DE102010032673A1 - Axial, cylindrical pipe construction for use in fish cage, has ballast chambers that are stable and flexible in axial, cylindrical sectional spaces, where ballast chambers control complete cage only with corresponding air volume - Google Patents

Abstract

The pipe construction has ballast chambers (2) that are stable and flexible in the axial, cylindrical sectional spaces, where the ballast chambers control a complete cage only with corresponding air volume in each desired depth. Three pipes are welded with steel plates and form ballast chambers for water and air and so control the cage in each desired depth. Independent claims are also included for the following: (1) a window for a fish cage; (2) a cylinder with compressed air and rubber containers; (3) a porous air tube that is fixed to the longitudinal strut of the fish cage; (4) a liquid- and air feeding pipe system; (5) a feeding device for feeding the intake of food pellets into a water stream; (6) a harvest fish net; and (7) a fish sorting grade with a fish harvesting device.

Description

Request for additional patents for:

System, technology, function and method of mobile and submersible fish cages for the open sea Reference 10 2008 057 515.1

The patent application of 13.11.2008 by Siegfried Beck with the file number: 10 2008 057 515.1 at the German Patent Office in Munich, was with an additional application on 10/10/2009 with the file number 10 2009 048 948.7 supplemented, which must be modified according to the letter dated 26.01.2010 (Examining Office 23) of the German Patent Office so that the additional patent in the case of self-employment have self-contained documents.

This will change the attachments: 3. Summary 1 Page; 4. Description with list of reference numbers 7 pages; 5. Claims 22-2 pages; 6. Sheet drawings 7.

In the patent application of 13.11.2008 is described:

The innovative, new system is a stable, cylindrical and horizontally floating fish cage (A) - 1 , Longitudinal section and cross section (3D) of the fish cage.

In the center, over the entire length of the cylindrical cage, the axial service pipe ( 1 ). In and around the service tube are the ballast chambers ( 2 ) for air or water to control the entire cage at any desired depth.

This axial service tube ( 1 ) gives the cylindrical cage the central stability. From the service tube ( 1 ) go spoked wheels ( 3 ) to the cylindrical outer frame with longitudinal struts ( 4 ) and round struts ( 5 ), which are firmly connected to each other at the crossing points. The cage ends are conical or semicircular for static reasons. Depending on the length of the cage, there are several sections ( 7 ). Each section is about 10 m wide. A standard cage is 100 m long with a diameter of 16 m and a volume of approximately 20,000 m ³ . Cage structures with a volume of 50,000 m ³ and more are feasible. Fishing nets ( 8th ) are stretched around the cylindrical cage and the separation of the sections.

The fish cage has only one traction point ( 6 ) and floats with the current 4 B-1, so that no lateral waves damage the cage and stress the fish. From the train and anchor point ( 6 ) of the fish cage, a pull rope leads over the navigation buoy ( 13 ) to the fixed anchorage or fishing boat. The service and air pipes, as well as the feeding pipes lead over the buoy ( 9 ) to the fishing boat. Both buoys are separable with a quick-release coupling to separate the cage from the trawler and lower it below deep troughs can. The different swimming positions of the fish cages are in 4 explained.

Addition to the patent application

The axial service pipe ( 1 ) of fish cage A 1 , can be replaced by two design variants.

Variant 1 is Fig. 2 - fish cage B (3D)

The axial service tube ( 1 ) in fish cage A 1 is characterized by an axial, cylindrical pipe framework ( 01 ) in the fish cage B - 2 replaced. In the axial pipe framework ( 01 ) are stable and flexible ballast chambers ( 02 ) for air. Like the construction of the entire fish cage, the axial, cylindrical pipe framework ( 01 ) of about 1.5 m diameter also longitudinal struts ( 04 ), Round struts ( 05 ) and spokes ( 03 ), which are fixed together and have several sections depending on the length of the entire cage. The diameter of the central pipe framework ( 01 ), depends on the static calculations for the volume of the ballast chambers ( 02 ), based on the size and weight of the entire fish cage in its floating positions, depending on the weather and fish service in the fish cage, 4 , So there are two types of ballast chambers ( 02 ). Stable volume non-adjustable air ballast chambers made of stainless steel ( 02a ) or marine plastic pressure vessels with approx. 6 bar air pressure and flexible ballast chambers as cylindrical rubber tanks ( 02b ), which are folded flat and can be inflated. The ballast compensation takes place exclusively with air and the weight of the cage according to the Archimedean principle: "The buoyancy of a body in liquid is equal to the weight of the displaced liquid".

