CZ36303U1 - Equipment for dissolving oxygen in a water tank - Google Patents

Description

Equipment for dissolving oxygen in a water tank

Field of technology

The technical solution relates to the field of breeding fish and other aquatic organisms, specifically a device for improving the solubility of oxygen in water during its oxygenation.

Current state of the art

Oxygenation of the water is known to be essential for raising fish and other aquatic organisms in aquaculture. Sufficient oxygen dissolved in water is necessary both for the very survival of aquatic organisms and for ensuring their food metabolism and growth. As the number of fish in the tank increases, the need to oxygenate the water increases. With a lack of oxygen in the water, fish do not digest the food they receive, limit their intake, and in the worst cases, fish may die.

There are various devices that are designed to improve the solubility of oxygen in water. E.g. document CN 105994117 A describes a device for the diffusion of microbubbles of oxygen and medicine for a pond forming a fish farm. The device is placed in the pond using a support structure. It includes a connecting tube, a rotary head, and a bubble source connected to the connecting tube, which is connected to the oxygen supply reservoir and to the actuator. The drive is further connected to the rotary head. The bubble source is located at the bottom of the pond and can be used to mix the water so that the water flows up and down while being drawn into the tube from below. The disadvantage of this solution is the complex design - the need for an active drive, e.g. a motor, and the frequent breakdown of the device, so the device must be cleaned and checked at least once a day.

The invention application IT 201900001025 AI describes an assembly for mixing and diffusing gas in a stream of water. It consists of a tube line with an inlet part and an outlet part on the opposite side of the tube line. The inlet and outlet parts are equipped with curved blades that break up the flow of water entering the tube line. A turbulent flow is created in the tube line, which facilitates the mixing of water and oxygen. Consisting of a larger device that uses vacuum to let water into the pipe line. The disadvantage of this solution is that it is a large and expensive device that can only be used in large water reservoirs.

The task of the technical solution is to create a device for improving the solubility of oxygen in water, especially in smaller tanks with a volume of up to 20 m ³ , which would eliminate the above-mentioned shortcomings, i.e. which would effectively oxygenate the water in the entire height of the water column, would be simple to manufacture and operate, and whose operation would be reliable without the need for frequent checks and repairs.

The essence of the technical solution

This task is solved by creating a device for dissolving oxygen in a water tank for breeding fish and other aquatic organisms according to the presented technical solution. The device includes a vertically arranged hollow body that can be connected to an oxygen supply and provided with an inlet of flowing water. The essence of the technical solution is that the hollow body is formed by a cylindrical tube with an open upper and lower base, so that the cylindrical tube is constantly filled with a column of water. The inlet of the flowing water is located in the upper part of the cylindrical tube and is opened into its shell tangentially and at the same time obliquely from top to bottom towards the bottom of the tube. The water fed through the inlet to the cylindrical tube is spun into a swirling downward flow in which it descends to the lower base of the cylindrical tube. The cylindrical shape of the tube facilitates this spiral flow. The device further includes a diffuser arranged in a horizontal plane perpendicular to the vertical axis of the cylindrical tube at a distance h > 5 cm below the lower base of the cylindrical tube, and an oxygen supply connected to the diffuser. Oxygen in the form of fine

- 1 CZ 36303 UI bubbles are released by the diffuser and rise to the water surface. Its rise to the surface is slowed by a stream of water that spirals down. The oxygen bubble thus rises more slowly and along a longer spiral path. This achieves a thorough and more efficient saturation of the water with oxygen compared to the simple rise of the bubbles through the water column.

The inlet of the flowing water is opened into the shell of the cylindrical tube at an angle and lying in the range of 5 to 90° relative to the tangential plane of the cylindrical tube at the point of opening and at an angle β lying in the range of 5 to 85° relative to the axis of the cylindrical tube. A very sharp angle of water entry causes a rapid flow of water inside the cylindrical tube, on the contrary, an obtuse angle of the mouth of the water entry slows down its flow inside the cylindrical tube. The decelerated spiral flow of water causes the water to become more saturated with oxygen bubbles that flow from the diffuser in the opposite direction. Adjusting the angle at which water flows into the cylindrical tube, as well as its amount, serves to optimally set the hydrodynamic conditions inside the device. Part of the inflow water is fed into the cylindrical tube into the tank with a small elevation. The flowing water spins inside the cylindrical tube and descends to the bottom in a spiral flow.

