WO2010062017A1

WO2010062017A1 - Dissolving apparatus

Info

Publication number: WO2010062017A1
Application number: PCT/KR2009/003236
Authority: WO
Inventors: 강원태
Original assignee: Kang Won Tae
Priority date: 2008-11-28
Filing date: 2009-06-17
Publication date: 2010-06-03
Also published as: CN101977672A; CN101977672B; KR100881868B1

Abstract

The present invention relates to a dissolving apparatus for producing a dissolved solution by dissolving a primary fluid into a secondary fluid. The dissolving apparatus comprises: a primary supply pipe for supplying the primary fluid, a secondary supply pipe for supplying the secondary fluid, a vortex induction housing which is connected to the primary and secondary supply pipes and has an open top and a closed bottom to let the primary and secondary fluids move upward, a plate which closes the inside of the vortex induction housing and has multiple openings, vortex induction pipes which are installed in the openings of the plate to move the primary and secondary fluids to the top of the vortex induction housing, and a retention tank which has an outlet on one side to discharge the dissolved solution in which the primary and secondary fluids are dissolved and surrounds the vortex induction housing to guide the dissolved solution from the open top of the vortex induction housing to the outlet. The vortex induction pipes are arranged in pairs so that outlets for the primary and secondary fluids face each other.

Description

[Revision 01.07.2009] by Rule 26

The present invention relates to a dissolution device, and more particularly, to a dissolution device having a plurality of vortex guide tubes and plates to increase the solubility of the second fluid in the first fluid to facilitate dissolution between the fluids. will be.

In general, carbonated water production uses a gas injection nozzle having a dedicated container capable of holding water to a predetermined depth and a sealing member capable of sealing an inlet side of the dedicated container, and then inserting water into the container and closing the container with the sealing member. In the state in which the inlet was sealed, carbon dioxide was introduced into the container at a predetermined pressure so that carbon dioxide was dissolved in water to prepare carbonated water.

However, such a conventional carbonated water production device is to produce carbonated water by directly injecting gas into the liquid using a gas injection nozzle, the contact area of the gas to the liquid is limited to the gas injection region, so that the gas is efficiently dissolved in the liquid There is a problem that can not be.

Accordingly, the present invention has been made to solve the above problems, an object of the present invention is to increase the contact area of the second fluid to the first fluid by a plurality of vortex induction pipes and plates, effectively It is an object of the present invention to provide a dissolution apparatus in which two fluids can be dissolved in a high concentration in the first fluid.

The present invention provides a dissolution apparatus for dissolving a second fluid in a first fluid to produce dissolved water, comprising: a first supply pipe through which a first fluid is supplied; A second supply pipe through which the second fluid is supplied; A vortex induction housing in communication with the first supply pipe and the second supply pipe, the upper part being open and the lower part being closed to allow the first fluid and the second fluid to move upward; A plate closing the inside of the vortex induction housing and having a plurality of openings formed therein; Vortex induction pipes mounted in an opening of the plate to flow the first fluid and the second fluid to the top of the vortex induction housing, the pair of vortex induction pipes arranged in pairs so that the outlets of the first and second fluids face each other; And a retention tank formed at one side and having an outlet for discharging the dissolving liquid in which the second fluid is dissolved in the first fluid and surrounding the vortex induction housing, and including a retention tank for guiding the dissolution liquid from the open top of the vortex induction housing to the outlet. It is characterized by.

The present invention also provides a dissolution apparatus for dissolving a second fluid in a first fluid to produce dissolved water, comprising: a first supply pipe to which a first fluid is supplied; A second supply pipe through which the second fluid is supplied; A vortex induction housing in communication with the first supply pipe and the second supply pipe, the upper part being open and the lower part being closed to allow the first fluid and the second fluid to move upward; A plate closing the inside of the vortex induction housing and having a plurality of openings formed therein; Vortex induction pipes mounted in an opening of the plate to flow the first fluid and the second fluid to the top of the vortex induction housing, the pair of vortex induction pipes arranged in pairs so that the outlets of the first and second fluids face each other; And an outlet for discharging the dissolving liquid in which the second fluid is dissolved in the first fluid on one side and connected to an open upper portion of the vortex induction housing, and flowing down the dissolving liquid in which the second fluid is dissolved in the first fluid. It is preferable to include a retention tank for discharging the dissolved liquid through the outlet of the lower portion.

The present invention configured as described above can use a plurality of vortex induction pipes and plates to widen the contact area of the second fluid with respect to the first fluid, thereby efficiently increasing the solubility of the second fluid with the first fluid. You can.

1 is a cross-sectional view of a dissolution apparatus 100 according to a first embodiment of the present invention, in which the circulation of the first fluid and the second fluid is shown.

