IT202000006451A1 - Immersion device for dissolving oxygen in a liquid - Google Patents

Description

? Immersion device for dissolving oxygen in a liquid?

DESCRIPTION

Technical Field

The present invention? relating to a device for oxygenating a liquid. In detail, such a device? of the immersion type and is typically used for the oxygenation of water. The device according to the present invention can be used in various sectors such as waste water treatment or fish farming.

State of the art

Biological activated sludge plants for waste water treatment have been known for some time.

In such plants, the waste water is accumulated in large tanks in which there? a suspension of active biomass (saprophytic bacteria, protozoa, amoebae and other types of microorganisms), usually in the form of flakes. The biomass decomposes the biodegradable organic substances present in the wastewater into simple and less harmful compounds used by the microorganisms themselves for their own nourishment and reproduction.

The efficiency of the transformation of biodegradable organic substances into simple substances (CO2, H2O)? directly proportional to the quantity? of oxygen dissolved in the water. Precisely for this reason, the tanks of biological activated sludge plants for the treatment of waste water require constant oxygenation.

In the state of the art there are also known devices for oxygenating liquids comprising a typically disc or tubular diffuser. These oxygenation devices are uniformly installed on the bottom of the tanks containing the liquid to be oxygenated, and are connected to a pipeline for the supply of oxygen or a gas containing oxygen. Oxygen? released in the tank in the form of microbubbles which spontaneously will tend to rise towards the surface. In their upward motion, the micro bubbles diffuse oxygen into the liquid.

Problem of the known technique

Disadvantageously, to ensure homogeneous oxygenation of the tank, the diffusers described above should completely cover its bottom.

Also, disadvantageously the oxygenation efficiency? directly proportional to the liquid head. In other words, major? the liquid head, the greater it will be? the distance traveled by the micro bubbles in the liquid and therefore also the diffusion of oxygen in the liquid.

Purpose of the invention

In this context, the task of the technician behind the present invention? to propose a device for the oxygenation of liquids which overcomes the drawbacks of the known art mentioned above.

In particular, ? object of the present invention to provide a device for oxygenating liquids which maximizes the oxygenation efficiency and at the same time guarantees a homogeneous distribution of oxygen in the liquid.

SUMMARY OF THE INVENTION

The specified technical task and the specified purposes are substantially achieved by a device for oxygenating liquids according to the present invention.

Such a device comprises a conduit having an internal surface extending from an inlet opening to an outlet opening. In particular, the duct has an exchange zone arranged to receive a turbulent flow of a liquid. The device further comprises thrust means associated with the conduit and configured to urge liquid from the inlet opening to the outlet opening. In detail, the thrust means are configured to generate a turbulent flow at the exchange zone. The device further comprises a first diffuser arranged on the internal surface of the duct in correspondence with the exchange zone, to generate micro bubbles containing oxygen.

The gas micro-bubbles emitted by the diffusers are captured by the liquid in turbulent motion creating a liquid-gas mixing effect, which will go? to increase the residence time of the gas in the liquid. In this way, the present invention? able to maximize the oxygenation efficiency and at the same time guarantee a homogeneous distribution of oxygen in the liquid.

Advantageously, by capturing the gas microbubbles in turbulent motion, yes? able to prevent the immediate tendency to rise upwards, thus releasing? the oxygenation efficiency from the liquid head.

LIST OF FIGURES

Further characteristics and advantages of the present invention will become clearer from the indicative, and therefore non-limiting, description of a preferred but not exclusive embodiment of an immersion device for oxygenating liquids, as illustrated in the accompanying drawings in which:

Figure 1 shows a partially sectional perspective view of the device according to the present invention;

Figure 2 shows a top view of the device of Figure 1;

Figure 3 shows a partially sectioned side view of the device of Figures 1 and 2; And

Figure 4 shows a front view of the device of Figures 1 and 2.

Figure 5 shows a schematic top view of the device of Figures 1 and 2.

DETAILED DESCRIPTION

Even if not explicitly highlighted, the individual characteristics described with reference to the specific embodiments must be understood as accessory and / or interchangeable with other characteristics, described with reference to other embodiments.

With reference to the attached figures, the present invention relates to a device 1 for oxygenating a liquid, in particular water.

Such a device 1? in particular of the immersion type,? therefore configured to remain in the liquid for prolonged periods. Typically, but not exclusively, the device? deposited on a bottom of a tank (not shown), for example intended for waste water treatment.

