KR101010473B1 - Equipment and Container For Cultivating Lugworm - Google Patents

Abstract

The present invention consists of a support body 110, a concave and bottom body 121 having a through hole 123 formed on the bottom and a drainage means 130 is installed in the through hole 123 and a plurality of stacked on the support 110 A culture vessel (120) and seawater supply means (140) for supplying seawater to the culture vessel (120); The drainage means 130 is inserted into the through hole 123 and protrudes into the concave body 121 formed therein, and has a first pipe body 131 having an internal threaded portion 131 a on an inner diameter surface thereof, and the first pipe body 131. Male threaded portion (135a) is formed on the outer diameter surface to be screwed to the) and the lug is configured to include a second tube (135) protruding to the upper portion of the first tube 131 is screwed to the first tube (131) To the culture apparatus 100; In the seawater supply process, a concave groove is formed in the upper part of the breeding soil 129 or a problem that the food and the breeding soil 129 are mixed does not occur, and when the draining the breeding soil 129 is prevented from leaking, drainage In the process, the seawater penetrates into the breeding soil 129 and there is no fear of affecting the habitat environment of the worms, and an environment similar to the real tides is formed, and it is easy to change the seawater height, and when draining, the second pipe 135 is formed. There is no effect to worry about losing.

Lugworm, culture, device

Description

Earthworm Cultivating Lugworm {Equipment and Container For Cultivating Lugworm}

The present invention relates to a worm worm cultivation apparatus and a culture vessel, it is possible to form a large volume, to create an environment similar to when tidal, there is no fear of losing the land soil when draining, easy to adjust the height of seawater, drainage The invention relates to a worm cultivation device and a culture vessel without fear of loss of test parts.

A lugworm is an annulus that lives in a tidal flat in the sea. It swims underwater and eats at night, and during the day, it burrows oysters into the tidal flat and hides and supplies oxygen from the tidal flat. The lugworms are known to eat algae and shellfish and shellfish such as seaweed and shellfish carried by the seawater at the time when fresh seaweed and organic matter can be supplied by seawater. These lugworms have long been used as fishing baits in Japan, the United States, and Europe as well as in Korea. In addition, the lugworm is spotlighted as a beneficial aquatic organism that improves the environment of the tidal flat by ingesting organic matter in the tidal flat and decomposing it into inorganic substances, and local governments and the like release large amounts of tidalworms to protect the tidal flat environment.

 1 is a perspective view showing a worm farming device according to the prior art, Figure 2 is a plan view of the farming device shown in Figure 1, Figure 3 is a part showing a breeding box provided in the worm farming device shown in Figure 1 It is a cutaway perspective view, and FIG. 4 is sectional drawing of the breeding box which shows the breeding state of a worm.

As shown in FIG. 1 and FIG. 2, the worm farming apparatus according to the prior art includes a breeding tank 10 having a rectangular shape and a plurality of breeding boxes 20 sequentially arranged along the longitudinal direction of the breeding tank 10. And seawater supply means 30 for supplying seawater to the breeding box 20.

The breeding tank 10 is divided into a number of dogs using a partition member 11 made of a material such as concrete in the breeding facility. Both sides of the breeding tank 10 in the longitudinal direction are provided with water inlets 12 and drains 13, respectively, so as to selectively supply and discharge seawater necessary for the growth of the earthworm.

The breeding box 20 is a component that defines a space in which the lugworm is bred. As shown in FIGS. 3 and 4, the breeding box 20 includes a main body 21 having a box shape having an upper opening, a breeding soil 22 embedded in the main body 21, and the main body ( A plurality of drain holes 23 formed on the lower surface of the 21, a permeable blocking member 24 covering the drain holes 23, and the worm feed 25 is supplied to the upper portion of the breeding soil 22 do. The drainage hole 23 formed in the lower surface of the main body 21 is for smoothly draining the seawater supplied to the breeding box 20, and during breeding, the breeding soil 22 feeds the breeding box through the drainage hole 23. The permeable blocking member 24 is attached to the lower surface of the main body 21 in the form of blocking the drain hole 23 in order to prevent the flow out to the lower portion of the 20.