2 is a cross-sectional view of a dissolution apparatus 200 according to a second embodiment of the present invention, in which the circulation of the first fluid and the second fluid is shown.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

First embodiment

As shown in FIG. 1, the dissolution apparatus 100 of the present invention includes a retention tank 101, a first supply pipe 111, a second supply pipe 112, a vortex induction housing 110, a plate 130, and a

vortex Guide tubes

141 and 142. The dissolution device 100 is a device for dissolving the second fluid in the first fluid to produce dissolved water. The first fluid refers to a liquid such as water, and the second fluid refers to a liquid or gas having different properties from the first liquid. Hereinafter, for convenience of description, the first fluid is described as a first liquid and the second fluid as a second liquid or gas.

The retention tank 101 has a shape surrounding the vortex induction housing 110, and an outlet 102 for discharging the dissolved liquid is formed at one side. Retention tank 101 includes at least one vortex induction housing 110. The retention tank 101 guides the dissolved liquid from the open top of the vortex induction housing 110 to the outlet 102 and is a member for receiving the dissolved liquid. The dissolved liquid is a liquid in which a second liquid or gas introduced into the second supply pipe 112 is dissolved in the first liquid introduced into the first supply pipe 111. The dissolved liquid will be carbonated water if the first liquid is water, carbon dioxide and oxygen water if the gas introduced into the second feed tube is carbon dioxide, and diluted dye liquid if the second liquid introduced into the second feed tube is a dye source.

The vortex induction housing 110 is installed inside the retention tank 101 and communicates with the first supply pipe 111 and the second supply pipe 112. The vortex induction housing 110 conducts vortex induction of the first liquid and the second liquid, or the first liquid and the gas supplied into the vortex induction housing 110 through the first supply pipe 111 and the second supply pipe 112. It is a member for guiding to move to the upper portion of the housing (110). The shape of the vortex induction housing 110 is a shape in which the top is open and the bottom is closed. The vortex induction housing may be located on the side in the reservoir, although the open portion may be located at the top in the reservoir as shown in FIG. 1. In addition, the shape, the installation position, the number, and the like of the vortex induction housing can be variously modified and changed within a range recognized by those skilled in the art.

The plate 130 is installed inside the vortex induction housing 110 to close the interior of the vortex induction housing 110. A plurality of openings 131 are formed in the plate 130, so that the first liquid and gas, or the first liquid and the second liquid introduced into the vortex induction housing 110, guide the vortex through the plurality of openings 131. It flows to the top of the housing 110. The shape, size, number, and the like of the plate 130 may be modified and changed within the scope apparent to those skilled in the art.

The first vortex induction pipe 141 and the second vortex induction pipe 142 are installed in the openings 131 of the plate 130, and more preferably through the openings 131 of the plate 130 up and down It is installed to protrude.

The shape of the first vortex induction pipe 141 is a tubular shape of a tracer (a) in which the first inlet opening 141a and the first outlet opening 141b are formed, and the shape of the second vortex induction pipe 142 is first. The tubular shape of the tracer (a) shape in which the 2 inflow openings 142a and the 2nd discharge openings 142b are formed is preferable.

The first vortex induction pipe 141 and the second vortex induction pipe 142 are arranged on the plate 130 in a pair so that the first discharge opening 141b and the second discharge opening 142b face each other. The shape, size, number, and the like of the

vortex induction pipes

141 and 142 may be modified and changed within the scope apparent to those skilled in the art.

Meanwhile, in the present embodiment, a plurality of plates 130 and a plurality of

vortex induction pipes

141 and 142 are installed in the vortex induction housing 110 in the longitudinal direction of the vortex induction housing (ie, the flow direction of the fluid). do. This allows the flow of the first liquid and gas, or the first liquid and the second liquid, to proceed continuously through a plurality of plates and vortex guide tubes, thereby increasing the solubility of the gas in the first liquid, This is because it is possible to increase the solubility between the first liquid and the second liquid which are mutually different in properties.

Hereinafter, referring to FIG. 1, the flow of the gas and the first liquid introduced into the vortex induction housing 110, and thus the vortex formation will be described. The flow of the first liquid and the second liquid and thus the vortex formation is the same as that of the gas and the first liquid. Hereinafter, the flow of the first liquid and the gas and the vortex formation will be described, and the flow of the first liquid and the gas proceeds along an arrow.

First, the first liquid and gas flow into the lower portion of the vortex induction housing 110 through the first supply pipe 111 and the second supply pipe 112 communicated with the vortex induction housing 110. The gas and the first liquid introduced in this way flow upward due to the first liquid and gas introduced thereafter. A portion of the first liquid and gas flowing upward flows upwardly and enters the first vortex induction pipe 141 and the second vortex induction pipe 142 through the first inlet opening 141a and the second inlet opening 142a. And the other part is blocked by the lower end 130b of the plate 130 and is redirected to the lower side of the vortex induction housing 110. The first liquid and gas blocked at the bottom 130b of the plate 130 are vortexed by the collision, which will dissolve the gas in the first liquid.

According to the shape of the first vortex induction pipe 141, the flow direction of the first liquid and the gas introduced into the first inlet 141a is changed toward the first outlet 141b. The flow direction of the second liquid and gas introduced into the second vortex induction pipe 142 is also changed in the flow direction toward the second discharge opening 142b along the shape of the second vortex induction pipe 142.

