前苏联专利SU1711654A3 Sea fish rearing farm

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优先权

专利摘要:
The invention relates to a fish farm designed to be located in deep sea, and designed for intensive production of fish, constituted by a cultivation cage (1) designed to be submerged and kept at a considerable depth, provided with ballast tanks (6) which allow the adjustment of such depth, adjusting same to the suitable temperature level of the water, the upper end of such cultivation cage (1) extending into a hollow column (7), with a minimum floating area, and which is provided on its upper end with a tower (8) containing the personnel facilities and which projects from the surface of the water likewise being kept outside the scope of influence of the waves, as is the case of the lower cultivation cage (1), wherefore the stability of the fish farm is maximum.
公开号:SU1711654A3
申请号:SU884356867
申请日:1988-11-01
公开日:1992-02-07
发明作者:Отаменди Бусто Сантьяго
申请人:Santyago Otamendi Busto；
IPC主号:

专利说明:

FIELD OF THE INVENTION The invention relates to the fishing industry, in particular the aquaculum.
The well-known sea farm for fish breeding, consisting of a vertical cylinder with buoyancy and containing service and living quarters in its upper part, and reservoirs for animal feed, fresh water, combustible ballast tanks and so on in its middle part, in the lower part the cylinder is a retainer, in addition, the cylinder is equipped with tanks for growing aquatic organisms, with the vertical cylinder connected to the main tools.
The known device has a number of disadvantages, in particular, the farm cannot be placed at a considerable distance from the water surface, which leads to fouling of the cages, entanglement of networks, blocking them and preventing water renewal or oxygenation. In addition, cages cannot be large due to the effects of waves.
The purpose of the invention is to increase productivity, simplify the process of cleaning the grid.
The ka of Fig. 1 depicts a marine fish farm, side view (a table of temperatures corresponding to different depths is shown, as well as a cross section of an imaginary wave and its energy formed on the mass of water); figure 2 - the same, another version; on fig.Z - the same, side view.
The proposed fish farm consists of a tank 1 for breeding fish, forming a cylindrical structure based on annular elements reinforced with beams and crossbars designed to support the grid that completely surrounds cage v (not shown).
The ring-shaped elements form a large cylindrical container, which has a diameter of 25 m and a length of 50 m and is installed in water with its axis in an upright position.
In addition, the tank 1, also strengthened by the lower keel 2, contains a prismatic container 3 mounted on top of it and on one of its forming surfaces and extending along its length, inside of which several ballast tanks are placed, which allow the depth of the fish-fish to be adjusted. - water cell, and a shorter nyc k core mounted on container 3, divided into sections using several intermediate partitions
5, while the housing 4 is also provided with ballast tanks 6.
From the center of the body b stands
.la column 7, having a sufficient i length so; so that the tower 8 fixed at its upper end is located above the surface of the water 9, while the tower 8 is also provided with a large number of partitions 10 in which various services for the staff of the fish farm are located, i.e. bedrooms, toilets, kitchens, service rooms, etc., and
equipment for larvae and fry of fish. The column can also house tanks for reproductive animals, and in the lower prismatic buildings associated with the cylindrical design, forming the fish breeding cage itself, there are food stores, food dosing units, as well as chambers of larvae and fry along with ballast tanks and them into action. Regardless of the ballast means, the remaining compartments of these upper elements may vary depending on the building construction, which is considered convenient.
0
five
0
0
for each case.
Such a fish farm design makes it possible to place fish-water tank 1 outside the zone of influence of waves 11, with orbits diameter 12, described by water particles during the passage of waves, and therefore the effect of waves on tank 1 is practically absent, and the waves affect only a column 7 having a small diameter and a very small floating surface, which are practically irrelevant to the waves and do not affect the tower 8.
In accordance with this design, the fish farm can be installed in any deep-water location, secured to the seabed by any appropriate means, for example, by means of cables attached to the an- ®camera 13 on the keel 2, while the fish divider 1 is located outside the zones are affected by both waves and solar heat, and at an appropriate level so that the temperature in, 5 of tank 1 is constant. With the help of ballast tanks, carrying out the raising and lowering of the structure, the structure is reached, not sub-:
five
The favorable effects of the waves, the optimal temperature conditions for the growth of the fish and the optimal flow of water in the fish-breeding tank with the minimum need for cleaning the closing one. e: mesh.
Marine farm works as follows.
A marine fish farm is established for fish farming. It is not exposed to waves, provides optimal temperature control and minimal growth of algae on the surrounding grid or in its nests. Fish divorce capacity can be submerged to a considerable depth below wave energy, while staff support facilities are above water level. Moreover, the two parts of the marine fish farm, i.e. the submerged fish cage and the service equipment are connected by a column or tube of small diameter, which practically forms a floating surface and is the only element subject to wave action, as a result of which the stability of the fish farm is optimal.
The fish-breeding tank contains a cylinder with a diameter of 25 m and a length of 50 m (which is almost impossible to hold on the surface with a wave height of 22 m), while the cage is set at a depth of 25 - 50 m, completely avoiding wave action, which also important for service equipment located above the surface of the sea.
The temperature and the fraction of oxygen dissolved in water are more dependent on the depth. The fish-breeding tank can be submerged, and its depth can be adjusted as desired, in connection with which the cage is equipped with adjustable ballast tanks providing vertical cage displacement of approximately 25 m, with the result that its position can vary between maximum height m a minimum height of 30-55 m. The temperature is monitored using three sensors installed in the upper, central and lower parts of the cell, thereby temperature and oxygen dissolved
0
five
in a 25 meter water column, they are fixed automatically permanently, so for each tank there can be
An optimal choice has been made.
Such a submerged position, which is considerably remote from the surface, makes it possible to minimize the possibility of netting caused by the growth of algae, since. they grow rapidly on the surface where maximum heating takes place, whereas the fish farm of the fish farm is located
5 at depths of 30–35 m, where there is no solar heating, and therefore, algae are practically absent. However, nets of such huge fish-diverting tanks can attract some types of young fish: poliqudus, balanus, etc., as well as algae that need to be cleaned to maintain maximum water flow.
Formula of invention
A marine farm for breeding fish, including a fish-carrying capacity, a vertical cylinder equipped with ballast tanks for providing buoyancy, on which a keel tank is installed in the lower part and a tower containing personnel equipment and a feed tank are installed in the lower part of the water. characterized in that, in order to increase productivity, simplify the process of cleaning the mesh, the fish tank is a skeleton of rings and longitudinal and transverse beams, over which and the grid to form cell
5 with a length of 5) m and a height of 25 m, the central part of the vertical cylinder is made in the form of a hollow column, the height of which ensures that the fish tank is placed at a depth of 5-30 to 0-55 m from the surface of the water, with this ballast tanks are installed in a prismatic elongated body reinforced on the top forming fish-breeding tank, and in the tower additionally installed operational equipment, including chambers for larvae and fry
five
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eight
Phil, 1
13
2