The seawater supply means 30 is disposed along the longitudinal direction at the center of the breeding tank 10 to uniformly supply the seawater directly to the top of the breeding box 20 disposed on the left and right sides, respectively. As shown in FIG. 2, the seawater supply means 30 is constituted by a conduit 31 in which seawater is filled with a predetermined water pressure. A plurality of nozzle holes 32a and 32b through which seawater is injected are provided on the pipeline.

However, since the sea worm farming apparatus according to the prior art as described above, the seawater is supplied through the nozzle holes 32a and 32b, concave grooves may be formed in the upper part of the breeding soil 22 by the supplied seawater, and breeding at the time of drainage. Since it flows through the soil 22 and is drained to the drainage hole 23, it affects the habitat environment of the worm, as the oysters formed in the breeding soil 22 are destroyed by the drainage. To prevent the loss of (22), but can not prevent the ground soil 22 is lost at the time of drainage, because the blocking member 24 is installed, the time required for drainage becomes a long time, to adjust the height of the sea water It is impossible, and there was a problem that it is impossible to control the time that the sea water is supplied to the top of the breeding soil (22).

The worm worm culture device according to the present invention proposed to solve the above problems consists of a support, a concave and bottom body formed with a through hole and a drainage means installed in the through and a plurality of culture vessels are placed on the support And seawater supply means for supplying seawater to the culture vessel; The drainage means is inserted into the through hole and protrudes into the concave main body and has a first threaded body having an internal threaded portion formed therein, and a male threaded portion formed on the outer diameterd surface so as to be screwed to the first tubular body, and screwed into the first tubular body. And a second tube which protrudes to the upper portion of the first tube.

The first tube is characterized in that it further comprises an expansion portion is expanded in the upper portion.

The seawater supply means is a seawater supply pipe provided in parallel with the loading direction of the culture vessel, one end is connected to the seawater supply pipe and the other end is a seawater supply tube located in the culture vessel, and the seawater located in the culture vessel Characterized in that it comprises a buffer mechanism made of a porous elastic body provided at the end of the feed tube.

The support includes a vertical frame extending upward from the ground, one or more support frames connected horizontally and vertically spaced apart from the ground, and a reinforcement frame connecting the support frames of each layer. Is configured; The culture vessel is characterized in that it is stacked on top of the support frame.

On the other hand, the worm worm culture vessel according to the present invention is formed concave and includes a main body having a through hole formed on the bottom surface, the drain means provided in the through hole; The drainage means is inserted into the through hole and protrudes into the concave main body and has a first threaded body having a female threaded portion formed therein, and a male threaded portion formed on the outer diameterd surface so as to be screwed to the first tubular body, and screwed into the first tubular body. It is characterized in that it comprises a second tube which is fastened to protrude to the upper portion of the first tube.

The first tube body is characterized in that it further comprises an extension portion is expanded in the upper portion.

At least one through hole or through hole is formed in the second tube in a radial direction.

According to the worm worm cultivation apparatus and the culture vessel according to the present invention, due to the seawater supplied in the sea water supply process, a concave groove is formed in the upper portion of the breeding soil 129 provided in the culture vessel 120 or feed fed to the breeding soil top There is no problem of mixing with the breeding soil 129, and having a first tubular body 131 and a second tubular body 135 and by fitting the end of the first tubular body 131 and the rearing soil 129 During drainage, the breeding soil 129 may be prevented from leaking, and since the seawater flows from the upper portion of the breeding soil 129 into the first tube 131, the seawater penetrates into the breeding soil 129 during the draining process. There is no fear of affecting the habitat environment, and an environment similar to the actual tide is created, and it is easy to change the seawater height by adjusting the protruding height of the second tube 135, and the through hole to the lower portion of the second tube 135 Or by forming the through hole 136, the second To the body 135, it is possible to drain without completely separated from the first tube body 131, it becomes easy to drain there is an effect that is not a fear of losing the second tube 135.