The device 1 comprises a conduit 2 which extends between an inlet opening 3a to an outlet opening 3b. The duct 2 has a longitudinal development axis X-X. With particular reference to Figure 1, the duct 2 preferably has a substantially cylindrical shape. The duct 2 has an internal surface 2a, which extends at least in part along the longitudinal axis of development X-X, in particular between the inlet opening 3a and the outlet opening 3b. It should be noted that the duct 2 has an exchange zone 4 arranged to receive a turbulent flow of liquid.

In greater detail, the duct 2 comprises a converging portion 2b which extends from the inlet opening 3a to the exchange zone 4, in particular along the longitudinal extension axis X-X. This duct 2 has the function of conveying the fluid from the inlet opening 3a towards the exchange zone 4.

The device 1 also comprises thrust means 5 associated with the duct 2. These thrust means 5 have the function of pushing the liquid from the inlet opening 3a to the outlet opening 3b. The thrust means 5 are also configured to generate the turbulent flow of the liquid in correspondence with the exchange zone 4. It should be noted that the turbulent flow generated by the thrust means 5 is conveyed into the exchange zone 4 by the aforementioned converging section 2b.

In greater detail, the thrust means 5 comprise an immersion mixer 10. In particular, this mixer 10 comprises a propeller 10a associated with the inlet opening 3a, and configured to rotate around an axis of rotation which, as shown in Figures 1 and 2, preferably coincides with the longitudinal axis of development X-X of the duct 2. The propeller 10a, by rotating around its own axis of rotation, pushes the liquid from the inlet opening 2a to the outlet opening 2b, generating the turbulent flow in correspondence with the exchange zone 4.

Preferably, as shown in Figures 1 and 3, the propeller 10a of the mixer 10? placed inside the convergent section 2b, and in particular? overlooking the exchange area 4.

The device 1 also comprises oxygenation means 6. These oxygenation means 6 comprise at least one diffuser 7, arranged on the internal surface 2a of the duct 2 in correspondence with the exchange zone 4. Preferably, the diffuser 7 extends mainly along the axis of longitudinal development X-X. In detail, the speaker 7? configured to generate micro bubbles containing oxygen within the exchange zone 4. Even more? in detail the speaker 7? a microporous ceramic diffuser capable of creating micro bubbles of the order of magnitude of 100-500?. In other words, the speaker 7? preferably an oxygen bubble micronization device.

Preferably, the diffuser 7 develops mainly on a plane arranged transversely to a vertical direction Y-Y. In detail, as shown in figure 4, the diffuser 7? placed perpendicular to the vertical Y-Y direction.

In greater detail, the oxygenation means 6 comprise two further diffusers 8, which are arranged on the internal surface 2a of the duct 2, also in correspondence with the exchange zone 4. These further diffusers 8 are arranged on opposite sides of the duct 2. In other words, the further diffusers face opposite sides of the diffuser 7 described above. Preferably, the further diffusers 8 are facing each other and arranged parallel to the vertical direction Y-Y, as shown for example in figure 4. In the preferred embodiment, the further diffusers 8 are structurally similar to the diffuser 7

Preferably, as shown in Figures 1 and 4, the diffuser 7? connected in series to the further diffusers 8, in particular by means of a plurality of of tubes 9. In detail, the tubes 9 have the function of transporting oxygen or a gas containing oxygen, from a further diffuser 8 to the diffuser 7 and to the other further diffuser 8. In alternative embodiments, not shown, the diffuser 7 and the further diffusers 8 can be connected differently, for example in parallel, or they can be powered individually.

The device 1 further comprises a connecting element 11. In detail, the connecting element 11? integral with the duct 2 and the mixer 10 to fix the position of the duct 2, in particular of the converging portion 2b, with respect to the helix 10a. In other words, the connecting element 11 fixes the relative position between the helix 10a and the converging portion 2b, preferably aligning the axis of rotation of the helix with the longitudinal axis X-X along which the portion extends convergent 2b.

Furthermore, preferably the connecting element 11 has a base surface 11a configured to rest on the bottom of the tank to be oxygenated.

Preferably, the mixer 10 comprises a slider 12a configured to slide in a guide 12b not part of the device 1, in particular during an installation phase of the device 1 in the tank, in such a way as to fix the position of the device 1 with respect to the surrounding environment , in particular with respect to the tank to be oxygenated.