权利要求:
Claims (1)
[1]
The claims are the only element exposed to waves, as a result of which the stability of the fish farm is optimal. ·.
The fish hatchery contains • a cylinder with a diameter of 25 m and a length of 50 m (which is almost impossible to keep on a surface with a wave height of 22 m), while the cage is installed at a depth of 25 - 50 m, completely avoiding the effects of waves, which is also important for maintenance equipment, located above the surface of the sea.
The temperature and proportion of oxygen dissolved in water is highly dependent on depth. The fish hatchery can be immersed, and its depth can be adjusted. If desired, the cage is equipped with adjustable ballast tanks that provide vertical movement of the cage by about 25 m, as a result of which its position can vary between a maximum height of 5-30 m and the minimum height is 30-55 m. The temperature is controlled by three sensors installed in the upper, central and lower parts of the cell, thereby the temperature and oxygen dissolved
Marine fish farm, including a fish breeding tank, a vertical cylinder equipped with ballast tanks to ensure buoyancy, on which a keel tank is installed in the lower part, and a tower containing personnel and a feed tank is installed in the upper part above the water surface the fact that, in order to increase productivity, simplify the process of cleaning the net, the fish breeding tank is a frame of rings and longitudinal and transverse beams, over which the set is fixed with the formation of a cell with a length of 5 ⁽ 1 m and a height of 25 m, the central part of the vertical cylinder is made in the form of a hollow column, the height of which ensures the placement of fish hatcheries at a depth of 5-30 to 40-55 m from the surface of the water, while ballast tanks are installed in a prismatic elongated housing, mounted on the upper generatrix of the fish breeding tank, and in the tower additionally installed operational equipment, including cameras for larvae and fry

