KR20200022825A - Improved harvestability of stock cultivation kits - Google Patents

Abstract

The present invention relates to a pillar-type laver farming rack with improved harvestability, which farms laver of high-quality while being resistant to pests and disease based on a pillar-type laver farming method, greatly improve the harvestability of the laver by harvesting a large amount of laver without place restrictions, and has no fear of rapid devastation of the seawater environment caused by waste hydrochloric acid by farming the laver without the waste hydrochloric acid using the pillar-type laver farming method instead of a floating type laver farming method to farm the laver.

Description

Improved harvestability of stock cultivation kits

The present invention not only can grow the seaweed with excellent quality in a pest-type seaweed farming method, but also can harvest a larger amount of seaweed without place constraints, so that the seaweed yield can be greatly improved, and furthermore, the seaweed seaweed farming. In this regard, it is related to the land-based seaweed farm with improved harvestability, which does not need to use waste hydrochloric acid to grow seaweed by the land-based seaweed farming method.

In general, there are two types of laver farming methods: prop and class. 'Grown up sunny' is a laver produced by a holding ceremony.

First, the prop type seaweed farms are made of bamboo or pine trees in shallow waters, and the gimbal is farmed by installing gimbal on the shore.

By using the difference between tides, seaweed is exposed to water about 4 hours during the day, 4 hours at night, and 8 hours per day due to the low tide twice a day.

The seaweed exposed to sunlight naturally photosynthesizes, removes greens and grows into healthy seaweed that is resistant to pests.

That is, the sterilization effect by natural light.

Nori seaweed is less glossy and rougher than a variety of seaweed, but the more you chew, the better the taste and digestion.

This type of holding seaweed farming has a problem in that the yield of seaweed is low because there is a narrow constraint on the place where the land can be installed in shallow waters while being strong against pests and having excellent quality.

Next, the laver-style seaweed farming is a method of farming seaweed in a large scale while advocating the slogan 'Ranching of the sea'.In recent years, the laver-style seaweed farming is related to external conditions such as sunshine, climatic conditions and marine pollution. Irrespective of whether a light source device for photosynthesis for mass production of seaweed, a support for aquaculture, and a deep sea water supply pump have been proposed as Korean Patent Publication No. 10-1489510.

Often, white styrofoam is seen floating on the beach, and the way to float this kind of material on the sea is to hang the net under it and grow the seaweed.

This way, even if the sea is deep, it is possible to a large amount of seaweed farming.

This type of food is available for 7 months from September to March of the following year, and the seaweed grows submerged in seawater 24 hours a day.

In addition, the sterilization function due to natural light is remarkably degraded, so it is vulnerable to pests. Therefore, if no action is taken, the seaweed will decay. Therefore, the acidity is increased by using waste hydrochloric acid. There is a problem that the environment is rapidly devastated.

Domestic Patent Registration No. 10-1489510

The present invention was created in order to solve the above-mentioned problems, it is not only to grow the seaweed with excellent quality in a pest-type seaweed farming method, but also to harvest a larger amount of seaweed without place constraints, It can be greatly improved, and furthermore, it is not necessary to use waste hydrochloric acid for farming seaweed in the non-steamed seaweed farming method, so that the harvestable seaweed farming farm with improved harvestability does not have to worry that the seawater environment due to waste hydrochloric acid is rapidly destroyed. The purpose is to provide a cradle.

The present invention for achieving the above object and the mounting frame is exposed to a predetermined height in the upper direction of the sea water; Pulleys respectively provided at front, rear, and rear sides of the upper part of the mounting frame, and at the front, rear, and both sides of the lower part; One endless wire which is rotated in a state of being wound around a pulley positioned respectively at the front and rear one side and the front and rear one side of the upper part of the mounting frame; Another endless wire which is rotated while being wound around a pulley positioned at each of front and rear other parts of the upper part of the mounting frame and front and rear other parts of the lower part; A plurality of gimbal with both ends fixed at regular intervals between the one endless wire and the other endless wire, and laver spores; It provides a resilient holding type seaweed cradle, characterized in that it comprises a; drive member for intermittently rotating the one endless wire and the other endless wire.