Hereinafter, with reference to the drawings will be described in detail a worm worm culture device and a culture vessel according to a preferred embodiment of the present invention.

Figure 5 is a partial schematic perspective view showing a worm cultivation apparatus according to the present invention, Figure 6 is a schematic partial perspective view showing a support provided in the worm cultivation apparatus of the present invention, Figure 7 shows a worm culture vessel of the present invention FIG. 8 is a cross-sectional view taken along line AA of FIG. 7, and FIG. 9 is an enlarged view of a portion A of FIG. 5, and FIGS. 10 and 11 are perspective views illustrating a second tube provided in the culture vessel. to be.

As shown in FIG. 5, the worm worm culturing apparatus 100 according to the present invention includes a support 110, a plurality of culture vessels 120 stacked on the support 110, and seawater with the culture vessel 120. It comprises a sea water supply means 140 for supplying. And it may further include an air supply means 150 for supplying air to the sea water supplied to the culture vessel 120.

The support 110 is a vertical frame 113 that extends vertically from the ground as shown in Figures 5 and 6, and one or more layers of horizontal support spaced apart from the ground and connected to the vertical frame 113 Frame 115 and 117, the bottom of the vertical frame 113 may further include a base frame 111. When the base frame 111 is provided, the base frame 111 is installed on the ground, and when the base frame 111 is not provided, the lower end of the vertical frame 113 may be fixed to the ground. The vertical frame 113 and the support frame (115, 117) can be installed in pairs, each pair is preferably connected to each other by a connecting frame 112 as shown in FIG. The support frames 115 and 117 may of course have a plate shape. The support 110 may be made of metal or synthetic resin.

Hereinafter, for convenience of description, the support frame of one layer provided to be spaced apart from the ground is called the first support frame 115, and the support frame of the second layer is referred to as the second support frame 117.

As shown in FIG. 5, the plurality of culture vessels 120 are stacked on top of the support frames 115 and 117. One side of the support 110 is provided with sea water supply means 140. The seawater supply means 140 includes a seawater supply pipe 141 extending in the stacking direction of the culture vessel 120 and a plurality of seawater supply tubes 143 having one end connected to the seawater supply pipe 141. The other end of the seawater supply tube 143 is located in the culture vessel 120. The seawater supply tube 143 is preferably connected to the seawater supply pipe 141 at the same interval as the spacing of the culture vessel 120. The sea water supply pipe 141 is connected to a sea water supply tank (not shown) through a pump (not shown). The seawater supply tube 143 is preferably formed of a flexible material such as vinyl.

At the end of the seawater supply tube 143 toward the culture vessel 120 is provided with a buffer mechanism 145 made of a porous elastomer such as a sponge as shown in FIGS. 5, 7 and 9. As shown in FIG. 9, the shock absorbing mechanism 145 is installed as an elastic body 147 at the end of the seawater supply tube 143. When the buffer mechanism 145 provided with the elastic body 147 is provided as shown in FIG. 9, the seawater supplied through the seawater supply tube 143 is supplied through the fine holes of the buffer mechanism 145, so that the soil is fed by the seawater supply. There is no fear that a recess or the like in the upper portion of 129 will occur.

The air supply means 150 is an air supply pipe 151 extending in the stacking direction of the culture vessel 120, one end is connected to the air supply pipe 151, the other end of the plurality of air located in the culture vessel 120 Consisting of a feed tube 153, the feeder 153 which is a porous body toward the culture vessel 120 is provided. A pump (not shown) for supplying air is connected to the air supply pipe 151.

The culture vessel 120 has a concave shape as shown in Figs. 5 and 8, the main body 121 having a through hole 123 formed on the bottom thereof, and drainage means provided in the through hole 123 of the main body 121 ( 130).