It is also advantageous that the device further includes a removable cap for hermetically closing the upper base of the cylindrical tube. The removable cap helps capture oxygen that may not have dissolved in the water. The oxygen then remains under the removable cap in contact with the water level inside the cylindrical tube, so that the upper layer of the water column is still oxygenated.

In an advantageous embodiment, the device further includes a bed with a bottom. The bed is connected to the lower part of the cylindrical tube. The cylindrical tube is connected to the bed using handles, so that a gap of min. 5 cm, where the oxygenated water flows out of the device.

It is also advantageous that the diffuser is arranged at the bottom of the bed, as it is part of the device thanks to this arrangement. In the design of the device, where the cylindrical tube is provided with handles for hanging from the upper edge of the water tank, so that the bottom of the bed is located 2 to 5 cm above the bottom of the tank, the diffuser is raised with the whole device.

Finally, it is advantageous that a wedge-shaped base adjoins the bottom of the bed from the outside, which forms an angle γ between 50 and 85° with the vertical axis of the cylindrical tube. The wedge-shaped base evens out the unevenness of the bottom so that the cylindrical tube is always positioned in the direction of its vertical axis in the tank. This is important both from the point of view of the stability of the entire device and from the point of view of its functioning.

The device for dissolving oxygen in the water tank is very simple to assemble, thanks to this it has a long life, it is very low failure and low maintenance, it is energetically passive and very cheap to manufacture.

Clarification of drawings

The technical solution will be explained in more detail with the help of the attached drawings, which show:

Fig. 1 is a longitudinal section of a device located in a water tank;

Fig. 2 longitudinal section of the device in a water tank with a removable cover;

Fig. 3 is a side view of the location of the inlet of the flowing water into the tube;

Fig. 4 top view of the location of the inlet of the flowing water into the tube; and Fig. 5 is a longitudinal section of a device with a wedge-shaped base.

-2CZ 36303 UI

Examples of implementing a technical solution

The device 1 for dissolving oxygen in the water tank consists of a hollow cylindrical tube 2 with an open upper and lower base. The cylindrical tube 2 is placed in the water tank vertically and essentially perpendicular to the bottom of the tank. The height of the cylindrical tube 2 depends on the depth of the tank, because the cylindrical tube 2 is arranged vertically in the tank, its lower part is located in the bed 5 min. 5 cm above the bottom. The upper part of the cylindrical tube 2 slightly extends above the level 10 of the water tank, the height of the overlap is 2 cm to 10 cm. The minimum diameter of the cylindrical tube 2 is 10 cm. But it can be larger depending on the size of the tank and the intensity of fish farming. The maximum feasible diameter of the cylindrical tube 2 is 100 cm. Cylindrical tube 2 is made of inert, food-safe and non-corrosive solid material, e.g. laminate, stainless steel sheet. Most often made of plastic, the cylindrical tube 2 can also be made of solid translucent plastic, which allows the upward movement of the oxygen bubbles to be controlled.

Device 1 is mainly used in tanks for intensive breeding of fish and other aquatic organisms with a volume from 3 m ³ to 20 m ³ . In this case, the height of the cylindrical tube is 2100 cm and its diameter is 20 to 30 cm.

The lower base of the cylindrical tube 2 is connected by means of handles 11 to the bed 5, which in the embodiment shown in Fig. 1 and 2 is placed on the bottom of the tank. In the case of a conical tank bottom, which is common for better drainage of waste water with food and faeces residues, the bed 5 is provided with a wedge-shaped base 9, which ensures that the cylindrical tube 2 is placed in the tank in the direction of its vertical axis p. The wedge-shaped base 9 clamps with the vertical axis of the cylindrical tube 2 angle γ of 80 to 88°. An oxygen diffuser 6 is placed in the bed 5. Figures 1, 2 and 5 show a ceramic pressure diffuser 6 in a shape smaller than the diameter of the cylindrical tube 2. Oxygen is supplied to the diffuser 6 through an oxygen inlet 3 formed by a flexible hose line from the central distribution.

Between the diffuser 6 lying on the bottom of the bed 5 and the lower base of the cylindrical tube 2, there is a gap with a height of min. 5 cm so that the oxygenated water can flow freely from device 1. The bed 5 is connected to the cylindrical tube 2 by means of handles 11.