Here, the one endless wire and the other endless wire is preferably provided with a plurality of wire connectors that are connected at both ends of the plurality of gimbal to be idle.

In addition, the inner side of the pulley is preferably coupled to the rotary gear is rotated along the pulley and the plurality of the wire connector is wound.

In addition, the one endless wire and the other endless wire is preferably guided in a zigzag form between the top and bottom of the mounting frame.

Further, it is preferable that a seawater injection unit for injecting seawater into the gimbal exposed to the upper portion of the mounting frame of the plurality of gimbal is disposed above the mounting frame.

Here, the seawater injection unit is preferably composed of a plurality of injection nozzles disposed on the upper side of the mounting frame, and an underwater pump fixed to the lower portion of the mounting frame to supply the seawater to the plurality of injection nozzles through a connection hose. .

In addition, the mounting frame is preferably provided with a horizontal control unit for adjusting the horizontal of the mounting frame.

In addition, the horizontal adjustment portion preferably includes a withdrawal support that is installed to be pulled out to the lower end of the mounting frame, respectively, and a withdrawal member for withdrawing the withdrawal support.

The present invention is strong against pests in a holding type seaweed type by intermittently rotating a plurality of gimbal drawn by the spores along the one endless wire and the other endless wire wound on the mounting frame exposed to a certain height in the upper direction of the sea water. While not only can we produce high quality seaweed but also harvest a larger amount of seaweed without place constraints, the yield can be greatly improved. Since there is no need to use waste hydrochloric acid, there is no possibility that the seawater environment due to waste hydrochloric acid is rapidly destroyed.

1 is a perspective view schematically showing a holding-type seaweed laver with improved harvestability as an embodiment of the present invention,
2 is a side view of FIG. 1,
3 is a plan view of FIG. 1,
4 is a partially cutaway plan view schematically illustrating a state in which a pulley is provided with a gear;
Figure 5 is a partial side view schematically showing a state in which the moving wheel is provided on the lower portion of the mounting frame,
Figure 6 is a side view schematically showing the installation state of the holding type seaweed girders improved harvestability of one embodiment of the present invention,
7 is an exploded perspective view schematically illustrating a state in which the seawater injection unit is separated from an upper portion of the mounting frame;
8 is a perspective view of the combination of FIG.
9 is a side view schematically showing an example of an installation state of an underwater pump of a seawater injection unit;
10 is a partially cutaway side view schematically illustrating an example of a horizontal adjustment unit;
11 is a partial cutaway side view schematically showing a state in which the horizontality of the mounting frame is adjusted through the horizontal adjustment unit;
12 to 14 are side views schematically showing an example of a state in which one endless wire and the other endless wire are installed to be guided in a zigzag form,
15 and 16 are side views schematically showing another example of a state in which one endless wire and the other endless wire are installed to be guided in a zigzag form.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Of course, the scope of the present invention is not limited to the following examples, and various modifications can be made by those skilled in the art without departing from the technical gist of the present invention.

Figure 1 is a perspective view schematically showing a holding type seaweed lager fertilizer with improved harvestability of an embodiment of the present invention, Figure 2 is a side view of Figure 1, Figure 3 is a plan view of Figure 1.

As shown in Figures 1 to 3, the holding type seaweed type cradle with improved harvestability of the present invention is largely, a mounting frame 10, a pulley 20, one endless wire 30, and the other endless wire 40. , A plurality of gimbal (50) and comprises a drive member.

First, the mounting frame 10 is the front vertical frame 110, the rear vertical frame 120, the front connection frame 130, the rear connection frame 140, one side connection frame 150 and the other side connection frame 160. Can be made.

The front vertical frame 110 may be composed of first and second front vertical frames 111 and 112 arranged left and right at a predetermined interval.

