KR101324635B1 - Mixing apparatus - Google Patents

Abstract

PURPOSE: A mixing apparatus is provided to have the effect capable of quickly mixing input chemicals and rotating fluid by including a first fluid rotating means, a second fluid rotating means and an input part. CONSTITUTION: A mixing apparatus comprises a pipe (100) in which fluid flows through a fluid path formed inside; a mixing part (200) including a first fluid rotating means (210) which is protruded along the inner periphery inside the pipe, and rotates the fluid along the moving direction of the fluid, and a second fluid rotating means (220) which is positioned on the downstream of the first fluid rotating means along the moving path of the fluid, and rotates the rotating fluid to the reverse direction; and an input part (300) which is equipped on the pipe, and inputs chemicals into the pipe from the outside.

Description

Mixing Apparatus {Mixing Apparatus}

The present invention relates to a mixing device, and more particularly, to a mixing device that has a separate mixing unit in the pipe to rotate the fluid to quickly mix the drug and the fluid introduced into the mixing device.

In general, pipes are widely used for moving a fluid to a specific area, and recently, a separate mixing device is provided so that the pipe is mixed with additional chemicals or fluids instead of simply used to move the fluid. It is also used for purposes.

The mixing device is also widely used for disinfecting drugs for preventing the contamination of bacteria, such as chlorine in the water pipe, and is also widely used for dispensing drugs for the use of sea water in ships.

In particular, when supplying and using the seawater in the engine room or the vessel in the ship, since the seawater cannot be used as it is, separate chemicals are used to remove the salt or microorganisms in the seawater. In addition, the concentration of the drug during administration is adjusted to suit the use on the vessel.

Here, the length of the pipe for supplying sea water is limited because of the limitation of the space of the vessel. Therefore, it has been required to develop a method of quickly mixing the chemicals into the sea water moving through the pipe. In addition, whether or not the sea water and chemicals are quickly mixed with a method for measuring the concentration of the sea water and the injected chemicals provided with a separate concentration sensor downstream of the area where the chemicals are injected along the longitudinal direction of the pipe have

When chemicals added to seawater supplied to ships are not quickly mixed, problems have arisen due to the inflow of seawater, the devices using seawater are corroded or contaminated with salt.

Therefore, various devices have been developed to solve such a problem, and a similar device includes a conventional water-drug mixing device, which is disclosed in Korean Patent Publication No. 10-2007-0075085.

The present invention relates to a mixing device, comprising a separate mixing unit in the fluid flowing pipe to rotate the fluid by spraying the chemical in the center of the rotating fluid, by mixing the rotating fluid and the injected chemical can be quickly mixed In providing a device.

In order to solve the above problems, the mixing apparatus according to the present invention includes a pipe through which a fluid flows through a flow path formed therein, a first fluid which protrudes along an inner circumference of the pipe and rotates the fluid along a moving direction of the fluid. A mixing part including a rotating means and a second fluid rotating means positioned downstream of the first fluid rotating means along the movement path of the fluid and rotating the rotating fluid in the opposite direction, and provided to the pipe, It includes an input unit for injecting into the pipe.

In addition, the first fluid rotating means may be composed of at least two and may have a first blade protruding from the inner wall of the pipe so that the flowing fluid rotates in the circumferential direction along the cross section of the pipe.

In addition, the first blade may be formed twisted from the inner circumference of the pipe.

In addition, the second fluid rotating means may comprise at least two and may include a second blade formed by protruding from the inner wall of the pipe so that the flowing fluid rotates in the circumferential direction along the cross section of the pipe, The two blades may be twisted from the inner circumference of the pipe.

In addition, the injection portion is formed to reach the center portion from the side of the pipe in the cross-section and can inject the chemical to the fluid that is rotated by the first fluid rotation means.

In addition, the input portion may include a plurality of injection holes for injecting the drug to be spaced apart a predetermined interval along the longitudinal direction, the injection hole may be formed so as to increase the diameter from the inside of the input portion to the outside.

In addition, the input unit may be disposed between the first fluid rotation means and the second means along the longitudinal direction of the pipe.

The apparatus may further include a concentration measuring sensor disposed downstream of the second fluid rotating means along the longitudinal direction of the pipe through which the fluid flows to measure the concentration of the fluid mixed with the medicine.

The mixing device according to the present invention has the following effects.

A first fluid rotating means disposed on the pipe in which the fluid flows and having a first fluid rotating means for rotating the fluid flowing in the pipe and a second fluid rotating means for rotating the fluid in a direction opposite thereto; By providing an injection unit for injecting the chemical into the pipe between the second fluid rotating means there is an effect that can quickly mix the rotating fluid and the injected chemical.

In addition, the injection portion for injecting the drug has a predetermined length to reach the center from the side along the cross section of the pipe and has a plurality of injection holes spaced at regular intervals in the longitudinal direction by which the injected chemical is evenly injected into the fluid to be quickly mixed It can be effective.