In the upper part of the cylindrical tube 2, as shown in Fig. 3 and 4, the inlet 4 of flowing water is connected in the vertical plane at an angle β = 45° and in the horizontal plane at an angle a = 90°, which brings a smaller part of the water from the inflow pipe into the tank. In another example of the implementation of the technical solution, part of the inflow water is fed into the inlet 4 into the water tank. It is also possible to pump water with a small pump from its own tank and let it into the cylindrical tube 2. Due to the connection of the inlet 4 of the flowing water to the cylindrical tube 2 at an angle, the water inside the cylindrical tube 2 spins and descends to the bottom by spiraling through the inner shell of the cylindrical tube 2. Size angle β and a set the hydrodynamic conditions inside the tube. In the embodiment example, where the angle β is sharp, namely 5°, the water practically jets into the cylindrical tube 2 and the spiral flow inside the cylindrical tube 2 is very fast and violent. On the contrary, in the embodiment where the inlet 4 is mouthed into the shell of the cylindrical tube 2 at a large angle of 85°, the spiral flow of water inside the cylindrical tube is very slow. The optimal implementation is where the angle β is 70 to 80°, which creates an optimal speed of spiral flow inside the tube.

The angle a affects the speed of the water stream, and the angle β, in particular, the angle at which the water sinks to the bottom, here the largest possible angle is preferable, so that the path of the water stream is as slow and long as possible. The optimal setting of the water inlet 4 is when the water inlet 4 makes an angle a of 20 to 30° with the tangential plane t and an angle β of 70 to 80° with the vertical axis of the cylindrical tube 2.

On the other hand, the oxygen bubbles released from the diffuser 6 rise up to the level 10. The spiral flow of water slows down their progress and at the same time lengthens the path of their movement, which causes a better dissolution of oxygen in the water. Thus, very little, if any, oxygen reaches level 10.

CZ 36303 UI

Homi base of the cylindrical tube 2 exceeds the water level 10 by 5 cm, in a tank with larger fish an overlap of even 10 cm is suitable. The water inlet 4 is opened into the casing of the cylindrical tube 2 at the level of the water level 10, or 1 cm below it.

In an example of implementation, which is not shown in the figures, the cylindrical tube 2 is provided in the upper part with one or two handles for hanging by the upper edge of the water tank. In that case, the bottom 8 of the bed 5 does not touch the bottom of the tank and there is no need to put a wedge base 9 under it.

Fig. 2 shows a device 1 for dissolving oxygen in a water tank, where the cylindrical tube 2 is equipped with a removable cover 7. This is used to collect undissolved oxygen, which remains under the cover 7 and gradually dissolves into the water surface 10.

The equipment described above can be used for intensive breeding of fish, as well as crustaceans, or it would be possible to use it for CO2 application in algae cultivation.

Industrial applicability

The device for dissolving oxygen in a water reservoir according to the technical solution can be used for oxygenating water for breeding fish and other aquatic organisms and generally for improving the quality of water in artificial water reservoirs.

Claims (7)

1. Device (1) for dissolving oxygen in a water tank for breeding fish and other aquatic organisms, comprising a vertically arranged hollow body connected to an oxygen supply (3) and provided with an inlet (4) of flowing water, characterized in that the hollow body is formed cylindrical tube (2), the inlet (4) of the flowing water is located in the upper part of the cylindrical tube (2) and is opened into the casing of the cylindrical tube (2) tangentially and at the same time obliquely from top to bottom towards the lower part of the cylindrical tube (2), while the device further includes a diffuser (6) arranged in a horizontal plane perpendicular to the vertical axis (o) of the cylindrical tube (2) at a distance h > 5 cm below the lower base of the cylindrical tube (2), with the oxygen supply (3) being connected to the diffuser ( 6). 2. Device according to claim 1, characterized in that the inlet (4) of the flowing water is mouthed into the shell of the cylindrical tube (2) at an angle lying in the range of 5 to 90°, relative to the tangential plane of the cylindrical tube (2), and below by an angle β lying in the range of 5 to 85°, relative to the vertical axis (o) of the cylindrical tube (2) at the mouth. 3. Device according to claim 1 or 2, characterized in that it further includes a removable cap (7) for hermetically closing the upper base of the cylindrical tube (2). 4. The device according to one of claims 1 to 3, characterized in that it further includes a bed (5) with a bottom (8) in which the lower part of the cylindrical tube (2) with an open lower base is placed. 5. Device according to claim 4, characterized in that the diffuser (6) is arranged in the bed (5). 6. Device according to one of claims 1 to 5, characterized in that the cylindrical tube (2) is provided with at least one handle for hanging the device (1). 7. Device according to claim 4 or 5, characterized in that a wedge-shaped base (9) adjoins the bottom (8) of the bed (5) from the outside, the bottom of which forms an angle γ with the vertical axis (o) of the cylindrical tube (2) ranging from 50 to 85°.