The volume of stable air ballast chambers ( 02a ) in the axial pipe frame is dimensioned so that the buoyancy force the entire cage about 7 meters below the deepest troughs, so swim in about 20 to 30 m depth. Because of the buoyancy (hydrostatic pressure), the cage can never sink lower and get lost.

The volume of flexible rubber containers ( 02b ) in the axial pipe frame is dimensioned so that the variable volume of air can raise and lower the fish cage in any desired position. The entire volume of air raises the cylindrical fish cage up to half of the water. The stable ballast chambers ( 02a ) and the flexible cylindrical rubber containers ( 02b ) in the axial pipe frame are distributed over the length of the cage so that the statics of the entire cage is balanced horizontally.

The flexible, cylindrical rubber tanks ( 02b ) are on a longitudinal strut ( 04 ) of the axial pipe framework ( 01 ) and folded flat without air. All rubber tanks ( 02b ) are connected to a compressed air hose ( 15 ) connected. The compressed air hose ( 15 ) leads over the buoy ( 9 ) 1 up to the compressed air tank and compressor on the service boat or trawler ( 14 ). Valves control the air supply and air discharge.

Fishing nets ( 8th ) with predetermined mesh sizes are around the entire, cylindrical fish cage and around the axial pipe framework ( 01 ) with the air tanks, as well as for the separation of the sections ( 07 ), curious; excited.

In strong storms, the fish cage is sunk below the deepest troughs, 4 B-3. This will be the buoys 9 and 13 disconnected at their quick-release couplings. The air of flexible rubber tanks ( 02b ) escapes. The fish cage sinks with its own weight to below the troughs. After the storm, the cage is moved over the navigation buoy ( 13 ) and both buoys are again verkuppelt together and at the fishing boat ( 14 ) 4 attached. The respective functions are reactivated.

Otherwise, the outer tube frame of fish cage B is similar to the outer tube frame of fish cage A. 1 with its longitudinal struts ( 4 ), its round struts ( 5 ), its spokes ( 3 ) and semicircular ends. All fish cages are placed over the air-filled ( 010a ) and evacuate ( 010b ) Fender, 2 turned and stabilized and with the safety airbags ( 16 ) secured. A controllable rudder ( 12 ) 1 At the end of the fish cage, let the cage swim diagonally to the current, so that oxygen-rich water flows laterally through the fish cage.

Variant 2 is Fig. 3 - fish cage C (3D)

The axial service tube ( 1 ) in the fish cage A 1 , is characterized by a three-limb construction ( 001 ) in fish cage C 3 replaced. It consists of three tubes ( 001a , b, c), which are three-legged welded with steel plates and so form an air space.

The leg width of (plus / minus) 1.5 m and the size of the three tubes ensures the axial stability for the entire fish cage.

The air volume of the three tubes and the three-legged air space, are so dimensioned that the entire fish cage with the axial construction ( 001 ) floats on the water.

The three pipes ( 001a , b, c) again have a volume that causes the fish cage to descend about 7 m below the deepest troughs when filled with water. This will control the fish cage in any desired depth position. As with the construction with the axial service tube ( 1 ) of fish cage A 1 , the ballast compensation takes place with water and air. Otherwise, the outer tube frame of fish cage C is similar to the tube frame of fish cage A and B with its air-filled ( 010a ) and evacuate ( 010b ) Fenders for turning and stabilizing the cage, as well as its safety airbags ( 16 ) 2 ,

Further innovations

1. Turning and Stabilizing the Fish Cage - Fig. 2

The device described in the patent ( 10 ) of the fish cage A 1 for turning and stabilizing the entire fish cage, is enhanced by the innovative air tank technology ( 010 - Fender) 2 replaced at fish cages A, B and C.