1 is a view showing an arrangement of a mixing device according to an embodiment of the present invention;
Figure 2 is an exploded perspective view schematically showing the configuration of the mixing device of Figure 1;
3 is a cross-sectional view showing the configuration of the mixing unit in the mixing device of FIG.
4 is a view showing a state that is injected into the pipe in the mixing device of FIG. And
5 is a view showing the shape and arrangement of the injection port in the mixing device of FIG.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In describing the present embodiment, the same designations and the same reference numerals are used for the same components, and further description thereof will be omitted.

First, referring to FIG. 1 to FIG. 3, the configuration of a mixing apparatus according to an embodiment of the present invention will be described.

1 is a view showing the arrangement of the mixing device according to an embodiment of the present invention, Figure 2 is an exploded perspective view schematically showing the configuration of the mixing device of Figure 1 and Figure 3 shows the configuration of the mixing unit in the mixing device of Figure 1 It is a cross section.

The mixing device according to the present invention is a device for mixing the drug (A) and the fluid (W) in a quick time by putting the drug (A) in the flowing fluid (W) in the embodiment of the present invention largely pipe (100), The mixing unit 200 and the input unit 300 is configured to be included.

The pipe 100 has a flow path formed therein and is configured such that the fluid W flows through the flow path. In the present embodiment, the pipe 100 is configured to move to the target position (engine room, ballast tank, cold heating facility, etc.) flows through the flow path is introduced from the outside in the state provided in the vessel.

Here, the pipe 100 may be a pipe generally used for ships and may be made of a material that does not cause erosion or corrosion by seawater.

The mixing unit 200 is disposed in some section along the longitudinal direction of the pipe 100 so that the fluid W rotates inside the pipe 100 to form a vortex.

In the present embodiment, as shown in FIG. 2, the mixing part 200 includes the first fluid rotating means 210 and the second fluid rotating means 220, each of which is a direction in which the fluid W moves. Are placed along.

The first fluid rotating means 210 rotates the fluid W flowing in the pipe 100.

The first fluid rotating means 210 is formed of at least two and formed to protrude from the inner wall of the pipe 100 so that the flowing fluid (W) rotates in the circumferential direction along the cross section of the pipe (100) It comprises a first blade 212. Here, the first blade 212 is twisted in the longitudinal direction from the inside of the pipe 100 toward the center, and each of the first blades 212 are twisted in the same direction.

In this embodiment, the first blade 212 is composed of a plurality of spaced apart along the outer periphery of the pipe (100). Each of the first blades 212 are separately separated and twisted in the same direction, so that the fluid W passing through the first blades 212 rotates.

The second fluid rotating means 220 is formed similar to the first fluid rotating means 210 described above, and the first fluid on the path along which the fluid (W) moves along the longitudinal direction of the pipe (100). It is located downstream from the fluid rotating means 210.

The second fluid rotating means 220 is formed of at least two to protrude along the inner circumference of the pipe 100, although not shown in the figure is formed to be twisted at a predetermined angle from the inner circumference of the pipe 100 It is configured to include a second blade (222). The first blade 222 is connected to have an inclination in connection with the inner circumference of the pipe 100. Here, the second blade 222 has a configuration similar to the first blade 212, but is formed to be inclined and twisted in the opposite direction to the first blade 212 as shown in FIG.

Thus, when the fluid W rotated by the first fluid rotation means 210 passes through the second fluid rotation means 220, the rotation direction of the fluid W is reversed and rotates.

Meanwhile, since each of the first blade 212 and the second blade 222 does not protrude to the center of the pipe 100 along the cross section, the flow of the fluid W flowing along the pipe 100 is It is not disturbed. That is, the first fluid rotating means 210 and the second fluid rotating means 220 are a plurality of the first blade 212 and the second blade outside a predetermined distance based on the center of the pipe 100. 222 is formed to protrude to form. Therefore, the vortex may be formed as the fluid W moves without significantly inhibiting the flow of the fluid W flowing in the pipe 100.

The input unit 300 is connected to the outside is configured to be inserted into the pipe 100, a part of the input chemicals (A) supplied from the outside into the pipe (100).

Here, the inlet 300 is disposed to reach the center from the side along the cross section of the pipe 100 has a predetermined length to the fluid (W) rotated by the first fluid rotating means 210 Spray the medicine (A).

More specifically, the inlet 300 is located between the first fluid rotating means 210 and the second rotating means along the longitudinal direction of the pipe 100, as shown in FIG. It is configured to inject the drug (A) to the fluid (W) rotated by the first fluid rotating means (210).

In addition, the fluid W injected with the medicine A by the input part 300 is rotated in the opposite direction by the second fluid rotating means 220. In this way, the fluid (W) is quickly mixed with the chemicals (A) introduced by the rotation by each of the first fluid rotation means 210 and the second fluid rotation means 220.