The rear vertical frame 120 may be composed of first and second rear vertical frames 121 and 122 disposed left and right while being positioned in the rearward directions of the first and second front vertical frames 111 and 112, respectively.

The front connection frame (130) includes a first front connection frame (131) formed horizontally between an upper portion of the first front vertical frame (111) and an upper portion of the second front vertical frame (112); And a second front connection frame 132 horizontally formed between the bottom of the first front vertical frame 111 and the bottom of the second front vertical frame 112.

The rear connection frame 140 includes a first rear connection frame 141 horizontally formed between an upper portion of the first rear vertical frame 121 and an upper portion of the second rear vertical frame 122; And a second rear connection frame 142 horizontally formed between a lower portion of the first rear vertical frame 121 and a lower portion of the second rear vertical frame 122.

The one side connecting frame 150 includes a first one side connecting frame 151 horizontally formed between an upper portion of the first front vertical frame 111 and an upper portion of the first rear vertical frame 121; And a second one-side connecting frame 152 horizontally formed between the lower portion of the first front vertical frame 111 and the lower portion of the first rear vertical frame 121.

The other side connecting frame 160 includes a first other side connecting frame 161 which is horizontally formed between the top of the second front vertical frame 112 and the top of the second rear vertical frame 142; And a second other side connecting frame 162 horizontally formed between the bottom of the second front vertical frame 112 and the bottom of the second rear vertical frame 142.

Next, the pulley 20 may be axially coupled in a state facing each other before and after both sides of the upper portion and the front and rear both sides of the lower portion of the mounting frame 10.

More specifically, the pulley 20 may be rotatably coupled to an upper portion of the first and second front vertical frames 111 and 112 and an upper portion of the first and second rear vertical frames 121 and 122 to face each other. have.

In addition, the pulley 20 may be rotatably coupled to a lower portion of the first and second front vertical frames 111 and 112 and a lower portion of the first and second rear vertical frames 121 and 122 to face each other. .

Next, the one endless wire 30, which may be made of various materials such as metal, is wound around the pulley 20 positioned at each of the front and rear one side and the front and rear one side of the lower part of the mounting frame 10, respectively. Rotate along pulley 20.

More specifically, each corner portion of the one endless wire 30 is axially coupled to the upper and lower portions of the first front vertical frame 111 and the upper and lower portions of the first rear vertical frame 121, respectively. It can be wound around the pulley 20.

Next, the other endless wire 40, which may be made of various materials such as metal, is wound around the pulley 20 positioned respectively at the front and rear other parts of the upper part and the front and rear other parts of the lower part of the mounting frame 10. Rotate along pulley 20.

More specifically, each edge portion of the other endless wire 40 is the pulley axially coupled to the upper and lower portions of the second front vertical frame 112 and the upper and lower portions of the second rear vertical frame 122, respectively. It can be wound up to 20.

Next, the plurality of gimbal 50 is a plurality of gimbal 50 so as to be arranged at a predetermined interval in the front and rear direction of the mounting frame 10 between the one endless wire 30 and the other endless wire 40. Both ends of the may be fixed to the one endless wire 30 and the other endless wire 40, respectively.

Laver spores are plunged into the plurality of laver 50.

Next, although not shown in the drawing, the driving member is coupled to any one of the plurality of pulleys 20 in a state of coupling to the upper or lower of the first or second front vertical frame (111, 112) Fixed in a manner or fixed in various ways such as bolt fixing on the upper or lower portion of the first and second rear vertical frames (121, 122) by intermittently rotating any one of the pulleys 20 and the one endless wire (30) and It may be made of a drive motor for intermittently rotating the other endless wire 40.

4 is a partially cutaway plan view schematically illustrating a state in which a pulley is provided with a gear.

