ES2352166T3 - APPARATUS AND PROCEDURE FOR GENERATING AND DISTRIBUTING BUBBLES IN A GAS AND LIQUID MIXTURE. - Google Patents

Abstract

The invention concerns n apparatus for providing and distributing bubbles in a gas-liquid mix transported in a flow path of a pipe. The apparatus is arranged in line with the pipe and comprises in successive order an inlet region, an obstacle unit and an outlet region. The inlet region is arranged for the entering of gas-liquid mix containing initial sized bubbles, the inlet region is provided to accelerate and direct the flow into the obstacle unit. The obstacle unit is provided with structure elements to produce a turbulence whereby reducing the initial sized bubbles to smaller sized bubbles and dispersing the bubbles in the flow. The outlet region is arranged for the entering of the gas-liquid mix containing smaller sized bubbles and has provisions to accelerate the flow and maintain an even distribution of smaller sized bubbles in the flow for further transport in the pipe. The invention also include an method.

Description

The present invention relates to an apparatus and a method for generating and distributing bubbles in a mixture of gas and liquid transported in a flow path of a tube.

The object of the invention is to obtain an efficient dissolution and / or distribution of the gas in the liquid during transport in the tube. Another object of the invention is to reduce the size of the initial bubbles in the liquid and distribute said bubbles in the flow.

Procedures and apparatus can be applied to provide bubbles of a smaller size to dissolve the gas in liquid in different technical fields. The dissolution of oxygen in water is of special interest for the present invention, even if the invention is applicable to other uses in which different types of gases and liquids may be part of the current process. The water to be used for fish farms presents a need to dissolve oxygen in the water transported through a tube in the pools or deposits for the fish to live. The production and distribution of bubbles with a smaller size according to the invention is advantageous for dissolving oxygen in water. Even if fish farms are of particular interest, the invention can be applied in other technical fields, such as, for example, adding gas (eg oxygen or carbon dioxide) to wastewater, drinking water and various process flows.

In the prior art, devices for generating microbubbles are described, for example, in JP 2006326484. The apparatus disclosed in said publication has a box-shaped structure divided into three compartments. A mixture of gas and liquid is introduced through an entrance into the first compartment and said mixture flows from the first to the second and from the second to the third compartment, through small holes made in the common wall between each two compartments. The small holes generate microbubbles in the liquid and the flow leaves the box structure through an outlet arranged in the third compartment.

Due to the device configuration of JP 2006326484 a significant pressure loss occurs when the mixture passes through the device. The speed of said mixture when passing through the outlet is low and, therefore, the risk of joining the bubbles is substantial. If this device had to be used in the same application as the invention, given the condition that the mixture that flows outside through the outlet needs a certain level of pressure, it would be necessary to install an additional pump in the third compartment, to maintain the working pressure in the tube arrangement in which the invention is installed. The installation of an additional pump increases the level of costs, as well as the need for maintenance.

The apparatus according to the present invention has a construction of reduced cost, relatively simple and without parts, such as an additional pump with the need for frequent revision, or increased operating costs, since the pressure loss of the apparatus is low and the flow moves through the apparatus using the pressure in the fluid path. In addition, the device of JP 2006326484 provides for an input and an output arranged in an angular relationship, whereby said device of JP 2006326484 would not be suitable for adaptation in an in-line arrangement with an elongated driving arrangement, as is oriented the present invention. In the device of JP 2006326484, the gas dissolves in the liquid when the mixture passes through the device due to the size of the volume captured in the device and the retention period in which the mixture remains in said device, while the objective The main feature of the apparatus according to the invention is to provide bubbles of a smaller size and obtain a uniform distribution thereof in the flow. When the present invention is used, the dissolution process takes place in several stages; a part of the dissolution process takes place prior to the entry of the flow into the apparatus according to the invention, another part of the dissolution process occurs in the apparatus, and the process is terminated after the flow has left the apparatus, by example in the fish pond. The size of the holes between the compartments of the device disclosed in JP 2006326484 makes the device vulnerable to obstructions due to leaves, branches, etc. that enter the device.

Reference should also be made to US publications 6,982,968, WO 01/36105 and JP 2003117365.

US Patent No. 6,982,968 shows a nozzle device for the treatment of wastewater, in which the object of the invention relates to the release and elevation of microbubbles from the liquid. Thus, the object of the invention of US Patent No. 6,982,968 is the opposite of the objective of the present invention, since an important aspect of the invention is to prevent the accumulation of smaller bubbles in the upper part of the flow and maintain a uniform distribution of the bubbles

smaller in size through the cross section of the flow.