类似技术:

公开号 | 公开日 | 专利标题

SU1711654A3|1992-02-07|Sea fish rearing farm

US6712023B2|2004-03-30|Culture of sessile marine animals

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同族专利:

公开号 | 公开日

DK606688A|1989-05-03|

BR8805660A|1989-07-18|

NO169932C|1992-08-26|

NO169932B|1992-05-18|

YU203188A|1991-02-28|

DK606688D0|1988-10-31|

PL275592A1|1989-06-12|

ZA888199B|1989-07-26|

IS3410A7|1989-01-09|

ES2008304A6|1989-07-16|

AU611729B2|1991-06-20|

PT88905A|1989-09-14|

FI885054A|1989-05-03|

TNSN88114A1|1990-07-10|

IL88250D0|1989-06-30|

US4936253A|1990-06-26|

NO884871L|1989-05-03|

CN1036122A|1989-10-11|

JPH0514B2|1993-01-05|

KR890007635A|1989-07-05|

EP0315561A2|1989-05-10|

AU2456988A|1989-05-04|

MA21421A1|1989-07-01|

SE9001397D0|1990-04-19|

EP0315561A3|1989-10-18|

FI885054A0|1988-11-02|

JPH01187038A|1989-07-26|

KR930000121B1|1993-01-09|

NO884871D0|1988-11-01|

引用文献:

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JPH0254053B2|1983-10-25|1990-11-20|Shugo Abe|

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JPH0311733B2|1984-11-15|1991-02-18|Takashi Mori|

SE446053B|1984-11-21|1986-08-11|Farmocean Ab|DEVICE FOR CULTIVATING FISH IN A NET BOX WHICH IS COLLECTED BY A PONTON WHERE'S DEPARTURE IS VARIABLE|

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US5438958A|1993-11-18|1995-08-08|Ericsson; John D.|Platform supported mariculture system|

ES2174759B1|2001-04-11|2003-12-16|Busto Santiago Otamendi|FISHING, FISHING AND TRANSPORTATION FISHING VESSEL|

NO20031504L|2003-04-02|2004-10-04|Rune Haug|Device for supply vessel for fish feed|

US8028660B2|2006-10-10|2011-10-04|Hawaii Oceanic Technology, Inc.|Automated positioning and submersible open ocean platform|

US9655347B2|2006-10-10|2017-05-23|William A Spencer, Jr.|Automated open ocean fish farm structures and systems for open ocean fish farming|

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KR101024386B1|2011-01-20|2011-03-23|엔엔티시스템즈|Automatic feeding system for underwater fish cages|

JP6351580B2|2012-06-14|2018-07-04|フィリップスライティングホールディングビーヴィ|Lighting system for improving the growth of aquatic organisms|

FR2996722A1|2012-10-17|2014-04-18|Serge Menard|AQUACULTURE INSTALLATION OF HIGH SEA|

CN102972317B|2012-12-11|2015-03-18|浙江海洋学院|Netting for fast collecting fish|

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CN103430878B|2013-08-12|2014-12-31|中国水产科学研究院东海水产研究所|Upright pile for surrounding cultivation net|

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CN104686410A|2013-12-05|2015-06-10|包顺柳|Modern intensive fast fish farm|

WO2016128981A1|2015-02-11|2016-08-18|Agro Shipping Ltd.|Open sea fish farming|

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法律状态:

优先权:

申请号 | 申请日 | 专利标题

ES8703125A|ES2008304A6|1987-11-02|1987-11-02|marine fish farm.|

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