Next, the lower end of the plurality of laver growing in the plurality of gimbal 50 during the process of intermittently rotating the plurality of gimbal 50 together with the one endless wire 30 and the other endless wire 40 In order to be able to smoothly intermittently rotate along the plurality of gimbal 50, a plurality of seams in the state toward the bottom of the mounting frame 10, as shown in Figure 2 and 4 the endless wire 30 and the plurality of wire connectors 70 to which both ends of the plurality of gimbal 50 are rotatably connected to the other endless wire 40 may be provided at predetermined intervals in the front and rear directions of the mounting frame 10. Can be.

A plurality of the wire connector 70 is weld fixed, adhesive fixed, solder fixed, bolts on the outer surface of the one endless wire 30 and the outer surface of the other endless wire 40 to be disposed in the outer direction of the pulley 20 It can be fixed in a variety of ways, such as fixed.

Inserted grooves provided on an outer surface of the one endless wire 30 to be inserted into one side of the plurality of gimbal (50) in the inner side of the plurality of wire connector (70) portions facing one side of the plurality of gimbal (50) 710 may be formed.

An insertion groove provided on an outer surface of the other endless wire 40 to insert the other side of the plurality of gimbal 50 into the inner side of the plurality of wire connectors 70 facing the other side of the plurality of gimbal 50. 710 may be formed.

In order to allow the plurality of gimbal 50 to be more smoothly idling, one outer diameter size and the other outer diameter size of the plurality of gimbal 50 may be formed smaller than the inner diameter size of the insertion groove 710. .

Next, in order to allow the plurality of wire connectors 70 to be rotated more easily and intermittently along the one endless wire 30 and the other endless wire 40, the plurality of pulleys 20 Rotating gear 80 that rotates along the pulley 20 and the plurality of wire connectors 70 are wound on the side may be coupled in various ways such as bolt fixing.

5 is a partial side view schematically showing a state in which the moving wheel is provided at the bottom of the mounting frame.

Next, in order to smoothly move the mounting frame 10, as shown in Figure 5 the lower inner and rear inner frame of the front vertical frame 110 of the mounting frame 10, casters, etc. The shaft member 171 formed on the upper portion of the moving wheel 170, which can be made of various kinds, may be detachably inserted.

Figure 6 is a side view schematically showing the installation state of the holding-type seaweed girders with improved harvestability as an embodiment of the present invention.

Next, the lower inner side and the lower vertical frame 120 of the front vertical frame 110 of the mounting frame 10 from which the moving wheel 170 is separated, as shown in FIG. Can be inserted and fixed to a certain depth.

Alternatively, although not shown in the drawing, the mounting frame 10 may be installed at various locations such as the seawater installed on land may be accommodated inside the tank stored at a predetermined height.

The upper portion of the plurality of gimbal 50 together with the upper portion of the front vertical frame 110 and the rear vertical frame 120 of the mounting frame 10 may be exposed to a predetermined height in the upper direction of the sea water.

In this state, as the plurality of gimbal 50 is intermittently rotated along the one endless wire 30 and the other endless wire 40, a plurality of seaweeds 3 growing on the plurality of gimbal 50 are seawater. Intermittently exposed in the upper direction of the sterilized by the sun while the photosynthetic action to remove the seaweed and grow into healthy laver (3) resistant to pests.

7 is an exploded perspective view schematically showing a state in which the seawater injection unit is separated from an upper portion of the mounting frame, FIG. 8 is a combined perspective view of FIG. 7, and FIG. 9 is a side view schematically showing an example of an installation state of an underwater pump of the seawater injection unit. to be.

Next, in order to prevent the plurality of laver (3) growing in the plurality of gimbal (50) is exposed to the sun to dry out as shown in Figure 7 to 9 the front vertical frame ( The seawater is intermittently sprayed by the laver (3) located in the laver (50) exposed to the upper direction of the mounting frame (10) of the plurality of laver (50) on the upper side of the upper and rear vertical frame (120). Sea water injection unit 90 may be disposed.

The seawater injection unit 90 may include a seawater storage body 910, a plurality of injection nozzles 920, and an underwater pump 930.