WO 01/36105 shows a nozzle provided with holes of different sizes for the introduction of liquid and gas into a tube element. The publication does not refer to the disintegration of bubbles in smaller bubbles or to the obtaining of a certain arrangement of the bubbles in the flow.

JP 2003117365 refers to the reduction of bubbles in microbubbles through the use of a pump that provides stirring and pressurization of a mixture of gas and liquid. This procedure cannot be applied to the present invention.

Other devices according to the prior art are disclosed in US 2004/0251566 and US 5,810,052.

US 2004/0251566 discloses a device for generating microbubbles, said device comprising multiple cavitation generators. The device, in its various embodiments, provides an inlet for liquid and a path for the entry of the gas downstream of the liquid inlet. The path for the gas inlet is arranged so that said gas is supplied in the first cavitation generator, which can be a baffle or other constrictions to the flow path, and is mixed with the liquid in this place. Downstream of the first cavitation generator, a first cavitation field is generated. Next, the flow enters a second cavitation generator and, a second cavitation field is generated downstream of the second cavitation generator. In the flow channel of the bubble generating device of US 2004/025 1566, any number of hydrodynamic cavitation stages can be provided.

US Patent No. 5,810,052 discloses an apparatus for mixing two liquids, for example, oil and water. Since said device is intended for mixing oil and water, high pressure conditions are required to obtain the mixture between both liquids. The pressure drop in the D2 apparatus is quite important and the objective of the apparatus is to create the conditions for using the cavitation effect.

The object of the invention is achieved by the apparatus as defined in the independent claim of said apparatus and in the independent claim of the process. Other embodiments of the invention are defined in the following subordinate claims.

According to the first independent claim, an apparatus is provided for

provide and distribute bubbles in a mixture of gas and liquid transported in a fluid path in a tube. The apparatus is arranged in line with the tube and comprises, in successive order, an entrance zone, an obstacle unit and an exit zone. The entrance area is arranged for the entrance of the gas and liquid mixture containing the initial size bubbles and, in addition, the entrance area is provided to accelerate and direct the flow in the obstacle unit. Said obstacle unit is provided with structural elements to produce a turbulence with which the initial size of the bubbles is reduced to bubbles with a smaller size and, in addition, to disperse and distribute the bubbles evenly in the flow. The outlet zone is provided for the entry of the gas and liquid mixture containing bubbles with a smaller size, and accelerates the flow and maintains a uniform distribution of said smaller size bubbles in the flow for subsequent transport in the tube.

According to the second independent claim, the invention also includes a method.

In an embodiment of the invention, the objective of the apparatus is to produce microbubbles distributed uniformly through the cross-section of the flow, in order to achieve the effective dissolution of the gas in the liquid. In this embodiment, the small bubbles constitute the initial size bubbles and the microbubbles constitute the bubbles with a smaller size.

Various types of gas and liquid, preferably transported in a mixture, may be suitable for the apparatus according to the independent claims. The gas may be present in various states and quantities in the liquid, and the states may vary as the mixture is transported through the apparatus. The gas may be present only as a bubble in the liquid, or the gas may be present both as a bubble and partially dissolved in the liquid. The gas can also be introduced in liquid form. Said gas is introduced into the liquid that flows through the fluid path of the tube through, for example, a gas inlet located in said fluid path. Bubbles of an initial size can be generated when the gas is inserted into the liquid. The gas inlet is preferably located upstream of the entrance of the inlet zone and would be connected to a gas supply by suitable means.

The tube in which the gas and liquid mixture is transported comprises at least one tube element. Said tube may be composed of a plurality of tube elements arranged in an elongated relationship forming a conduit. Each tube element is formed with at least one fluid path and, preferably, is attached to an end-to-end arrangement. The size, shape, flexibility and material of the individual tube element may vary depending on the field of use.

The apparatus is arranged in an in-line relationship with respect to the tube. The fluid path of the tube defines a main direction of flow. The flow is transported by the apparatus in a direction corresponding to the main direction of the flow. Unlike in the device of document JP2006326484, when the apparatus is installed in an existing line, the main direction of the flow is not altered when the flow travels through the apparatus. The in-line arrangement of the apparatus according to the invention allows the gas and liquid mixture to be displaced by the apparatus to use the pressure existing in the tube.

