KR102369774B1 - Apparatus for neutralizing of liquified carbon dioxide gas - Google Patents

Abstract

The present invention provides a reactor comprising: a reactor having an inlet through which alkaline wastewater is introduced, and a wastewater flow part allowing the alkaline wastewater to flow; and a liquefied carbon dioxide cylinder connected to the reactor, accommodating liquefied carbon dioxide, and supplying the liquefied carbon dioxide to the reactor to dissolve the liquefied carbon dioxide in the alkaline wastewater, the reactor is, a first pipe formed in plurality; and a second pipe having a curved shape that is fixedly installed between each of the plurality of first pipes.

Description

Liquefied carbon dioxide neutralization device {APPARATUS FOR NEUTRALIZING OF LIQUIFIED CARBON DIOXIDE GAS}

The present invention relates to a device for neutralizing liquefied carbon dioxide, and more particularly, to a device for dissolving and neutralizing liquefied carbon dioxide gas that promotes dissolution through a reactor using a pipe.

In general, strong acids or weakly acidic chemicals such as sulfuric acid (H ₂ SO ₄ ) are used to treat alkaline wastewater generated at industrial sites. When using high-concentration sulfuric acid according to the application of the Chemicals Control Act, it is necessary to conduct a pre-evaluation of the impact. In order to solve this inconvenience, a technique for adjusting the pH of water by adding carbon dioxide is known.

There are two types of technology for adjusting the pH of water by injecting carbon dioxide. There is a method of directly injecting carbon dioxide into raw water in a gaseous state and a method of supplying carbon dioxide in a dissolved state.

The direct injection method of carbon dioxide into raw water connects the carbon dioxide pipe to the raw water pipe and injects it. The facility is simple and easy to install, but it has the disadvantages of low carbon dioxide dissolution rate and difficult pH adjustment. The method of dissolving it in a furnace and supplying it to raw water is mainly used.

In particular, in this method, it is necessary to develop a device that can treat the pH to neutral by reacting carbon dioxide with raw water and does not require a separate input of sulfuric acid.

In addition, it is required to develop a device that can neutralize raw water using carbon dioxide gas to satisfy the pH conditions suitable for the downstream flocculation reaction and effluent standards, and can be used as a pretreatment for downstream filthy water treatment facilities.

The present invention has been devised to solve the above problems, and an object of the present invention is to provide a device for injecting liquefied carbon dioxide gas for pH control of alkaline wastewater and a device for dissolving high concentration of carbon dioxide using a pipe.

The apparatus for neutralizing liquefied carbon dioxide according to the present invention comprises: a reactor having an inlet through which alkaline wastewater is introduced, and a wastewater flow part allowing the alkaline wastewater to flow; and a liquefied carbon dioxide cylinder connected to the reactor, accommodating liquefied carbon dioxide, and supplying the liquefied carbon dioxide to the reactor to dissolve the liquefied carbon dioxide in the alkaline wastewater, the reactor is, a first pipe formed in plurality; and a second pipe having a curved shape that is fixedly installed between each of the plurality of first pipes.

According to an example related to the present invention, the first pipe is made of a straight pipe, and the plurality of straight first pipe and the plurality of curved second pipe are arranged in parallel with each other.

According to another example related to the present invention, the apparatus for neutralizing liquefied carbon dioxide of the present invention further includes a control unit capable of controlling the supply of the liquefied carbon dioxide gas based on the pH concentration of the alkaline wastewater inside the reactor.

The control unit may include: a pH control unit configured to control opening and closing of the supply valve based on a pH value inside the reactor; And it may include a pressure control unit for operating an alarm based on the pressure value inside the gas supply pipe connected to the outlet of the liquefied carbon dioxide cylinder.

Preferably, the pH control unit is provided with the pH value inside the reactor and, when the pH value is higher than the required pH value, opens the supply valve installed in the gas supply pipe, and when the pH value is less than the required pH value, the supply valve can be closed. there is.

According to another example related to the present invention, the apparatus for neutralizing liquefied carbon dioxide of the present invention further includes a mixing member installed on the inlet side of the first pipe to stir the liquefied carbon dioxide and alkaline wastewater to be mixed.