At the crossing points of the longitudinal struts ( 4 ) and the round struts ( 5 ) are in the inside or outside of the fish cage inflatable air tank rows ( 010 ) (Fender) as seen from the longitudinal direction of the cage, at the beginning, middle and end of the cage.

Three fenders each in a longitudinal direction are connected to a compressed air hose. With 6 fender rows, 6 compressed air hoses arrive at the axial cage start, where they are bundled via the navigation buoy ( 9 ) to the compressed air tank on the trawler. Each compressed air line is individually controlled on the cutter by means of a two-way valve.

To stabilize the fish cage, the two upper fender rows of three air tanks ( 010a ) in the longitudinal direction of the fish cage filled with air, the lower air tank ( 010b ) Not. So the fish cage is stabilized. To rotate the cage, the air from the three fenders of a longitudinal direction is let out and three empty fender rows next to it filled with air. This is how the fish cage rotates and stabilizes in every desired rotational position.

2. Safety Air Bag ( 16 ) Fig. 2

Three compressed air cylinders with compressed air and refillable air bags are located at the beginning, in the middle and at the end of the axial service tube ( 1 ) of fish cage A 1 , or at the axial pipe framework ( 01 ) of fish cage B 2 , or at the axial, three-limb construction ( 001 ) of fish cage C 3 attached. For some reason, the fish cage should be moved from its lowest float position 7 m below the deepest troughs can no longer be lifted via the compressed air system, the safety airbags are activated via the remote control and the compressed air fills the air bags and lifts the fish cage. The volume of the air bags is designed accordingly.

3. oxygenation

At a water flow of 0.6 m / sec, the water has sufficient oxygen for a stocking density of 25 kg fish / m ³ . Less flow and warm water do not meet these values and reduce the stocking density accordingly.

A diffuse air supply in the fish cage increases the oxygen content of the water. Porous tubing ( 17 ) 2 , suitable for underfloor irrigation, are on longitudinal struts ( 4 ) 2 the fish cages attached. They drove over compressed air hoses to the compressor and compressed air tank on the trawler. Ball valves are used to control the air in order to remove from the porous hoses ( 17 ) 2 on the outer longitudinal struts ( 4 ) of the fish cage, diffuse air escapes. The oxygen content in the water is optimized and ensures a stocking density of 25 kg / m ³ .

4. Fish feeding

The fish food is stored loose or in bellows on the trawler or skipper. A hose and pipe system from the trawler to the fish cage and in the fish cage is suitable for both compressed air or liquid feeding systems.

An innovative liquid feeding unit 5 , or a blower unit on the trawler feed the feed pellets into the sections of the fish cage. A flexible feeding tube leads from the fishing cutter over the buoy 9 to the axial feeding tube ( 19 ) in the fish cage B, 2 with its branches to the sections ( 7 ) of the fish cage. The branches to the individual sections are via pinch valves ( 19a ) controlled. From the pinch valve ( 19a ) leads a flexible hose ( 19b ) to a buoy ( 19c ) on the water surface, where the fish food is distributed umbrella-like by means of a self-rotating angular tube with bounce plate. The length of the flexible hose ( 19b ) allows half a turn of the fish cage. If a second fish cage is attached to the first fish cage, the feeding tube ( 19 ) to the second fish cage with the same feeding facilities as in the first fish cage.

This feeding pipe system is also installed in fish cage A and fish cage C.

5. Feed feeding device - Fig. 5

The feed feeding device for liquid feeding is based on the "Bunsen water jet pump". The Bimsen-Wasserstrahlpumpe generated because of the tube constriction at the intake, a hard water jet, which destroys the feed pellets. Furthermore falls after the aspirator an original water pressure of 3 bar to 0.8 bar back. The aim is to develop a feed feeder that protects the pellets and increases the lost water pressure again.

