An anterior end of the first upper plate 66 includes a third guide bolt 71 positioned vertically downward toward the upper surface of the netting platform 13.

As shown in FIG. 3, a network guide 73 is provided at the end of the network platform 13 on which the first roller 15 is placed and the network is collected. The angle of the network guide 73 can be changed with respect to the end of the network platform 13 using a hydraulic angle adjusting cylinder 72. The network guide 73 includes a fixed axis 74, a channel 75, a mobile guide 78 and a reinforcement 79. The fixed axis 74 is stored in a cut formed at the end of the network platform 13, and both ends of the axis 74 Fixed are fixed to the respective sides of the cut. The fixed shaft 74 is inserted in the channel 75, and the channel 75 is rotatably mounted on the fixed shaft 74 through a bearing (not shown). The mobile guide 78 has both ends fixed to the respective sides of the channel 75. The mobile guide 78 includes a section 76 curved in its center and a straight guide section 77 next to the first roller 15. The reinforcement 79 connects a middle portion of the channel and section 76 curved. When the mobile guide 78 is separated from the upper surface of the network platform 13, the channel 75 placed within the cut formed in the network platform 13 guides a part of the network 18, that is, the plumbs 83 and a part of the main network 82 connected to them (see FIG. 7).

On the other hand, the curved section 76 includes a projection 80, which avoids a detachment of the part of the net 18 that passes through the guide section 77. The projection 80 may be formed in an intermediate position between the curved section 76 and the guide section 77 (ie, in the guide section 77 adjacent to the curved section 76).

As shown in FIG. 5, the rotation support 25 is immobilized by the rotation immobilization member, the movable section 28 is held towards the protector 26 by means of the immobilization bolts 35, 36, and then the piston rod 44 of the tilting cylinder 43 is ejected . This operation allows the network platform 13 in a horizontal position to be tilted towards the platform 38 of the network platform, using the first connecting bolt 40 as a support point. In addition, the rotation immobilizer member in the pivoting mechanism 21 of the unlocking pivot 22 and the rotation support 25 is rotated by the hydraulic motor 25a. This operation allows the mobile section 28 and the rotation support 25 to be rotated together. With these operations, the network platform 13 can be rotated on the platform 38 of the network platform attached to the mobile section 28.

As shown in FIG. 6, the rotation support 25 is immobilized by the immobilizing member of the rotation, the piston rod 44 of the tilting cylinder 43 is pushed in and then the net platform 13 is rotated around the platform 38 of the net platform. This operation allows the network platform 13 to be returned to the horizontal position. On the other hand, the mobile section 28 retained to the guard 26 is unlocked by moving the immobilizer bolts 35, 36, and the piston rod 33 of the hydraulic storage cylinder 23 is ejected. This operation allows the mobile section 28 to be rotated towards the guard 26, using the mounting bolt 27 as a fulcrum. With these operations, the mobile section 28, the platform 38 of the network platform and the network platform 13 can be tilted integrally towards the guard 26 and stored under the cover 19. Therefore, the network hacker 10 can be stored under the working cover 19 during the casting of the net, improving the efficiency in the casting of the net.

Next, descriptions will be given on the operation of the network hacker 10 according to an embodiment of the present invention.

The platform 13 for network is tilting and rotating. By tilting and turning the net platform 13 as shown in FIG. 7, even if the direction in which the net 18 is collected to the purse-seine vessel during the hauling of the net is changed, the axial direction of the first roller 15, around which the net 18 is first wound, can be adjusted to an optimum angle with respect to the direction in which the net 18 is collected (ie, the buoys 81 connected to the net 18 and a part of the main network 82 connected thereto). Accordingly, the buoys 81 and a part of the main network 82 connected thereto are safely wound around the first roller 15 and are directed to the network platform 13. On the other hand, the plumb lines 83 of the network 18 and a part of the main network 82 connected thereto advance to an area on the network platform 13 under the third guide bolt 71. Next, the jig 83 of the network 18 and a part of the main network 82 connected thereto are wound around the first roller 15 guided by the first and second guide bolts 46, 47, and then directed to the second roller 16.

When viewed from the axial direction of the first to third rollers 15 to 17 having parallel axes, the opening angle between the axes of the first and third rollers 15 and 17 is 70-150 degrees with respect to the axis of the second roller 16 Thus, the net 18 is gathered by the first and second rollers 15, 16 when it passes through it. Next, the net 18 is wound around the second roller 16 after the plumbs 83 and a part of the main network 82 connected thereto are wound around the first roller 15. After passing through the second roller 16, the net 18 is joined by the second and third rollers 16, 17, and is directed towards the third roller 17 with the guidance by means of the first and second guide pins 46, 47. Accordingly, the buoys 81 and a part of the main network 82 connected thereto are safely wound around the third roller 17. In that sense, the net 18 barely slides from the rollers 15 to 17 first to third, which prevents wear and damage on the main network 82.

