RU48250U1 - DEVICE FOR CONTAINING HYDROBIONTS - Google Patents

Abstract

The utility model relates to aquaculture, namely, devices for the maintenance and cultivation of aquatic organisms in open areas of the seas and oceans. The technical task of the claimed utility model is to create a device with increased operational reliability, with improved conditions for storing feed and preventing loss of feed, regulating the time of immersion and ascent. The problem is solved in a device for the maintenance of hydrobionts, including a lower horizontal frame, an upper frame with elements forming a cone-shaped frame, a feed hopper mounted in the upper part of the frame, a feed distributor and a caisson chamber, a mesh camera fixed to the frames and elements of the control system; equipped with an n-number of cylinders for high pressure air and a cylindrical body mounted on a caisson chamber, while the body has hatches located on the bases and on The touch surface in the housing coaxially mounted a hopper for fodder and feeding device, control elements and a part of cylinders for high-pressure air fastened to the inner surface of the housing at the side surface of the hatch, and the other part of cylinders - on the upper frame.

Description

The utility model relates to aquaculture, namely, devices for the maintenance and cultivation of aquatic organisms in open areas of the seas and oceans.

It is known that a device for growing fish or shellfish in the open sea (accepted application, Japan 100338-72, A 01 K 64/00), which has a housing equipped with a constant buoyancy chamber and a net cage with flexible ties supported by cables wound on hoisting winches . This device does not have a feeder, elements of control systems, and requires large labor costs for operations on winding cables with winches during its operation.

The fittings of the fish tank (French application laid out 2339338 1976 A 01 K 63/00, 61/00) has two hoops with different ballasting. The hoops are interconnected by several vertical and inclined ropes. On the outside of the hoops is fixed a network forming a chamber for fish. The cage remains open due to varying degrees of buoyancy. This device also does not have a feeder, does not have elements of a control system, and the inclined ropes connecting the hoops are placed inside the volume of the net chamber, which can impede the movement of fish inside it.

A device for growing fish (USSR author's certificate 1219028 1984 A 0 K 61/00) contains a floating pontoon, actually a cage, consisting of a frame and a net chamber, and a feeder. This device is difficult to operate, has a rigid frame, inside of which a network camera is fastened, which transfers a greater load from the excitement to the frame than in

constructions without rigid vertical frame elements. The device does not have an alarm in case of failure of the feeder.

A device for growing fish (USSR author's certificate 1760965 1990 A 01 K 61/00) contains a central pontoon and cages fixed around it. Complex control systems and an air storage are located on the central pontoon, feeders with caisson chambers are installed on cages. The device is also difficult to operate, and the presence of vertical frame elements also leads to an increase in loads on cage frames; control systems are located outside the cages, which leads to an increase in the length of communication links. The device has good stability underwater.

Submersible device for the maintenance of aquatic organisms, mainly for growing fish (USSR author's certificate 1489673 1986 A 01 K 61/00), which has a net cage, a lower horizontal frame with variable buoyancy pontoons and a guide, an upper frame with elements forming a cone-shaped frame connected with bottom vertical rigid elements. A fixed buoyant pontoon with a feeder with a caisson chamber mounted in it is rigidly attached to the upper part of the frame. In addition, the device has a platform, unfastened at anchors and made sharing with the cage. The device is difficult to operate, requires lifting means, has vertical rigid elements of the cage frame, and it does not have an alarm if the feeding of fish systems fails.

Closest to the claimed technical essence is a device for containing hydrobionts (RF patent 2054250 1993 A 01 K 61/00) having a lower horizontal frame with pontoons of constant buoyancy and a guide, an upper frame with elements forming a cone-shaped frame; feed hopper with feed distribution mechanism, elements of the device operation control system and a network camera fixed to the frames, the upper frame is formed by interconnected pontoons

constant buoyancy, and to make fuller use of the length of the generatrix of the upper frame when suspending the mesh camera, ballast tanks are eccentrically attached to the bottom of the nodes of the connection of the pontoon pontoons.

Sufficient stability of the device during immersion or ascent is achieved by installing containers at the top of the mentioned nodes that serve as constant buoyancy or additional ballast tanks, the diameter and height of which provides the necessary waterline for a given roll angle of the device.