Preferably, the mixing member includes: a first member provided in plurality and having a shape twisted in one direction so as to have a curved surface portion; and a second member provided in plurality and having a shape twisted in the one direction and the other direction so as to have a curved portion.

The liquid carbon dioxide neutralization device of the present invention can treat the pH to neutral by reacting the liquid carbon dioxide gas with alkaline wastewater. Shorten the dissolution time of liquefied carbon dioxide.

In addition, in the apparatus for neutralizing liquefied carbon dioxide of the present invention, the number of collisions between liquefied carbon dioxide gas and alkaline wastewater is increased inside the reactor, so that the contact area of microbubbles with water is increased, so that the neutralization treatment is performed with carbonated water completely dissolved in high concentration. to make it happen efficiently.

In addition, the apparatus for neutralizing liquefied carbon dioxide of the present invention efficiently neutralizes liquefied carbon dioxide and alkaline wastewater by controlling the supply of liquefied carbon dioxide by the pH concentration of the alkaline wastewater and the pressure of the liquefied carbon dioxide gas.

On the other hand, in the apparatus for neutralizing liquefied carbon dioxide of the present invention, the neutralization treatment efficiency can be further improved by stirring the mixing member so that the liquefied carbon dioxide and the alkaline wastewater can be mixed.

1 is a conceptual diagram showing an example of a liquefied carbon dioxide neutralization device of the present invention.
2 is a cross-sectional view showing a reactor of the present invention.
Figure 3a is a perspective view showing a mixing member of the present invention.
Figure 3b is a cross-sectional view showing the mixing member of the present invention.
4 is a conceptual diagram showing an example in which the reactor of the present invention is installed in a sedimentation facility.

Hereinafter, the embodiments disclosed in the present specification will be described in detail with reference to the accompanying drawings, but the same or similar reference numerals are assigned to the same or similar components, and overlapping descriptions thereof will be omitted. The suffix "part" for the components used in the following description is given or mixed in consideration of only the ease of writing the specification, and does not have a meaning or role distinct from each other by itself. In addition, in describing the embodiments disclosed in the present specification, if it is determined that detailed descriptions of related known technologies may obscure the gist of the embodiments disclosed in the present specification, the detailed description thereof will be omitted. In addition, the accompanying drawings are only for easy understanding of the embodiments disclosed in this specification, and the technical idea disclosed herein is not limited by the accompanying drawings, and all changes included in the spirit and scope of the present invention , should be understood to include equivalents or substitutes.

Terms including an ordinal number such as 1st, 2nd, etc. may be used to describe various elements, but the elements are not limited by the terms. The above terms are used only for the purpose of distinguishing one component from another.

When a component is referred to as being “connected” to another component, it may be directly connected to the other component, but it should be understood that other components may exist in between.

The singular expression includes the plural expression unless the context clearly dictates otherwise.

In the present application, terms such as “comprises” or “have” are intended to designate that a feature, number, step, operation, component, part, or combination thereof described in the specification exists, but one or more other features It should be understood that this does not preclude the existence or addition of numbers, steps, operations, components, parts, or combinations thereof.

1 is a conceptual diagram illustrating an example of a liquefied carbon dioxide neutralization apparatus 100 of the present invention, and FIG. 2 is a cross-sectional view showing a reactor 10 of the present invention. In addition, FIG. 3A is a perspective view showing the mixing member 60 of the present invention, and FIG. 3B is a cross-sectional view showing the mixing member 60 of the present invention.

1 to 3b, the liquefied carbon dioxide gas neutralization device 100 of the present invention will be described.

The apparatus 100 for neutralizing liquefied carbon dioxide according to the present invention includes a reactor 10 and a liquefied carbon dioxide cylinder 20 .

The reactor 10 has an inlet 11 through which alkaline wastewater is introduced, and a wastewater flow section 12b that allows alkaline wastewater to flow.

The reactor 10 includes first and second pipes 12 and 14 .

The first pipe 12 is formed in plurality. For example, the first pipe 12 may be formed of a straight pipe, and the plurality of first pipes 12 may be arranged in parallel with each other.