In network hauling, the position of the network platform 13 is adjusted sequentially by tilting and rotating the network platform 13. Therefore, buoys 81 and a part of the main network 82 connected thereto can be safely wrapped around the first roller 15.

As shown in FIG. 8 (A), for example, when the network platform 13 is tilted 30-40 degrees to a horizontal direction and rotated 30 degrees clockwise (i.e., rotated 30 degrees clockwise. clock), a feed direction of the plumb lines 83 and a part of the main network 82 connected thereto is substantially perpendicular (orthogonal) to an axis of the channel 75 of the network guide 73 provided at the end of the platform 13 for net. In this case, the network guide 73 is rotated around the end of the network platform 13 using the angle adjustment hydraulic cylinder 72, and the mobile guide 78 of the network guide 73 is directed downward (i.e., it separates from the surface of the network platform 13). Thus, the plumbs 83 can be curved together with a part of the main network 82 connected to them when they pass through the channel 75 on the network platform 13. As a result, a large sliding of the plumb lines 83 and a part of the main network 82 connected to them on the network platform 13 is avoided and the additional twisting of the network 18 caused when the network 18 is wound around the first one is reduced roller 15.

In the successive network hauling, a feed direction can be changed to the first roller 15 of the buoys 81 and a part of the main network 82 connected thereto. In that case, as shown in FIG. 8 (B), for example, the network platform 13 is tilted 20-30 degrees to a horizontal direction and rotated 30 degrees counterclockwise, thereby returning to a reference position (i.e. rotated 0 degrees) According to this operation, the feed direction of the plumb plugs 83 and a part of the main network 82 connected thereto can be changed until orthogonal with respect to the axis of the channel 75 provided at the end of the network platform 13. In such a case, the network guide 73 is rotated around the end of the network platform 13 using the angle adjustment hydraulic cylinder 72, and the mobile guide 78 of the network guide 73 is directed upward to a position of mid angle within the range that the mobile guide 78 can rotate.

After passing through the guide section 77 of the network guide 73, the plumbs 83 and a part of the main network 82 connected thereto move on the network platform 13. Here, (a) a torsion angle 81 of the pulled plumbs 83 and a portion of the main network 82 connected thereto that move on the net guide 73 and (b) a twist angle 82 of the plumb bob 83 and a part of the main network 82 connected to them that move from the network guide 73 on the network platform 13 may be smaller than (c) a twist angle 8T of the plumbs 83 and a part of the main network 82 connected to them that move directly on the network platform 13. Thus, even if the plumb lines 83 and a part of the main network 82 connected thereto are not curved together, a sliding amount S1 on the guide 73 for the plumb line 83 and a part of the network can be reduced (a) 82 main connected to them as well as (b) a sliding amount S2 on the platform 13 for network of the plumbs 83 and a part of the main network 82 connected to them, and in addition the twisting of the network 18 which can be reduced it moves on the platform 13 for network. As a result, it becomes easy to unwind the twisted net 18 that descends through a pulley (road rails) and extend the net 18 on a network stacking platform, which avoids a decrease in the efficiency of the network hacking.

When the mobile guide 78 is rotated by the hydraulic angle adjusting cylinder 72, the mobile guide 78 is preferably held in a specific rotated position (if any) in which the direction of movement of the plumbs 83 and a portion of the main network 82 connected thereto is substantially perpendicular to the axis of the guide section 77 of the mobile guide 78. This operation can reduce the twisting of the pulled plumbs 83 and a part of the main network 82 connected to them that advance towards the network guide 73, and also reduce the twist of the network 18 that advances towards the network platform 13.

In successive network hauling, if the feed direction is changed to the first roller 15 of the buoys 81 and a part of the main network 82 connected thereto, as shown in FIG. 8 (C), for example, the network platform 13 is tilted to the horizontal position and rotated 15 degrees counterclockwise (i.e. rotated 15 degrees counterclockwise). On the other hand, the feed direction of the plumb lines 83 and a part of the main network 82 connected thereto remains non-orthogonal to the axis of the guide section 77 of the network guide 73. Thus, the network guide 73 is rotated around the end of the network platform 13 using the angle adjustment hydraulic cylinder 72, and therefore the mobile guide 78 in the network guide 73 is placed in the horizontal position. As a result, the feed direction of the plumb lines 83 and a part of the main network 82 connected thereto becomes substantially orthogonal to the axis of the guide section 77 of the movable guide 78.

In view of the above, when they pass through the guide section 77 and move over the network guide 73, the plumbs 83 and a part of the main network 82 connected thereto can be curved together, thereby avoiding that slip a lot from the 73 guide for network. Thus, the twisting of the network 18 caused when the network 18 is pulled over the network guide 73 can be reduced. In addition, the network guide 73 is connected to the network platform 13 so that the upper surfaces of the network guide 73 and the network platform 13 are at the same height. Thus, after passing through the network guide 73, the plumbs 83 and a part of the main network 82 connected thereto can move on the network platform 13 without twisting. As a result, the twisting of the network 18 that moves on the network platform 13 can be reduced.