The drainage means 130 has a first tubular body 131 inserted into the through hole 123 and a second tubular body 135 detachably provided to the first tubular body 131. The first tubular body 131 is a hollow pipe and is inserted into the through hole 123 so that the upper portion protrudes into the concave body 121. The breeding soil 129 is introduced into the main body 121 to reach the height of the first tubular body 131 protruding into the concave main body 121. It is also possible to inject the breeding soil 129 higher than the protruding height of the first tubular body 131, but may be lost to the outside through the first tubular body 131 together with the sea water at the time of drainage. The first tubular body 131 has an internal threaded portion 131a having an inner diameter surface. After inserting the first tubular body 131 into the through hole 123 in the above, it is possible to insert or fix the adhesive between the outer diameter surface of the first tubular body 131 and the through hole 123, or to be inserted by interference fit. .

As shown in FIGS. 8, 10, and 11, the second tubular body 135 has a male thread portion 135a fastened to the female thread portion 131a on the outer surface of the hollow piper. The first tube 131 has an extension 133 having an increased diameter at the top thereof.

The second tubular body 135 is screwed to the first tubular body 131 and protrudes above the first tubular body 131. When the breeding soil 129 is introduced into the main body 121 and the seawater is supplied, the height of the seawater cannot be higher than the upper end surface of the second tubular body 135, and thus the seawater height is increased by the protruding height of the second tubular body 135. It is possible to adjust. It is of course possible to insert and install the 2nd tubular body 135 inside the 1st tubular body 131, without forming a threaded part in the 1st tubular body 131 and the 2nd tubular body 135 in the above. The first tube 131 is provided with an extension 133 at an upper portion thereof, such that a gap is formed between the first tube 131 and the second tube 135 at an upper portion of the first tube 131.

As shown in FIG. 8, the first tube 131 is inserted into the through hole 123 of the main body 121, and the second tube 135 is coupled to the first tube 131. It is possible to adjust the height of the breeding soil 129 and the height of the seawater 125 by feeding the breeding soil 129 as the projecting height of the first tube 131, and supplying seawater.

At least one through hole or through hole 136 is formed in the lower portion of the second tube 135 as shown in FIGS. 10 and 11. Through-holes or through-holes 136 are formed in the lower portion of the second tube (135) as described above, without separating the second tube (135) from the first tube (131), the through-holes or through-holes ( It is possible to drain the seawater 125 by allowing 136 to be exposed. Therefore, drainage is easy and there is no fear of losing the second tube 135.

When the second tubular body 135 is separated from the first tubular body 131 for drainage, or a through hole or through hole 136 is formed and the through hole or through hole 136 is exposed, the seawater is indicated by an arrow in FIG. 8. As shown in the drawing through the inside of the first tube 131 is discharged to the outside. Therefore, during the drainage process, the interior of the breeding soil 129 is not affected, so that the oysters formed by the worms do not have to worry about collapse in the drainage process.

The support provided in the worm worm cultivation apparatus 100 of the present invention may be provided with one or more support frames 115 and 117, and the culture vessel 120 may be disposed above the support frames 115 and 117 of each layer. It is loaded. As shown in FIGS. 5 and 6, the seawater drained from the culture box 120 disposed on the first support frame 115 spaced apart from the ground falls to the ground, and the second support frame 117. Seawater drained from the culture box 120 to be stacked may fall into the culture box 120 stacked on the first support frame 115. The curved elbow 137 is inserted into the lower portion of the first tube 131 of the culture box 120 loaded on the second support frame 117, and the connecting tube 139 is inserted into the other end of the elbow 137. It is possible to drop the drainage to the ground. Of course, it is also possible to install the culture box 120 is placed on the second support frame 117 to protrude more than the culture box 120 is placed on the first support frame 115.

In FIG. 8, reference numeral 127 illustrates a lugworm feed supplied to the culture box 120.