Since gas rises by buoyancy in water, it is preferable that the first pipe 12 is configured as an upflow pipe to maximize the mixing effect of liquefied carbon dioxide gas and alkaline wastewater.

The second pipe 14 has a curved shape that is fixedly installed between each of the plurality of first pipes 12 . In addition, the second pipe 14 may have a bent portion. The first and second pipes 12 and 14 may have a zigzag shape as a whole.

FIG. 2 shows an example in which a plurality of first pipes 12 arranged in parallel with each other and a second pipe 14 having a curved shape are fixedly installed between each of the first pipes 12 . In addition, referring to FIG. 2 , the reactor 10 may be installed in the base portion 19a and the support frame 19b, but is not necessarily limited to this structure.

In addition, a liquid carbon dioxide diffuser 12a is installed at the inlet side of the first pipe 12 of FIG. 2 . The liquid carbon dioxide diffuser 12a has a plurality of holes formed in its body, and the liquid carbon dioxide gas is supplied into the first pipe 12 of the reactor 10 through the plurality of holes. It is preferable that the plurality of holes have a small diameter and are formed in plurality to be advantageous in forming microbubbles. The liquefied carbon dioxide diffuser 12a may be understood as a gas injection pipe for supplying liquefied carbon dioxide gas into the reactor 10 .

Meanwhile, referring to FIG. 2 , there is shown an example in which a mixing member 60 for mixing liquefied carbon dioxide gas and alkaline wastewater is installed on the inlet 11 side of the first pipe 12 , which will be described later.

By such a reactor (10), the pH can be treated to be neutral by reacting the liquefied carbon dioxide with alkaline wastewater. While forming the shape, microbubbles are generated to shorten the dissolution time of the liquefied carbon dioxide gas.

In the present invention, the reactor 10 may be a reactor using a pipe, similar to the principle similar to that of a general reaction tank (Buffle Plate).

In addition, the number of collisions between the liquefied carbon dioxide gas and the alkaline wastewater in the reactor 10 increases, so that the microbubbles increase the contact area with water, so that the neutralization treatment can be effectively performed by the carbonated water completely dissolved in high concentration.

On the other hand, after neutralization treatment is performed on the alkaline wastewater in the reactor 10, the neutralized wastewater flows to the sedimentation facility 50 shown in FIG. 1 .

The liquefied carbon dioxide cylinder 20 is connected to the reactor 10, receives liquefied carbon dioxide gas, and supplies the liquefied carbon dioxide gas to the reactor 10 so as to dissolve the liquefied carbon dioxide gas in the alkaline wastewater. make it

The apparatus 100 for neutralizing liquefied carbon dioxide according to the present invention may further include a control unit 30 . The control unit 30 makes it possible to control the supply of the liquefied carbon dioxide gas based on the pH concentration inside the reactor 10 .

On the other hand, a gas supply pipe 20b may be installed between the liquefied carbon dioxide gas cylinder 20 and the reactor 10, and the liquefied carbon dioxide gas flows from the liquefied carbon dioxide cylinder 20 to the reactor ( 10) will flow. Gas supply valves 20b, 35b, and 33a that can be opened and closed may be installed in the gas supply pipe 20b.

The control unit 30 makes it possible to adjust the opening and closing of some of the valves 33a and 35b based on the pH concentration of the alkaline wastewater inside the reactor 10 .

The control unit 30 may include a pH control unit 33 and a pressure control unit 35 .

The pH controller 33 controls the opening and closing of the supply valve 33a based on the pH value inside the reactor 10 . For example, the pH control unit 33 receives the pH value inside the reactor 10 and is higher than the required pH value, opens the supply valve 33a installed in the gas supply pipe 20b, and is less than the required pH value. In this case, it is possible to close the supply valve (33a).

The pH control unit 33 receives the pH value inside the reactor 10 and opens the supply valve 33a when the pH value is higher than the required pH value, and closes the supply valve 33a when the pH value is less than the pH value. The supply valve 33a is installed in the gas supply pipe 20b and supplies or restricts liquefied carbon dioxide gas as it opens or closes. To this end, a pH measuring unit for measuring the pH inside the reactor 10 is installed in the reactor 10 , and the pH information measured by the pH measuring unit is provided to the pH controlling unit 33 .