In addition, the online arrangement makes installation of the device in an existing pipe / conduit easier. Preferably, the installation takes place in situ, where a part of the tube is removed and the apparatus according to the invention to be used is inserted and connected to the remaining parts of the tube. If the apparatus according to the invention is to be used in a tube that transports liquid and gas to an aquaculture pool, the installation can be carried out by the owner or maintenance staff of the farm, because the installation procedure is quite Simple and does not require specific professional skills.

The apparatus as contributes to the dissolution of gas in liquid. In one embodiment, the dissolution of gas in liquid takes place in several places during transport by the tube and the apparatus according to the invention. A part of the gas inserted in the liquid can dissolve upstream of the inlet zone. Another part of the gas can be dissolved during transport by the apparatus and the remaining part of the gas can be dissolved downstream of the outlet zone, for example during additional transport in the tube or in the tank, where the mouth of the tube. For example, a deposit such as the fish pond included in a fish farm.

The apparatus according to the invention offers a simple alternative, with lower costs and effective to obtain an efficient dissolution of gas, such as oxygen, in liquid, such as water. One or more components: the entrance area, the obstruction unit and / or the exit zone may consist of prefabricated elements, such as standard elements made of a plastic material or a metallic material.

In one embodiment, a flow obstacle is provided on a path of

The obstacle unit. The flow obstacle is arranged so that at least one opening appears between the flow obstacle and the wall of the path. Said flow obstacle may be constituted by a structural element fixed by suitable means in the path leaving one or more openings between the element and the wall of the path so that the flow passes through them. By introducing the flow obstacle which, preferably, is provided with a determined flow stop zone disposed essentially in the center of the path, the flow hits said flow obstacle and is forced in a direction transverse to the main direction of the flow prior to its passage through the opening / s, preferably arranged in the perimeter of the flow obstacle. Due to the incidence caused by the impact on the flow obstacle, turbulence occurs downstream of said flow obstacle that causes a reduction in the initial size of the bubbles to smaller bubbles and also disperses the bubbles in the flow.

The flow obstacle can be conceived by several structures, in which the arrangement of a solid material structure arranged in the center of the path that leaves an opening for the flow to pass in the perimeter of the structure, provides the basis for achieving a turbulence. The flow obstacle may be provided by a disk-shaped structure with one or more openings, preferably through holes. The hole (s) is preferably disposed in proximity to the perimeter of the disk and the central part of the disk constitutes a flow stop zone. Alternatively, the flow obstacle is made with a cross-shaped cross-section, with arms that generally have the same length and an intersection that generally has a circular shape that constitutes the flow stop zone. (The arm zone can be included in the flow stop zone). In another embodiment, an elongate element disposed in the obstacle unit, for example a tube element, forms the flow obstacle. Said elongate element may be arranged transversely to the main direction of the flow, so that at least one opening is provided between the travel wall and said flow obstacle.

The size of the flow obstacle or the flow stop zone and the openings are made depending on the pressure available in the flow path. The total open area of the flow obstacle is calculated according to the total pressure drop available and / or desired in the unit. In this way, this total open area is distributed in one or more openings, so that the total open area of the flow obstacle and thus the pressure drop remain unchanged. The entrance area may provide arrangements to accelerate and direct the flow in the obstacle unit. In one embodiment, the entrance area provides a path provided to reduce the size of the cross-section of the flow passing through the opening, thereby obtaining an acceleration effect. The entrance area can be formed as an element similar to the venturi type.

In addition, the exit zone can be foreseen as a structure similar to the entrance zone. In one embodiment, the exit zone provides a path provided to reduce the cross-sectional size of the flow passing through the exit, thereby obtaining an acceleration effect. The exit zone can be formed as an element similar to a venturi.

In the following example, the invention will be described with reference to the accompanying drawings, in which:

Figure 1 shows a first embodiment of the invention; Figure 2 shows a first embodiment of the invention arranged in a tube element; Figure 3 shows a second embodiment of the invention; Figure 4 shows the invention arranged in a tube assembly; Figure 5 shows a third embodiment of the invention.

Figure 1 shows the apparatus 1 comprising an inlet zone 2, an obstacle unit, shown in the figure as a turbulence chamber 3 and an outlet zone 4. A liquid flow is transported in a flow path 6. The flow of liquid is illustrated by arrows. Arrow 5a shows a main direction of flow of the flow path 6. Gas is introduced into the tube by a gas supply 7a that feeds gas into the liquid through a gas inlet 7b, such as a gas diffuser or other equipment suitable. The gas in the flow path 6 is shown as points 8 illustrating gas bubbles, preferably bubbles with a small size. The mixture of liquid and gas enters the inlet zone 2, shown herein as an element of the venturi type, which is formed with a narrow open path in a conical path that increases and decreases respectively. This narrow path of the inlet zone 2 ensures a sufficiently good bubble concentration through the cross section of the flow and accelerates the flow in the direction of a flow obstacle 12

arranged in the turbulence chamber 3.