Ballast tanks and additional tanks being an integral part of the device are removable. They can have several sizes, which allows, without changing the design of the upper frame, to change the buoyancy of the device, as well as carry out routine maintenance (cleaning, painting).

The vertical elements of the frame of the network camera, used to connect the lower frame to the upper, are made in the form of vertical and inclined lines. When the device is tilted under the influence of waves, so that the guide does not increase the roll and stability does not deteriorate, the pairwise inclined slings are fastened together at the intersection point.

Control system elements, a feeding mechanism with a drive, pneumatic system elements, ballast tank ventilation valves are mounted in a caisson chamber, at the top there is a quick-detachable part of the caisson chamber made of soft airtight material and fixed to the caisson chamber through a sealed connector. In the absence of air supply to the caisson chamber at the time of immersion, water may rise and feed leakage in the feed distributor, its sticking together and the possibility of further functioning.

Each ballast tank has an air duct with a ventilation valve located in the caisson chamber. Due to the geometry of the device, when

possible small inclinations, the air stops coming out of the BC, which increases the initial roll of the device and can lead to loss of stability. The device is equipped with an emergency buoy and means for its return when the feed is cut off or the feeding mechanism is working. The buoy may be poorly visible in bad weather or because of the greater distance to the coastal base.

The technical task of the claimed utility model is to create a device with increased operational reliability, with improved conditions for storing feed and preventing loss of feed, regulating the time of immersion and ascent.

The problem is solved in a device for the maintenance of hydrobionts, including a lower horizontal frame, an upper frame with elements forming a cone-shaped frame, a feed hopper mounted in the upper part of the frame, a feed distributor and a caisson chamber, a mesh camera and control system elements fixed to the frames, while it is additionally equipped with an n-number of cylinders for high pressure air and a cylindrical body mounted on a caisson chamber, while the body has hatches located on the bases and and on the side surface, in the housing, a feed hopper and a feed distributor, control system elements and part of the high-pressure air cylinders mounted on the inner surface of the body at the level of the side surface hatch, and the other part of the cylinders on the upper frame are coaxially installed.

In addition, the lower base hatch connects the cylindrical body to the caisson chamber.

The device shown in figure 1 is a General view, figure 2 is a cylindrical body in section.

A device for containing hydrobionts includes a lower horizontal frame 1, an upper frame 2 with elements 3 forming a cone-shaped frame, a mesh chamber 4 mounted on the frames, n-number of cylinders 5 for high-pressure air and a cylindrical body 6

mounted on the caisson chamber 7 (figure 2). The cylindrical body 6 has hatches located on the upper 8 and lower 9 bases and a hatch 10 on the side surface. A feed hopper 11 and a feed distributor 12 are coaxially installed in the housing. Control elements 13 and a part of the high pressure air cylinders 5 are fixed on the inner surface of the housing 6 at the level of the hatch 10 of the side surface, and the other part of the cylinders 5 is on the upper frame 2.

In addition, the hatch 9 of the lower base connects the cylindrical body 6 with the caisson chamber 7.

At the same time, for stability of the device during immersion or ascent, it is equipped on the upper frame 2 with constant buoyancy pontoons 14 interconnected, and for a fuller use of the length of the generatrix of the upper frame 2 when the mesh camera 4 is suspended in the lower part of the nodes of the constant buoyancy pontoons 14 ballast tanks 15 are attached, the diameter and height of which provides the necessary waterline for a given roll angle of the device.

Ballast tanks 15 are removable. They can have several sizes, which allows, without changing the design of the upper frame 2, to change the buoyancy of the device, as well as carry out routine maintenance (cleaning, painting).

The vertical frame elements of the network camera 4, used to connect the lower frame to the upper one, are made in the form of vertical and inclined slings 16. When the device is tilted under the influence of waves, so that the guide does not increase roll and stability does not deteriorate, the pair of inclined slings 16 are fastened together intersection point.

The cylindrical housing 6 for saturation with equipment is divided into two structural parts connected through a flange connector. The feed hopper 11, made of various materials, with the feeder 12 attached at the bottom, is fixed inside so that between the inside

The wall of the cylindrical body 6 and the hopper 11 contained an optimally defined air gap 17, which allows water to flow out by condensation of moisture on the inner wall of the body when the device emerges from colder waters and the body exits to the surface. For the functioning of the hull there are three hatches: on the upper base 8 for loading feed, on the side surface 10 for access to the elements of the control system 13, on the lower base 9 for unloading feed.