The pressure control unit 35 may operate an alarm based on the pressure value inside the gas supply pipe 20b connected to the outlet of the liquefied carbon dioxide cylinder 20 . For example, when the pressure value inside the gas supply pipe 20b falls below the reference value, a low alarm may operate, and when the pressure value inside the gas supply pipe 20b falls below the maximum allowable value, a low low alarm may operate. When this alarm works, the manager manually replaces the used carbon dioxide cylinder.

A heater 40 for preventing freezing by heating the liquefied carbon dioxide gas may be installed between the liquefied carbon dioxide cylinder 20 and the reactor 10 . 1 shows an example in which the heater 40 is installed in the gas supply pipe 20b on the side of the liquefied carbon dioxide gas cylinder 20 . For example, the heater 40 may be a heater.

On the other hand, the introduced wastewater is described in relation to an example in which suspended matter removes sediment through chemical treatment.

When wastewater flows in, it is collected in a water collecting tank, and then wastewater is supplied to the coagulation tank. In the coagulation tank, the suspended matter (sludge) in the wastewater is aggregated with each other to facilitate sedimentation by treating with a chemical such as a coagulant or polymer. Thereafter, it flows into the sedimentation tank, in which the suspended solids that are largely agglomerated are settling by gravity. The precipitated suspended matter moves to a concentration tank where it is concentrated, and is pressurized by a filler press to remove moisture.

As described above, referring to FIG. 2 , the liquefied carbon dioxide neutralization device 100 of the present invention enables mixing of liquefied carbon dioxide gas and alkaline wastewater, and is installed on the inlet 11 side of the first pipe 12 The mixing member 60 may be further included. Hereinafter, a detailed configuration of the mixing member 60 will be described with reference to FIGS. 3A and 3B .

The mixing member 60 may be installed inside the first pipe 12 of the reactor 10 , and as shown in FIGS. 1 and 2 , the mixing member 60 is the inlet of the first pipe 12 ( 11) Can be installed on the side.

The mixing member 60 may include first and second members 61 and 62 . The mixing member 60 may have a structure in which the first and second members 61 and 62 are alternately disposed inside the first pipe 12 .

The first member 61 may be provided in plurality, and may include a flow path 61b through which a fluid passes to enable mixing of liquefied carbon dioxide gas and alkaline wastewater. The first member 61 may be twisted to have a curved surface portion 61a, for example. Also, the first member 61 may have a predetermined width. The flow path 61b of the first member 61 is preferably provided between the curved portions 61a.

Like the first member 61, the second member 62 may be provided in plurality, and may include a flow path 62b through which a fluid passes to enable mixing of liquefied carbon dioxide gas and alkaline wastewater. The second member 62 may have, for example, a twisted shape. Also, the second member 62 may have a predetermined width. The flow path 62b of the second member 62 is preferably provided between the curved portions 62a.

For example, the first and second members 61 and 62 may be disposed to be twisted in opposite directions in the first pipe 12 .

As shown in FIGS. 3A and 3B , the first member 61 and the second member 62 are preferably twisted in opposite directions to each other, whereby liquid carbon dioxide gas and alkaline wastewater flow in opposite directions to each other. Passing through (61b, 62b), the movement path is reversed and can be mixed, and the mixing performance can be further improved.

Meanwhile, an example in which the ends of the first and second members 61 and 62 are disposed to maintain a predetermined angle with each other is illustrated in FIG. 3A , but the structure is not necessarily limited thereto.

The mixing member 60 may further include a connection support 65 connecting the first and second members 61 and 62 and supporting each other. The connecting support 65 prevents the first and second members 61 and 62 from being shaken or separated from the inside of the first pipe 12 . 3a and 3b, a connection support 65 is installed inside the first pipe 12 so as to be parallel to the first pipe 12, and the first and second members 61 and 62 are connected to the support part 65 An example in which they are connected to each other is shown.

coupling of the first pipe 12 and the first and second members 61 and 62; coupling of the first and second members 61 and 62 and the connecting support; The coupling of the first pipe 12 and the connecting support portion may be made by, for example, welding, but is not necessarily limited thereto.