While the invention has been shown and described in connection with specific embodiments thereof, it is conventional in the art that various changes, modifications and variations are possible without departing from the spirit and scope of the invention as indicated by the appended claims. Anyone who knows the knowledge of is easy to know.

1 is a perspective view showing a lugworm breeding tank according to the prior art.

2 is a plan view of the worm breeding tank shown in FIG.

3 is a perspective view showing a part of the breeding container provided in the worm breeding tank of FIG.

4 is a cross-sectional view showing a breeding container provided in the lugworm breeding tank of FIG.

Figure 5 is a schematic partial perspective view showing a worm cultivation apparatus according to the present invention.

Figure 6 is a partial perspective view showing the support provided in the worm worm culture device of the present invention.

Figure 7 is a schematic perspective view showing a culture vessel provided in the earthworm culture apparatus of the present invention.

FIG. 8 is a schematic cross-sectional view taken along the line A-A of FIG. 7.

9 is an enlarged view of a portion A of FIG. 5.

10 and 11 are schematic perspective views showing a second tube provided in the culture vessel.

** Description of the main parts of the drawing

100: culture device 110: support

111: base frame 112: connection frame

115: first support frame 117: second support frame

120: culture vessel 121: main body

130: drainage means 131: first pipe

135: second tube 140: sea water supply means

141: seawater supply pipe 143: seawater supply tube

145: shock absorber 150: air supply means

Claims (7)

A plurality of culture vessels consisting of a support body 110, a concave body having a through hole 123 formed on the bottom surface and a drainage means 130 installed in the through hole 123 and disposed on the support 110 ( 120, and seawater supply means for supplying seawater to the culture vessel (120); The drainage means 130 is inserted into the through hole 123 and protrudes into the concave body 121 formed therein, and has a first pipe body 131 having an internal threaded portion 131 a on an inner diameter surface thereof, and the first pipe body 131. A male screw portion (135a) is formed on the outer diameter surface so as to be screwed to the) and is configured to include a second tube (135) protruding to the upper portion of the first tube 131 is screwed to the first tube (131) Lugworm culture device 100 characterized in that. The method according to claim 1, wherein the first tube 131 is a worm cultivation device (100), characterized in that it further comprises an extension portion (133) having an enlarged diameter in the upper portion. According to claim 1, The seawater supply means 140 is a seawater supply pipe 141 is provided in parallel with the stacking direction of the culture vessel 120, one end is connected to the seawater supply pipe 141 and the other end is the culture It is configured to include a buffer mechanism 145 made of a seawater supply tube 143 positioned in the vessel 120 and a porous elastic body provided at the end of the seawater supply tube 143 of the culture vessel 120 side Lugworm culture device 100, characterized in that. According to claim 1, The support 110 is a vertical frame 113 extending upwards from the ground, one or more layers horizontally connected to the vertical frame 113 spaced apart from the ground in the upward direction A frame and a reinforcing frame 112 connecting the support frames of each layer; The culture vessel 120 is a worm cultivation device 100, characterized in that the upper portion of the support frame. It is formed concave and includes a main body 121 having a through hole (123) on the bottom, and the drain means 130 provided in the through hole (123); The drainage means 130 is inserted into the through hole 123 and protrudes into the concave body 121 formed therein, and has a first pipe body 131 having an internal threaded portion 131 a on an inner diameter surface thereof, and the first pipe body 131. A male screw portion (135a) is formed on the outer diameter surface so as to be screwed to the) and is configured to include a second tube (135) protruding to the upper portion of the first tube 131 is screwed to the first tube (131) Lumberjack culture vessel 120 characterized in that. The method of claim 5, wherein the first tube 131 is a worm culture vessel (120), characterized in that it further comprises an expansion portion (133) having an enlarged diameter in the upper portion. 7. The worm culture vessel (120) according to claim 6, wherein at least one through hole or through hole (136) is formed in the second tube (135) in a radial direction.

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