This is with the innovative feed feeder 5 succeeded. It consists of a seawater pump F1, a feeder F2, an innovative pellet feed F3 in a water pipe F4, and a by-pass pipe F5 with the initial pressure of the water pump F1 to increase the water pressure in the water pipe F4 after the pressure loss at the intake pipe.

The feed is thus not fed to a narrowed outer wall of the pipe as in the Bunsen water jet pump, but via an innovative suction device F3 as a suction pipe with the opening in the middle of the DN50 water pipe F4. A conical enlargement around the suction pipe opening F3 generates a larger water vortex in which the pellets are not destroyed and pass harmlessly into the water flow of the water pipe F4.

The lost by sucking water pressure is increased again via the by-pass tube F5 with the original water pressure of the seawater pump F1. The higher water pressure at the end of the water pipe F4 can pump the fish food into the fish cage.

However, when starting the pump F1 5 always an outlet valve ( 19c ) 2 be open in a cage section, otherwise there is a recoil of the increased water pressure through the suction pipe opening F3 5 , The pump delivers 4 m ³ / h (+/- 1 m ³ / h) and a water pressure of 3 bar.

6. Fish harvesting device Fig. 6

In a standard fish cage are up to 500 tons of fish, which must be harvested quickly and smoothly. By the given fact that the fish cage lifted up to half of the water 4 B-2 and can be rotated on its own axis, results in an innovative fishing crop device 6 in conjunction with a fish vacuum pump.

Description of the fishing harvesting device Fig. 6:

A PE pipe frame ( 1 ) 6 is fitted in the radius area of a section of the fish cage and at the central pipe framework ( 6 ) hinged.

In this tube frame ( 1 ) is a fish net ( 5 ), which forms on the side of the outer net of the fish cage a deepening depression towards a corner. The bowl depth of about 70 cm is through a PE pipe ( 2 ) and by two short struts ( 3 + 4 ) stabilized in the corner of the tubular frame. The suction pipe of the fish vacuum pump reaches into the bowl depth at the crossing point of the stabilizing tubes ( 2 . 3 and 4 ).

The fish vacuum pump works efficiently when the space for the fish is reduced. This is achieved by lifting the cage halfway out of the water 4 Position B-2 and turning the cage about its own axis when the fish harvesting device is attached to an external strut ( 8th ) 6 the fish cage and the spokes ( 7 ) 6 is attached.

In the outer net of the fish cage are along a round strut ( 5 ) 1 Each section has several closable openings for the suction pipe of the fish vacuum pump. Depending on the rotational position of the fish cage, the closest cage opening for the intake pipe of the vacuum pump is taken, so that the intake pipe always extends to the bowl depth of the fishing harvesting device. The fish vacuum pump with an hourly capacity of up to 15 tons, is installed next to other fishing harvesters and machines on a special fishing boat next to the cage.

In order to reduce the risk of algae being attached to the fishing nets during the long rearing season, the fishing nets will be transported by means of appropriate slide rails on the fishing nacelle frame in the direction of the axial pipe construction ( 6 ) 6 folded. Only for the harvest, the net is stretched again in the fishing frame.

7. Fish sorting

The technology and handling of the fishing crop device 6 , is also used for fish sorting. The fishing net is replaced by a net with appropriate selection meshes for sorting fish by size. As with the fish harvest, the frame is fixed in the section area, the cage half lifted out of the water via the axial, flexible air chambers and then the fish cage via the fenders ( 010 ) 2 turned. The smaller fish pass the mesh size and the larger fish are sucked by the vacuum pump as in the fishery harvest from the pit depth.