The number or formation angle of the first and second members 61 and 62 may be changed according to a flow rate or a flow rate. In the present invention, the mixing member 60 may be, for example, an in-line mixer.

The mixing member 60 of the present invention has no noise, vibration, or leakage during operation, and requires less maintenance/repair than a power-type mixer due to less occurrence of failure. In addition, it may be made of various materials.

4 is a conceptual diagram illustrating an example in which the reactor 10 of the present invention is installed in the precipitation facility 50 . With reference to FIG. 4 , the precipitation facility 50 in which the reactor 10 is installed will be described.

The settling facility 50 receives wastewater from the first pipe 12 and rotates it to precipitate and separate the flocs to discharge the clean water to the outside. For example, the settling facility 50 may be provided with an inlet pipe 16 having an inlet 16a.

The settling facility 50 may include a body portion 54 having a floc removal unit 55 formed at a lower portion thereof. The settling facility 50 removes the floc from the wastewater and at the same time supplies clean water from which the floc is removed to the body. (54) It is a configuration for discharging to the outside. In the present invention, the sedimentation facility 50 may be understood as a cyclone for precipitating and separating foreign substances from wastewater.

The body 54 may be formed of, for example, a cylindrical tank. A high-speed nozzle connected in a tangential direction to the outer peripheral surface of the body 54 may be connected to the upper outer circumferential surface of the body 54 , so that when wastewater enters the body 54 , the inside of the body 54 is to cause a vortex flow.

In addition, a funnel-shaped floe removal part 55 having a diameter gradually decreasing downward is formed in the lower portion of the body part 54, and the flocs that are precipitated by the swirling flow generated in the body part 54 are formed. These are collected, and then, when a certain amount of flocs are accumulated in the floe removal unit 55 , the accumulated flocs are discharged to the outside through the flock discharging unit. In addition, the floc removal unit 55 forms the bottom surface of the settling facility 50, so that wastewater flowing in from the outside is accommodated.

In addition, the sedimentation facility 50 may include a drain pipe part 51 and a sedimentation guide part 52 .

The drain pipe part 51 may be a hollow pipe upright in the vertical direction. A settling guide part 52 and a guide skirt 53 are fixedly supported on the outer peripheral surface of the drain pipe part 51 . On the outer periphery of the drain pipe part (51) between the settling guide parts (52), a flow hole for introducing wastewater into the drain pipe part (51) is formed.

The upper opening of the drain pipe 51 is connected to a drain communication pipe having an outlet for discharging clean water from which the flocs are separated from the wastewater by flowing into the inside of the drain pipe section 51 through a distribution hole, and the drain pipe section 51 ) is formed on the lower side of the sedimentation outlet hole (51a), and when the flocs to be sedimented are discharged downward through the sedimentation outlet hole (51a), they are accumulated in the floc removal unit 55 described above.

A plurality of funnel-shaped sedimentation guide parts 52 having a diameter gradually expanding downward are formed on the outer circumferential surface of the drain pipe part 51 vertically at regular intervals from each other. The settling guide part 52 guides the sedimentation of the flocs that cannot enter the drain pipe part 51 through the circulation hole so that they are accumulated in the floe removal part 55 . In addition, the sedimentation guide part 52 may have a structure in which the lower side is opened so that the wastewater fills up between the sedimentation guide parts 52 in the upward direction.

4 shows an example of the settling guide part 52 consisting of three pieces.

In addition, the settling facility 50 may further include a guide skirt 53 above the settling guide part 52 .

The guide skirt 53 is formed in a funnel shape whose upper part is formed parallel to the settling guide part 52 and gradually expands in diameter, and the lower part is made up of a sidewall 53a of the skirt having a tubular structure.

The skirt sidewall 53a has a tubular structure extending downward by a predetermined length from the lower end of the guide skirt 53. Accordingly, the guide skirt 53 including the skirt sidewall 53a is provided with a settling guide part on the lower side thereof. (52) will surround them.