The first liquid and gas flowing into the inside of the vortex induction housing 110 and flowing upward are diverted in directions of the first vortex induction pipe 141 and the second vortex induction pipe 142 and positioned to face each other. It is discharged through the first discharge opening 141b and the second discharge opening 142b. As such, vortices are formed by the collision of the first liquid and the gas discharged in opposite directions, thereby increasing the contact area between the first liquid and the gas, thereby increasing the solubility of the gas in the first liquid. . This process produces a dissolved liquid in which gas is dissolved in the first liquid.

The first liquid and the gas discharged through the first and

second discharge openings

141b and 142b are converted after the collision so that the flow direction is turned upward by the gas and the first liquid introduced thereafter. The above-described flow of the first liquid and gas proceeds repeatedly along the direction of the arrow.

The high concentration of dissolved liquid generated while passing through the plurality of plates 130 and the plurality of

vortex induction pipes

141 and 142 flows into the retention tank 101 from the open top of the vortex induction housing 110. Dissolved liquids and gases are stabilized in the retention tank 101 in the course of moving from the open top of the vortex induction housing 110 to the outlet 102. The dissolved liquid is discharged through the outlet 102 located on one side of the retention tank 101.

Hereinafter, the dissolution apparatus according to the second embodiment of the present invention will be described with reference to FIG. 2.

Second embodiment

2 is a cross-sectional view of the dissolution apparatus 200 according to the second embodiment of the present invention, in which the circulation of the first liquid and gas is shown. The circulation of the first liquid and the second liquid is the same as that of the first liquid and the gas.

In this embodiment, the shape of the vortex induction housing 210 performing the same function as in the first embodiment described above, the shape and position of the plate 230 and the

vortex induction pipes

241 and 242, the first supply pipe ( 211) and the position of the second supply pipe 212, the flow direction of the liquid, the flow direction of the gas and the like will be omitted.

Hereinafter, only the shape of the retention tank 201 and the connection relationship between the retention tank 201 and the vortex induction housing 210 will be described. Referring to Figure 2 as follows.

As shown in FIG. 2, the vortex induction housing 210 is not accommodated in the retention tank 201, but the upper portion of the vortex induction housing 210 and the upper portion of the retention tank 201 are connected to each other. That is, the vortex induction housing 210 and the retention tank 201 have a wedge shape in which the upper part of the vortex induction housing 210 and the upper part of the retention tank 201 are connected to each other.

Meanwhile, the first liquid and gas introduced into the vortex induction housing 210 flow in the same manner as in the first embodiment, and flow into the retention tank 201 through the open upper portion of the vortex induction housing 210.

The illustrative embodiments described above are intended to be illustrative within all aspects of the invention rather than limiting. Accordingly, the present invention is capable of many modifications and detailed implementations which may be obtained from those contained within the specification by those skilled in the art. All such modifications and variations are considered to be within the scope and spirit of the invention as defined by the following claims.

Claims

A dissolution apparatus for dissolving a second fluid in a first fluid to produce dissolved water,

A first supply pipe through which the first fluid is supplied;

A second supply pipe through which the second fluid is supplied;

A vortex induction housing in communication with the first supply pipe and the second supply pipe, the top of which is open and the bottom of which is closed to allow the first fluid and the second fluid to move to the top;

A plate closing the inside of the vortex induction housing and having a plurality of openings;

Vortex guide tubes mounted in an opening of the plate to flow the first fluid and the second fluid to an upper portion of the vortex induction housing, the pair of vortex induction tubes being arranged so that the outlets of the first and second fluids face each other. ; And

An outlet for discharging the dissolving liquid in which the second fluid is dissolved in the first fluid is formed at one side and surrounding the vortex induction housing, and guiding the dissolution liquid from the open upper portion of the vortex induction housing to the outlet. Dissolution apparatus comprising a retention tank.
A dissolution apparatus for dissolving a second fluid in a first fluid to produce dissolved water,

A first supply pipe through which the first fluid is supplied;

A second supply pipe through which the second fluid is supplied;

A vortex induction housing in communication with the first supply pipe and the second supply pipe, the top of which is open and the bottom of which is closed to allow the first fluid and the second fluid to move to the top;

A plate closing the inside of the vortex induction housing and having a plurality of openings;

Vortex guide tubes mounted in an opening of the plate to flow the first fluid and the second fluid to an upper portion of the vortex induction housing, the pair of vortex induction tubes being arranged so that the outlets of the first and second fluids face each other. ; And

On one side is formed an outlet for flowing out the dissolved liquid in which the second fluid is dissolved in the first fluid

And a retention tank connected to an open upper portion of the vortex induction housing, for flowing down the dissolved liquid in which the second fluid is dissolved in the first fluid, and then discharging the dissolved liquid through an outlet of the lower portion. Dissolving device.