LIST OF REFERENCE NUMBERS

1

Servicerohr

2

Ballastkammern

3

Streben-Speichenräder

4

Längsstreben

6

Ankerpunkt

7

Sektionen

8

Fischnetze

9

Navigationsboje für Serviceleitungen

10

Vorrichtung für Käfig Drehen

11

Netzstreifen

12

Ruder

13

Zugseil mit Boje

1 Fischkäfig A – Querschnitt (3D)

1

Servicerohr

2

Ballastkammern

3

Streben-Speichenräder

4

Längsstreben

5

Rundstreben

8

Fischnetz

10

Drehvorrichtung

Fig. 2 Fischkäfig B (3D)

01

Axiale Rohrgerüst

02

Stabile und flexible Ballastkammern

03

Speichen im axialen Rohrgerüst

04

Längsstreben im axialen Rohrgerüst

05

Rundstreben im axialen Rohrgerüst

07

Mehrere Sektionen im Käfig

02a

Stabile Ballastkammern (Nirosta Stahlblech oder Kunststoffdruckbehälter)

02b

Flexible Ballastkammern als zylindrische Gummibehälter

15

Druckluftschlauch für flexible Ballastkammern

16

Sicherheit Air-Bag

17

Poröse Schläuche für Sauerstoffanreicherung

19

Fütterungsrohr für Flüssig- und Luftfütterung

19a

Quetschventil

19b

Flexibles Fütterungsrohr

19c

Boje mit rotierendem Winkelrohr und Prellplatte

3

Streben (Speichenräder) des Fischkäfigs

4

Längsstreben des Fischkäfigs

5

Rundstreben des Fischkäfigs

8

Fischnetz um den gesamten Käfig und zwischen den Sektionen

010

Fender zum Drehen und Stabilisieren des Käfigs

010a

Luftgefüllte Fender zum Stabilisieren des Käfigs

010b

Luftleere Fender

Fig. 3 Fischkäfig C

001

Dreischenkelige Konstruktion

001a

Rohr a der dreischenkeligen Konstruktion

001b

Rohr b der dreischenkeligen Konstruktion

001c

Rohr c der dreischenkeligen Konstruktion

010a

Luftgefüllte Behälter (Fender) zum Drehen und Stabilisieren des Käfigs

010b

Luftleere Behälter (Fender)

Fig. 4 Positionen der Fischkäfige und Fischkutter Bei unterschiedlichen Wetterbedingungen

6

Ankerpunkt, Zugpunkt

9

Navigationsboje für Serviceleitungen

13

Zugseil Boje

14

Fischkutter oder Schifffrachter

12

Ruder zum Schrägstellen des Käfigs zur Wasserströmung

B-1

Normaler Seegang-Käfig etwas aus dem Wasser

B-2

Ruhige See-Service im Käfig, Fischernte, Käfig halb aus dem Wasser

B-3

Sturm und hohe Wellen-Versenkter Fischkäfig bis unter Wellentäler

Fig. 5 Fütterung-Einspeisungsgerät

F1

Meerwasserpumpe

F2

Futter-Dosierer

F3

Futter-Einspeisung

F4

Wasserrohr

F5

By-Pass Rohr

Fig. 6 Fischernte-Vorrichtung

1

PE-Rohrrahmen

2

PE-Rohr zur Stabilisierung der Mulde im Fischnetz

3

PE-Strebe für Rohr 2

4

PE-Strebe für Rohr 2

5

Fischernte-Netz

6

Axiales Rohrgerüst des Fischkäfigs

7

Strebe der Speichenräder des Fischkäfigs

8

Äußere Längsstrebe des Fischkäfigs

Fig. 6 Zusammenfassung Fischkäfig

Versenkter Fischkäfig unter Wellentäler

Fig. 1 fish cage A - longitudinal section

1

service Pipeline

2

ballast chambers

3

Struts-spoke wheels

4

longitudinal struts

6

anchor point

7

sections

8th

fishing nets

9

Navigation buoy for service lines

10

Rotate device for cage

11

power strip

12

rudder

13

Pull rope with buoy

1 fish cage A - cross section (3D)

1

service Pipeline

2

ballast chambers

3

Struts-spoke wheels

4

longitudinal struts

5

around pursuit

8th

Fishnet

10

rotator

Fig. 2 fish cage B (3D)