Insertion shafts 911 which are detachably inserted into upper upper portions of the front and rear vertical frames 110 and rear vertical frames 120 of the mounting frame 10, respectively at the lower corners of the seawater storage body 910. This can be vertically formed.

Seawater may be stored inside the seawater storage body 910.

The plurality of injection nozzles 920 are provided in a plurality at a predetermined interval on the lower portion of the seawater storage body 910 arranged horizontally on the upper side of the mounting frame 10 to store the seawater stored in the seawater storage body 910. It may be intermittently sprayed with a plurality of steam (3) exposed to the sun.

The submersible pump 930 may be fixed to the bottom surface of the tank or the ground around the bottom of the mounting frame 10 is stored.

A connection hose 940 connecting the submersible pump 930 and the seawater storage body 910 may be provided between the submersible pump 930 and the seawater storage body 910.

The submersible pump 930 may pump the sea water and sequentially supply the seawater storage body 910 and the plurality of injection nozzles 920 through the connection hose 940.

10 is a partially cutaway side view schematically showing an example of the horizontal adjustment unit.

Next, the mounting frame 10 may be provided with a horizontal control unit 100 for adjusting the horizontal of the mounting frame 10.

As shown in FIG. 10, the horizontal adjustment unit 100 may be configured to include a withdrawal support 101 and a withdrawal member 102.

The withdrawal support 101 may be installed to be pulled outward from the lower inner side of the front vertical frame 110 and the lower inner side of the rear vertical frame 120 constituting the mounting frame 10.

The shaft member 171 of the movable wheel 170 may be detachably inserted into the lower inner side of the pull-out support 101.

The withdrawal member 102 may be composed of a lead screw 102a and a handle 102b to withdraw the withdrawal support 101.

The lead screw 102a is the inner and rear vertical frames of the front vertical frame 110 of the mounting frame 10 in a state where the lower part of the lead screw 102a is screwed to the upper inner side of the lead support 101. It may be vertically rotatable inside the 120.

An annular groove 102c may be formed on an upper outer surface of the lead screw 102a, and an annular groove 102c may be formed on an inner upper portion of the front vertical frame 110 and an inner upper portion of the rear vertical frame 120. A protrusion 180 may be formed to protrude in a direction and be inserted into the annular groove 102c.

The handle 102b may be connected and fixed in various ways, such as integrally formed or bolted to an upper portion of the lead screw 102a so as to be positioned in an upper direction of the upper and rear vertical frames 120 of the front vertical frame 110. have.

An insertion tube 102d into which the insertion shaft 911 of the seawater storage body 910 is inserted may be vertically formed at an upper center portion of the handle 102b.

11 is a partial cutaway side view schematically showing a state in which the horizontality of the mounting frame is adjusted through the horizontal adjustment unit.

The operator rotates the lead screw 102a forward and backward using the handle 102b to move the lead support 101 to the inner and rear vertical frames 120 of the front vertical frame 110 of the mounting frame 10. It can be drawn inwards or outwardly in the lower outer direction of the front vertical frame 110 and the lower outward direction of the rear vertical frame 120, and as a result, as shown in FIG. It is possible to more easily adjust the horizontal state of the mounting frame 10 accommodated in the tank where the sea water is stored.

Although not shown in the drawings, in order to more precisely adjust the horizontal state of the mounting frame 10, the upper outer surface of the front vertical frame 110, the scale portion may be formed on the upper outer surface of the rear vertical frame 120. have.

12 to 14 are side views schematically showing an example of a state in which one endless wire and the other endless wire are installed to be guided in a zigzag form.

Next, as shown in FIG. 12, the one endless wire 30 and the other endless wire 40 may be guided in a zigzag form between the top and bottom of the mounting frame 10.

For example, as shown in FIG. 12, an auxiliary vertical frame 190 may be formed on an upper portion of the second one side connection frame 152 of the mounting frame 10 and an upper portion of the second other side connection frame 162.