In a preferred embodiment, the device 1 comprises at least a first and a second ring 14a, 14b. In particular, the first and second rings 14a, 14b are configured to be secured to ropes (not shown in the drawings) to allow the introduction and extraction operations of the device 1 from the tank.

In a preferred form, the first ring 14a? fixed integrally to the duct 2, in particular in correspondence with the outlet opening 2b. Furthermore, preferably, the second ring 14b? fixed to the mixer as shown in the attached figures.

? also part of the present invention is an assembly 13 comprising the aforementioned guide 12b and the device 1.

In particular, guide 12b? arranged vertically to allow the introduction and extraction of the device 1 along the vertical Y-Y direction. In detail, as shown in Figure 5, the cursor 12a of the device 1? configured to slide in the guide 12b along the vertical Y-Y direction to allow the introduction and extraction of the device 1 from the guide 12b. Advantageously, the insertion of the device 1 along the vertical direction Y-Y facilitates the installation operation of the device 1 with the tank full.

In use, the device 1 operates as follows. Once activated, the mixer 10 pushes the liquid through the duct 2. In detail, the propeller 10a, rotating around its own axis of rotation, pushes the liquid from the inlet opening 2a to the outlet opening 2b of the internal surface 2a, generating the turbulent flow at the exchange zone 4.

The diffuser 7 and the further diffusers 8, arranged on the internal surface 2a of the duct 2 in correspondence with the exchange zone 4, introduce micro-bubbles containing oxygen into the turbulent flow of liquid.

The micro bubbles are then captured by the liquid in turbulent motion creating a liquid-gas mixing effect, which will go? to increase the residence time of the gas in the liquid. In this way, the present invention? able to maximize the oxygenation efficiency and at the same time guarantee a homogeneous distribution of oxygen in the liquid.

Claims (10)

CLAIMS 1. Immersion device (1) for oxygenating liquids comprising: - a duct (2) having an internal surface (2a) extending between an inlet opening (3a) and an outlet opening (3b), said duct (2) having an exchange zone (4) arranged for receiving a turbulent flow of a liquid; - thrust means (5) associated with the duct (2) and configured to push the liquid from the inlet opening (3a) to the outlet opening (3b) generating the turbulent flow in correspondence with said exchange zone (4 ); - oxygenation means (6) comprising at least one diffuser (7) arranged on the inner surface (2a) of said duct (2) in correspondence with the exchange zone (4) and configured to generate micro bubbles containing oxygen. Device (1) according to claim 1, wherein the diffuser (7)? arranged transversely and in particular perpendicular to a vertical direction (Y-Y). Device (1) according to claim 1 or 2, wherein the oxygenation means (6) comprise two further diffusers (8) arranged on the internal surface (2a) of the duct (2) in correspondence with the exchange zone (4) , the further diffusers (8) being arranged on opposite sides of the diffuser (7). Device (1) according to claim 3, wherein the diffuser (7) and the further diffusers (8) are connected in series by means of a plurality of of pipes (9). Device (1) according to any one of the preceding claims, wherein the duct (2) comprises a converging portion (2b) extending from the inlet opening (3a) to the exchange area (4), the converging portion (2b ) being configured to convey the turbulent flow generated by the thrust means (5) into the exchange zone (4). Device (1) according to claim 5, wherein: - the thrust means (5) comprise a mixer (10), the mixer (10) comprising a propeller (10a) associated with the inlet opening (3a) configured to rotate around an axis of rotation (X-X); - the converging portion (2b) extends at least in part along the rotation axis (X-X) of the helix (10a). Device (1) according to claim 6, in which the helix (10a) of the mixer (10) is located inside the converging portion (2b) in particular facing the exchange zone (4). 8. Device (1) according to claim 6 or 7, comprising a connecting element (11) fixed integrally to the duct (2) and to the mixer (10) to determine the position of the propeller (10a) with respect to the section convergent (2b). Device (1) according to any one of claims 6 to 8, wherein the mixer (10) comprises a slider (12a) configured to slide in a guide (12b) to fix the position of the device (1) with respect to the surrounding environment. Assembly (13) comprising a guide (12b) and a device (1) according to claim 9, the guide (12b) being arranged vertically to allow the insertion and extraction of the slider (12a).