01

Axial pipe scaffolding

02

Stable and flexible ballast chambers

03

Spokes in the axial pipe frame

04

Longitudinal struts in the axial pipe frame

05

Round struts in the axial pipe frame

07

Several sections in the cage

02a

Stable ballast chambers (stainless steel sheet or plastic pressure tank)

02b

Flexible ballast chambers as cylindrical rubber tanks

15

Compressed air hose for flexible ballast chambers

16

Safety Air Bag

17

Porous tubes for oxygenation

19

Feeding tube for liquid and air feeding

19a

pinch

19b

Flexible feeding tube

19c

Buoy with rotating angle tube and bounce plate

3

Struts (spoked wheels) of the fish cage

4

Longitudinal struts of the fish cage

5

Round struts of the fish cage

8th

Fishnet around the whole cage and between the sections

010

Fender for turning and stabilizing the cage

010a

Air-filled fenders to stabilize the cage

010b

Air empty Fender

Fig. 3 fish cage C

001

Three-limbed construction

001a

Tube a of the three-limb construction

001b

Tube b of the three-limb construction

001c

Tube c of the three-limb construction

010a

Air-filled containers (fenders) for rotating and stabilizing the cage

010b

Empty air tank (Fender)

Fig. 4 Positions of fish cages and trawlers In different weather conditions

6

Anchor point, tow point

9

Navigation buoy for service lines

13

Pull rope buoy

14

Trawler or ship freighter

12

Rudder for tilting the cage to the water flow

B-1

Normal swell cage something out of the water

B-2

Quiet lake service in the cage, fishery harvest, cage half out of the water

B-3

Storm and high waves-sunken fish cage up under troughs

Fig. 5 feeding-feeding device

F1

Sea water pump

F2

Feed Dispenser

F3

Feed feed

F4

water pipe

F5

By-pass tube

Fig. 6 fishing harvesting device

1

PE pipe frame

2

PE pipe to stabilize the trough in the fish net

3

PE strut for pipe 2

4

PE strut for pipe 2

5

Fish harvesting network

6

Axial pipe scaffold of the fish cage

7

Strut the spoked wheels of the fish cage

8th

Outer longitudinal strut of the fish cage

Fig. 6 Summary fish cage

Submerged fish cage under troughs

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102008057515 [0001, 0001]
• DE 102009048948 [0001]

Claims (9)

An axial, cylindrical pipe construction in the fish cage B, characterized in that in the axial, cylindrical section spaces, both stable and flexible ballast chambers control the entire cage only with appropriate volume of air at any desired depth. An axial three-legged tube construction in the fish cage C, characterized in that three tubes are welded to steel plates and form ballast chambers for water and air and thus control the cage at any desired depth. Fender on the longitudinal struts of fish cages A, B and C, characterized in that each Fenderreihe is connected to a compressed air hose to the compressed air tank on the trawler and the fish cage stabilized via valves and / or rotated. Pressure bottles with compressed air and flat folded rubber containers, characterized in that in emergency situations via a remote control, the rubber containers are filled with air from the pressure bottles and lift the fish cage. Porous air hoses fixed to the longitudinal struts of the fish cages, characterized in that air from compressors on the trawler evenly and diffusely distributed in the fish cage and increases the oxygen content of the water. A liquid and air feeding pipe system from the trawler to the individual sections in the cage, characterized in that each section is fed fully automatically with feed pellets via feeding units on the cutter or service boat. A feed feeding device for sucking feed pellets into a stream of water, characterized in that the suction pipe opens in the middle of the water flow, in the water vortex the pellets remain undamaged and the lost water pressure via a by-pass pipe from the water pump until after the feed supply increases again becomes. A fishing net, stretched in the radius surface of a section, characterized in that a prefabricated trough in the network, is used to collect the fish during cage rotation and to suck it from a deepening of the depression. A fish sorting with the fish harvesting device as dependent claim, characterized in that the fishing net is replaced with a network of predetermined mesh size, so that when turning the cage, the smaller fish sorted out and the larger fish are sucked with the vacuum pump.

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