The space under the cone of the hopper 11 is saturated with elements of the control system 13, cylinders 5 with high pressure air for the functioning of the control systems of the device and feed. The lower hatch 9 is opened by the command of the feed control controller before starting the feed discharge, provided that there is air in the caisson chamber 7. After passing the feeding procedure, the hatch 9 closes, thereby cutting off the internal volume of the housing 6 from the water mirror, preventing an increase in humidity inside the feed hopper 11. Substitution of feed occurs as it is sprinkled with dried air from cylinders 5 with high pressure air.

Immersion and ascent is carried out by portioned ventilation and purging of ballast tanks 15 and this achieves a smooth change in depth by the device.

When the device emerges, excess air from the housing 6 is vented through the lower hatch 9, opening it with an overpressure exceeding the force from the specially selected overpressure in the pneumatic cylinders holding the hatch 9 closed, so there is no need for an etching overpressure valve with a large flow rate.

The device operates as follows.

The device mounted on anchor braces can have its own air storage and an electrical power unit or

connected via hoses and electric cables to external energy sources.

In the net chamber 4 are placed hydrobionts, such as juvenile fish. The hopper 11 is filled with feed, the elements of the control system 13 provide energy, then a command is made to immerse the device, then the valves (in FIG. Not shown) for ventilation of the ballast tanks 15 are opened, and air from them is vented through the volume of the caisson chamber 7, with containers 14 located at the top of the nodes of the upper frame 2, provide a constant area of the waterline until the water surface touches the caisson chamber 7, the immersion process continues and the device is installed at a given depth.

After the supply of feed has been developed, an ascent command is issued through the elements of the control systems 13, air begins to flow into the ballast tanks 15. The area of the waterline of the device when passing through the water surface is formed sequentially by the caisson chamber 7 and ballast tanks 15. After the caisson chamber 7 leaves the water, the ballast tanks 15 and additional tanks 14 provide a moment of inertia of the waterline area sufficient for a given level of stability.

When carrying out any work on the device, especially with the opening of the upper part of the net chamber 4 in order to exclude the spontaneous opening of the ventilation valves of the ballast tanks 14, each valve is manually closed by a mechanism (not shown in FIG.). Access to the caisson chamber 7 is easily carried out by opening its upper part made of an airtight material.

In case of a possible refusal of the feeding mechanism or not sprinkling the feed, if the device is in a submerged position, the emergency buoy release mechanism is activated. The appearance of a buoy on the surface of the water means a malfunction of any element of the control system.

In any position of the device (underwater, surface) when the roll of the upper frame, the guide creates an additional heeling moment. To reduce it, the inclined slings of each side forming the upper and lower frames are fastened at the intersection point.

The removal of aquatic organisms from the network camera is one of the known methods.

The proposed device in comparison with the described analogues has great ease of use and increased stability in operation, especially during immersion and ascent.

A study of the above analogues shows that this utility model is new, does not follow with obviousness from the prior art. The device is industrially applicable, because it can solve the problem of growing and keeping aquatic organisms, in particular closed-bubble fish, convenient for assembly, transportation and installation in the sea, has increased operational reliability, keeps food from getting wet and high humidity during prolonged exposure of the device under water, the selected algorithm for controlling ventilation and blowing ballast tanks eliminates fish stress with a smooth change in the depth of the device.

Claims (2)

1. A device for containing hydrobionts, including a lower horizontal frame, an upper frame with elements forming a cone-shaped frame, a feed hopper mounted in the upper part of the frame, a feed distributor and a caisson chamber, a mesh camera and control system elements fixed to the frames, characterized in that it is additionally equipped with an n-number of cylinders for high pressure air and a cylindrical body mounted on a caisson chamber, while the body has hatches located on the bases and on the side spine, in a housing coaxially mounted a hopper for fodder and feeding device, control elements and a part of cylinders for high-pressure air fastened to the inner surface of the housing at the side surface of the hatch, and the other part of cylinders - on the upper frame. 2. The device according to claim 1, characterized in that the lower base hatch connects the cylindrical body to the caisson chamber.