One auxiliary to face each other on the upper portion of the auxiliary vertical frame 190 formed on the upper side of the second one-side connecting frame 152 and the auxiliary vertical frame 190 formed on the second other side connecting frame 162. Pulley 200 may be rotatably coupled.

In addition, the two auxiliary pulleys 200 face each other at regular intervals in the vertical direction of the mounting frame 10 such that the first and second rear vertical frames 121 and 122 are positioned between the pulleys 20. It can be rotatably axially coupled.

The rear side of the one endless wire 30 and the rear side of the other endless wire 40 may be guided once in a zigzag form horizontally in the front and rear direction of the mounting frame 10 in a state spanning the auxiliary pulley 200, respectively. Can be.

In order to allow the rear side of the one endless wire 30 and the rear side of the other endless wire 40 to be guided in a zigzag form two or more times, as shown in FIG. 13, two auxiliary vertical frames 190 are provided. More than three auxiliary pulleys 200 and three or more auxiliary pulleys 200 may be rotatably coupled to the first and second rear vertical frames 121 and 122 at regular intervals in the vertical direction of the mounting frame 10. have.

Instead of the rear end of the one endless wire 30 and the rear end of the other endless wire 40, the front side of the one endless wire 40 and the front side of the other endless wire 40 are in the front-rear direction of the mounting frame 10. Of course, it may be guided in a zigzag form horizontally one or more times.

To this end, the two auxiliary pulleys 200 face each other at regular intervals in the vertical direction of the mounting frame 10 so as to be positioned between the pulleys 20 in the first and second front vertical frames 111 and 112. It can be rotatably axially coupled to view.

The front side of the one endless wire 30 and the front side of the other endless wire 40 may span the auxiliary pulley 200, respectively.

Alternatively, as shown in FIG. 14, both the front side and the rear side of the one endless wire 30 and the front side and the rear side of the other endless wire 40 are one or two or more times in the front and rear direction of the mounting frame 10. It may be guided in a zigzag form horizontally.

To this end, the auxiliary vertical frame 190 is formed at a predetermined interval in the front and rear direction of the mounting frame 10 on the upper portion of the second one side connection frame 152 and the second other side connection frame 162. The front auxiliary vertical frame 191 and the rear auxiliary vertical frame 192 may be configured.

At least one auxiliary pulley 200 may be rotatably coupled to the front auxiliary vertical frame 191 and the rear auxiliary vertical frame 192, respectively.

The front side of the one endless wire 30 and the front side of the other endless wire 40 are auxiliary of the auxiliary pulley 200 and the front auxiliary vertical frame 191 of the first and second front vertical frames 111 and 112. Each of the pulleys 200 may be zigzag-shaped.

The rear side of the one endless wire 30 and the rear side of the other endless wire 40 are auxiliary to the auxiliary pulley 200 and the rear auxiliary vertical frame 192 of the first and second rear vertical frames 121 and 122. Each of the pulleys 200 may be zigzag-shaped.

15 and 16 are side views schematically showing another example of a state in which one endless wire and the other endless wire are installed to be guided in a zigzag form.

As another example, as shown in Figure 15 is horizontally extended in a predetermined length in the front side of the mounting frame 10 in the middle portion of the first, second rear vertical frames 121, 122 of the mounting frame 10 The auxiliary horizontal frame 300 may be formed.

One auxiliary pulley 200 rotates to face each other on the front side of the auxiliary horizontal frame 300 of the first rear vertical frame 121 and the front horizontal frame 300 of the second rear vertical frame 122. Possibly axially coupled.

In addition, two auxiliary pulleys 200 are positioned in the front and rear directions of the mounting frame 10 so that the first one side connection frame 151 and the first other side connection frame 161 are positioned between the pulleys 20. It may be rotatably coupled to face each other at regular intervals.

The upper portion of the one endless wire 30 and the upper portion of the other endless wire 40 may be guided in a zigzag form vertically in the up and down direction of the mounting frame 10 in a state spanning the auxiliary pulley 200, respectively. Can be.