The flow obstacle 12 is shown as a plate or disk element provided with openings 10, as through holes. Four openings 10 shown in proximity to the perimeter of the flow obstacle 12 are shown in Figure 1. The amount and size of the diameter and the length of the opening may vary according to, for example, with the diameter of the tube, the use of material, the pressure available in the tube, as well as other design criteria. The flow obstacle 12 has a flow stop zone 11 provided with a solid part of the disk structure arranged essentially centered around the axial axis of the tube. The flow hits the flow stop zone 11 in a main flow direction and experiences a change in the flow direction. The impact of the flow in the flow stop zone 11, forces said flow in a direction transverse to the main direction of the flow towards the perimeter of the flow obstacle 12, before taking the main direction of the flow passing through the openings 10 This causes an initial reduction in bubble size. A turbulence zone emerges downstream of the flow obstacle 12 illustrated by the arrows 5b, causing a further reduction in the size of the bubbles, preferably to a size of microbubbles, and the bubbles are dispersed through the cross-section of the tube. Next, the mixture of liquid and gas enters the outlet zone 4, which is shown herein as an element of the venturi type, which is formed by a narrow path opening in a conical path that increases and decreases respectively. In the outlet zone 4, the flow is accelerated, causing and maintaining a uniform distribution of the bubbles through the cross-section of the flow, to avoid the accumulation of bubbles in the upper part and ensure efficient contact surfaces between the bubbles of liquid and gas for transport in the tube.

In Figure 2, the apparatus 1 of Figure 1 is shown made by several tube elements, with a cover tube 14 arranged around the tube elements. Said tube elements that make up the apparatus 1 are standard elements, for example made of some kind of plastic or metallic material. The flow obstacle 12 can also be made by a standard element, for example, a metal plate.

Figure 3 shows a second embodiment of the apparatus 1, in which the inlet zone 24, the outlet zone 26 and the flow obstacle 22 are all constituted by disk or plate elements with screw holes 30 which provide fixing points for the elements. The other elements of the figure generally correspond to the elements of the figure. The disk elements of the input and output zone 24, 26 respectively are each arranged with a path that provides a restriction in the flow path. The entrance zone 24, the exit zone 26 and the flow obstacle 22 according to the second embodiment have the same functions and cause the same effects on the flow as those mentioned in the description of the entrance zones and exit 2, 4 and the flow obstacle 22 above. The flow obstacle 22 has a cross-shaped cross section with arms that generally have the same length and an intersection that generally has a circular shape that make up the flow stop zone 21. The arms define openings 20 for the flow path. .

In Figure 4, the apparatus 1 is shown with the cover tube as shown in Figure 2, installed in a tube or tube, such as the tube 15. The apparatus 1 is shown in an arrangement in line with the tube 15. When the apparatus 1 is installed, the existing tube is divided into separate parts. The apparatus 1 is disposed between said parts and each end of the apparatus 1 is connected to the separate parts of the tube 15. The installation procedure takes place on site and is quite simple. Since the installation is quite easy, the fish farmer can carry it out and can take care of its maintenance, making the installation and maintenance staff not necessary in most cases. The arrangement shown in Figure 4 is an arrangement that is used in a farm. The tube 15 carries water (fresh water or salt water) illustrated by arrow 16 and oxygen is inserted through the gas inlet 7 that will dissolve in the water. The end of the tube 15 submerged in a fish tank 18 is shown and is provided with outlets for the flow of the mixture of water and gas with microbubbles. Parts of oxygen can be dissolved in the liquid before the flow enters the apparatus 1, other parts dissolve in the liquid in the apparatus 1 and after leaving said apparatus 1. After leaving said apparatus it can take place the dissolution in the tube 15 and / or in the fish tank 18. A similar installation principle can be used for purposes other than the addition of oxygen for fish farms mentioned. An example is the addition of carbon dioxide to wastewater with a high pH prior to the drain outlet.