The above-described liquefied carbon dioxide gas neutralization apparatus 100 is not limited to the configuration and method of the embodiments described above, but all or part of each embodiment is selectively combined so that various modifications can be made. may be

It is apparent to those skilled in the art that the present invention may be embodied in other specific forms without departing from the spirit and essential characteristics of the present invention. Accordingly, the above detailed description should not be construed as restrictive in all respects but as exemplary. The scope of the present invention should be determined by a reasonable interpretation of the appended claims, and all modifications within the equivalent scope of the present invention are included in the scope of the present invention.

100: liquid carbon dioxide gas neutralization device
10: Reactor 11: Inlet
12: first pipe 12b: waste water flow part
12a: Liquefied carbon dioxide diffuser
14: Second pipe
19a: base 19b: support frame
20: liquefied carbon dioxide cylinder 20a: valve
30: control unit 33: pH control unit
33a: supply valve 35: pressure control unit
35a: valve
40: warmer
50: sedimentation facility
51: drain pipe part 52: sedimentation guide part
54: body part 55: flock removal part
60: mixed member
61, 62: first and second members
61a, 62a: curved part
61b, 62b: Euro
65: connection support

Claims (7)

a reactor having an inlet through which the alkaline wastewater is introduced and having a wastewater flow part allowing the alkaline wastewater to flow;
a liquefied carbon dioxide cylinder connected to the reactor, receiving liquefied carbon dioxide, and supplying the liquefied carbon dioxide to the reactor to dissolve the liquefied carbon dioxide in the alkaline wastewater;
a control unit capable of controlling the supply of the liquefied carbon dioxide gas based on the pH concentration of the alkaline wastewater in the reactor; and
The reactor is installed and includes a precipitation facility for removing flocs from wastewater and discharging clean water from which flocs are removed,
The reactor is
a first pipe formed in plurality and having a liquefied carbon dioxide diffuser installed on one side to enable supply of the liquefied carbon dioxide gas to the inside; and
and a second pipe having a curved shape that is fixedly installed between each of the plurality of first pipes,
The control unit is
a pH controller configured to control opening and closing of the supply valve based on the pH value inside the reactor; and
And a pressure control unit for operating an alarm based on the pressure value inside the gas supply pipe connected to the outlet of the liquefied carbon dioxide cylinder,
Further comprising a mixing member installed on the inlet side of the first pipe to stir the liquefied carbon dioxide gas and alkaline wastewater to be mixed,
The mixing member is
a first member provided in plurality and having a shape twisted in one direction so as to have a curved surface;
a second member provided in plurality and having a shape twisted in the one direction and the other direction so as to have a curved surface portion; and
Connecting the first and second members and including a connection support for supporting each other,
The settling equipment is
a body portion having a nozzle connected to the outer circumferential surface in a tangential direction to generate a swirling flow of inflowing wastewater;
a floc removal unit provided at a lower side of the body, the diameter of which decreases downward, and enables discharging of the floc to the outside when a certain amount of floc is accumulated;
A drain pipe part that is a hollow pipe erected in the vertical direction; and
It is disposed on the outer circumferential surface of the drain pipe part, it has a funnel shape that gradually expands downward in diameter, and includes a sedimentation guide part for guiding the sedimentation of flocs to accumulate in the flocc removal part,
A gas supply pipe is installed between the liquefied carbon dioxide cylinder and the reactor to allow the liquefied carbon dioxide gas to flow from the liquefied carbon dioxide cylinder to the reactor,
The pressure control unit operates an alarm based on the pressure value inside the gas supply pipe connected to the outlet of the liquefied carbon dioxide cylinder, and when the pressure value inside the gas supply pipe falls below the reference value, a low alarm operates, Liquefied carbon dioxide neutralizer, characterized in that the low low (low low) alarm is activated when it goes below the maximum allowable value.
According to claim 1,
The first pipe is made of a straight pipe, and the liquefied carbon dioxide gas neutralization device, characterized in that the first pipe and the plurality of curved second pipe made of a plurality of straight pipes are arranged to be parallel to each other.
delete delete According to claim 1,
The pH control unit receives the pH value inside the reactor and, when the pH value is higher than the required pH value, opens the supply valve installed in the gas supply pipe, and closes the supply valve when the pH value is less than the required pH value Carbon dioxide neutralization device. delete delete

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