In order to allow the upper part of the one endless wire 30 and the upper part of the other endless wire 40 to be guided in a zigzag form two or more times, as shown in FIG. The auxiliary pulley 200 may be axially rotatably coupled to the front and rear directions of the mounting frame 10 at a predetermined interval.

In addition, at least three auxiliary pulleys 200 may be rotatably coupled to the first one side connection frame 151 and the first other side connection frame 161 at predetermined intervals in the front and rear directions of the mounting frame 10. Can be.

As the one endless wire 30 and the other endless wire 40 are guided in a zigzag form, the plurality of gimbal 50 may also be divided into a plurality of stages so as to be guided in a zigzag form. More and more seaweed can be farmed in the place, which will greatly improve the yield.

According to the present invention configured as described above, the spores are drawn along the one endless wire 30 and the other endless wire 40 wound on the mounting frame 10, the upper portion of which is exposed at a predetermined height in the upper direction of seawater. Rotating a plurality of the gimbal (50) intermittently to be able to cultivate a high quality seaweed while being resistant to pests in a holding-type seaweed farming method, as well as to produce a larger amount of seaweed without place constraints significantly improve the harvesting yield It can be, furthermore, there is no need to use waste hydrochloric acid to grow the seaweed in the holding-type seaweed farming method rather than the class-style seaweed farming, there is no advantage that the seawater environment due to the waste hydrochloric acid is rapidly destroyed.

10; Frame, 20; Pulley,
30; One endless wire, 40; Other endless wire,
50; Kimbal.

Claims (8)

A mounting frame having an upper portion exposed to a predetermined height in an upper direction of the sea water;
Pulleys respectively provided on both front and rear sides of the upper portion of the mounting frame and on the front and rear sides of the lower portion;
One endless wire which is rotated in a state in which it is wound around a pulley positioned at each of the front and rear one side and the front and back one side of the lower part of the mounting frame;
The other endless wire which is rotated while being wound around a pulley positioned respectively at the front and rear other parts of the upper part and the front and rear other parts of the lower part of the mounting frame;
A plurality of gimbal with both ends fixed at regular intervals between the one endless wire and the other endless wire, and laver spores;
It provides a resilient holding type seaweed cradle, characterized in that it comprises a; drive member for intermittently rotating the one endless wire and the other endless wire.
The method of claim 1,
Harvesting-provided holding type seaweed cradle, characterized in that the one endless wire and the other endless wire is provided with a plurality of wire connectors connected at both ends of the plurality of gimbal to be idle.
The method of claim 2,
The holding type seaweed cradle with improved harvestability, characterized in that coupled to the inner surface of the pulley is rotated along the pulley and the rotary gear is wound around the plurality of wire connectors.
The method of claim 1,
The one endless wire and the other endless wire is zigzag guide is improved between the upper and lower portions of the mounting frame characterized in that the holding type seaweed cradle.
The method according to claim 1 or 4,
On the upper side of the mounting frame is a seaweed spraying unit for improved harvestability, characterized in that the seawater injection unit for injecting seawater to the gimbal exposed to the upper portion of the mounting frame of the plurality of gimbal.
The method of claim 5,
The seawater injection unit is harvested, characterized in that consisting of a plurality of injection nozzles disposed on the upper side of the mounting frame, and an underwater pump that is fixed to the lower portion of the mounting frame to supply the seawater to the plurality of injection nozzles through a connection hose Holding style seaweed cradle with improved sex.
The method according to claim 1 or 4,
The holding frame is a holding type seaweed cradle with improved harvestability, characterized in that the horizontal adjustment portion for adjusting the horizontal of the mounting frame is provided.
The method of claim 7, wherein
The horizontal adjuster is a holding type gimyeochidae improved harvestability, characterized in that it comprises a withdrawal support that is installed to be pulled out to the lower end of the mounting frame, respectively, and a withdrawal member for withdrawing the withdrawal support.

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