Figure 5 shows the apparatus 1 according to a third version of the invention, in the

that the input zone 2 and the output zone 4 correspond to those shown in the

Figure 1. The embodiment of the flow obstacle arranged in the turbulence chamber 3 comprises a tube element 31 arranged so that two openings 30 are incorporated for the flow path. The central axis 32 of the tube element 31 is shown in a transverse orientation to the main direction of the flow 5b. The tube element 31 can be provided with its central axis 32 perpendicular to both the main direction of the flow 5a and the central axis 32 as shown in Figure 5. The use of a tube element (rounded) as a flow obstacle gives a low pressure loss compared to a flat surface.

Claims (14)

1. Apparatus (1) for providing and distributing bubbles (8) in a mixture of gas and liquid transported in a flow path (6) of a tube, the apparatus being arranged in line with the tube and successively comprising a entrance zone (2), an obstacle unit (3) and an exit zone (4), in which -the inlet zone (2) is arranged for the entrance of the gas and liquid mixture containing the initial size bubbles, said inlet zone (2) being provided to accelerate and direct the flow to - the obstacle unit (3) provided with structural elements to produce a turbulence, thereby reducing the initial size bubbles to smaller bubbles and dispersing the bubbles in the flow, and a flow obstacle (12) is arranged in a path of the obstacle unit (3), providing at least one opening between the flow obstacle (12) and a travel wall, the flow obstacle having a determined flow stop zone (21) arranged essentially in the center of the path, providing at least one opening between the flow obstacle (12) and the travel wall, - the outlet zone (4) is arranged for the entrance of the gas and liquid mixture containing bubbles of smaller size and is designed to accelerate the flow and maintain a regular distribution of the smaller bubbles in the flow for later transport in the tube.

2.

Apparatus according to claim 1, characterized in that the bubbles of initial size comprise bubbles of smaller size and / or bubbles of smaller size comprise bubbles of micro size.

3.

Apparatus according to one of claims 1 or 2, characterized in that the flow obstacle (12) comprises a disk-shaped structure arranged with one or more openings, preferably through holes, said hole / s being preferably arranged in the vicinity of the perimeter of the disk.

Four.

Apparatus according to one of claims 1 or 2, characterized in that the flow obstacle (12) has a cross-section in the form of a cross with arms that generally have the same length and an intersection generally in a circular shape.

5.

Apparatus according to one of claims 1 or 2, characterized in that the flow obstacle comprises an elongate element, in particular a tube element (31).

6.

Apparatus according to one of the preceding claims, characterized in that the size of the flow stop zone and / or the amount of openings are made depending on the pressure drop available in the flow obstacle.

7.

Apparatus according to one of the preceding claims, characterized in that the inlet zone and / or the outlet zone each have a path provided to reduce the size of the cross section of the flow to pass through the path.

8.

Apparatus according to one of the preceding claims, characterized in that the entrance zone and / or the exit zone are formed as an element of the venturi type.

9.

Apparatus according to one of the preceding claims, characterized in that a gas inlet is provided upstream of the entrance of the entrance area.

10.

Apparatus according to one of the preceding claims, characterized in that the entrance area and / or the obstruction unit and / or the exit zone are provided by prefabricated elements.

eleven.

Apparatus according to one of the preceding claims, characterized in that the tube transports a mixture of liquid and gas to a tank, such as a fish pond

(18) provided in a fish farm. An apparatus according to one of the preceding claims, characterized in that a part of the gas inserted in the liquid dissolves upstream of the inlet zone, another part of the gas dissolves during transport through the apparatus and the remaining part of the gas is dissolves downstream from the exit zone.

13.

Apparatus according to one of the preceding claims, characterized in that the liquid comprises water and / or the gas comprises oxygen.

14.

Method for providing and distributing bubbles in a mixture of gas and liquid transported in a tube, by using an apparatus (1) according to one of claims 1 to 13, wherein the apparatus is arranged in line with the tube and comprises , in successive order, an entry zone (2), an obstacle unit (3) and an exit zone (4), comprising the following steps:

-

the gas and liquid mixture containing the initial size bubbles access

to the entrance zone (2), in which the provisions of said entrance zone

(2) accelerate and direct the flow towards

-

the obstacle unit (3), provided with structural elements that it produces

a

turbulence, thereby reducing the initial size bubbles to

bubbles

from Minor size Y scattering sayings  bubbles in he flow, to

continuation

-

the gas and liquid mixture containing smaller bubbles accesses the

exit zone (4), accelerating the provisions of said exit zone (4) the

flow and maintaining a regular distribution of smaller bubbles

in the flow for later transport in the tube.