Although the embodiment of the present invention has been described, the present invention is not limited to the embodiment described above, and other embodiments and various modifications can be made without departing from the claims appended thereto.

The present invention further includes other combinations of the elements of the present embodiment and other embodiments and various modifications.

For example, the second gear of the second roller is coupled with the fourth gear rotatably driven by the rotary drive source in order to rotate the rollers first to third together at the same circumferential speed. However, the second gear of the second roller can be coupled with a plurality of the fourth gears rotatably driven by the rotary drive source. With this, the rotational force of the second gear can be increased, and the first to third rollers can rotate together at the same circumferential speed with a greater rotational force. As a result, the first to third rollers can retain the net with increased retention force.

In addition, two or more of the first to third gears can be coupled with one or more of the four gears rotatably driven by the rotary drive source. With this, the first to third rollers can rotate together at the same circumferential speed with a greater rotational force. As a result, the first to third rollers can retain the network with an increased retention force, allowing stable network hauling even with a larger network.

Once the nature of the present invention has been sufficiently described, as well as a way of putting it into practice, it only remains to be added that said invention may undergo certain variations in form and materials, as long as said alterations do not substantially vary the characteristics claimed then.

Claims (6)

one.

 A network hauler (10) that includes a net platform (13) and first to third rollers (15), (16) and (17), the net platform (13) swiveled mounted on a helmet (11) of a purse-seine boat through a mounting unit, the first to third rollers (15), (16) and (17), respectively cantilever and placed straight on the net platform (13) with spaces between said rollers, the rollers first (15) to third (17), subjected to rotation by means of a rotary drive source, pulling the net pull (10), a net while winding the net sequentially around the first (15), second (16) and third rollers (17), the network hauler (10), characterized in that:

The mounting unit includes a pivot (22) and a storage mechanism (24), the pivot (22) mounted through a base of the mounting unit (20) on a part of the hull (11) located under a cover , the pivot (22) having a rotation mechanism (21) within the pivot, the storage mechanism (24) pivotally mounted on the pivot (22), the storage mechanism (24) storing the network platform device ( 13) in a specific angular position under the cover by operating a hydraulic storage cylinder (23); the first to third rollers (15), (16) and (17), have parallel axes, the first (15) and third (17) roller axes having an opening angle of 70 to 150 degrees with respect to the axis of the second roller, when viewed from an axial direction of the first (15) to third (17) rollers; and a network guide (73) provided at the end of the network platform (13) on which the first roller (15) and the collection network is located, changing the network guide (73) an angle of the guide for network around the end of the network platform by operating a hydraulic angle adjustment cylinder (72).

2.

 The network hauler (10) according to claim 1, characterized in that the network guide (73) includes:

A fixed shaft (74) having both ends fixed to the end of the network platform (13); a channel (75) rotatably connected to the fixed axis (53); a mobile guide (78) having both ends fixed to respective sides of the channel (75), the mobile guide (78) having a curved section (76) in a center of the mobile guide (78), the mobile guide having a section guide (77) straight next to the first roller (15); a reinforcement (79) connecting a middle portion of the channel (75) and the curved section (76); and a projection provided in the curved section (76) or the guide section

(77)

 next to the curved section (76), avoiding the projection that the network that passes through the guide section

(77)

 detach from the guide section (77).

3.

 The network hauler (10) according to claim 2, characterized in that the fixed axis (53) is stored within a cut formed at the end of the network platform (13); and the channel guides a part of the network when the mobile guide (78) departs from a surface of the network platform (13).

Four.

 The net hacker (10) according to any one of claims 1-3, characterized in that the first (15) to third (17) rollers include first (48) to third (50) gears on respective proximal sides, having the first (48) to third (50) gears the same external diameter and the same number of teeth, the first (48) and second (49) gears engaging each other, the second (49) and third (50) gears engaging each other ); and a fourth gear (51) rotatably driven by the rotary drive source is coupled with any one of the first (48) to third (50) gears.

5.

 The net hacker (10) according to any one of claims 1-3, characterized in that the first (15) to third (17) rollers include first (48) to third (50) gears on respective proximal sides, said said having gears the same external diameter and the same number of teeth, the first (48) and second (49) gears engaging each other, the second (49) and third (50) gears engaging each other; and a plurality of fourth gears (51) driven by the rotary drive source are coupled with any one of the first (48) to third (50) gears.

6.

 The net hacker (10) according to any one of claims 1-3, characterized in that the first (15) to third (17) rollers include first (48) to third (50) gears, on respective proximal sides, having the first (15) to third (17) gears, the same external diameter and the same number of teeth, the first (48) and second (49) gears engaging with each other, the second (49) and third gears engaging each other (fifty); and one or more fourth gears (51) rotatably driven by the rotary drive source are coupled with any two or more of the first (15) to third (17) gears.