As shown in FIG. 3, the mixing unit 200 and the input unit 300 may be divided into three regions A, B, and C on the pipe 100.

First, the region A located upstream along the movement path of the fluid W flowing in the pipe 100 passes through the plurality of first blades 212 in which the first fluid rotating means 210 is disposed. Rotate the fluid (W). In the region B, the injection unit 300 is disposed downstream of the region A, and the medicine A is supplied from the outside to the fluid W that is rotated and moved by the first fluid rotating means 210. do.

In the region C, the second fluid rotating means 220 is disposed to mix the chemicals A injected from the injection part 300 and the fluid W rotated by the first fluid rotating means 210. At the same time, the fluid W passes and rotates in a direction opposite to the direction in which the second blade 222 rotates.

On the other hand, the mixing device according to an embodiment of the present invention may be configured to further include a concentration measuring sensor 400 as shown in FIG.

The concentration sensor 400 is provided downstream of the mixing unit 200 on the pipe 100 and the fluid W is mixed with the chemicals A injected from the input unit 300. Measure the concentration at

Thus, by providing the concentration sensor 400, it is possible to determine whether the fluid (W) mixed with the medicine (A) is suitable to move to the target position (engine chamber, ballast tank, cold heater, etc.). .

Here, the quicker the mixing of the fluid (W) and the drug (A) by the mixing unit 200 is shorter the separation distance between the concentration sensor 400 and the mixing unit 200 on the pipe 100 Can lose.

Separately, in the mixing apparatus according to the embodiment of the present invention, the mixing unit 200 and the input unit 300 may be configured in plural numbers. As shown in FIG. 1, the mixing portion (W) on the pipe 100 is downstream of the concentration sensor 400 along the direction in which the fluid W flows on the pipe 100. 200 and the input unit 300 may be further provided, and thus the mixing unit 200 and the input unit 300 are configured in plural, and thus, the medicine A injected into the fluid W. The concentration of can be adjusted more accurately.

The fluid flowing in the pipe 100 through the measurement by the concentration measuring sensor 400 is arranged by the plurality of mixing part 200 and the input part 300 is arranged on the pipe 100 ( The concentration of the drug (A) mixed in W) can be adjusted.

Next, referring to FIG. 4, the state in which the drug A is injected into the pipe 100 through the input unit 300 is as follows.

4 is a view showing a state that is injected into the pipe 100 in the mixing device of FIG.

As shown in FIG. 4, the input part 300 has a predetermined length and is formed to reach the center portion from the side portion along the cross section of the pipe 100. Thus, the injection part 300 is provided with a plurality of injection holes 310 for injecting the drug (A) spaced apart at regular intervals along the longitudinal direction of the region inserted into the pipe (100).

As shown in FIG. 4, the injection hole 310 injects the medicine A to the fluid W that is rotated by the first fluid rotating means 210 through the inlet 300. Here, as shown, the fluid (W) is rotated in a clockwise direction about the center of the cross section of the pipe 100 by the first fluid rotating means (210).

In this case, the injection unit 300 is disposed so as to reach the center from the side of the pipe 100 is the drug (A) in the direction opposite to the direction in which the fluid (W) is rotated by the first fluid rotating means 210 Spray).

In this way, the drug (A) is injected in the opposite direction in which the fluid (W) flows to allow the fluid (W) and the drug (A) to be mixed more quickly. After the drug (A) is injected, the fluid (W) rotates and moves along the pipe (100) along the pipe (100) to the C region by the second fluid rotating means 220 Rotate in the direction.

That is, the fluid W rotates clockwise by the first fluid rotation means 210 in the area A and moves to the area B, and the fluid W in the area B is caused by the inlet 300. It is mixed with the drug (A) is injected to move to the C region. Although not shown in the figure, the fluid W rotates in the counterclockwise direction along with the chemical agent A by the second fluid rotating means 220.

As such, the fluid W rotates in the clockwise and counterclockwise directions by the first fluid rotating means 210 and the second fluid rotating means 220, and the inlet part 300 rotates. The drug (A) is injected into the fluid (W) to rotate with the fluid (W) and mix quickly.

On the other hand, in the present embodiment, the input unit 300 is configured to be located in the region B, but is not particularly limited to this type. Although not shown in the drawing, even if the input part 300 is located in the A area instead of the B area and the first fluid rotating means 210 is located in the B area, there is no deviation from the meaning of the present invention.

Next, referring to Figure 5 looks at the configuration and shape of the input unit 300 as follows.

5 is a view showing the shape and arrangement of the injection port 310 in the mixing device of FIG.

As shown in FIG. 5, the injection part 300 has a predetermined length to be centered on the side of the pipe 100, and the plurality of injection holes 310 spaced apart at regular intervals along the longitudinal direction. ) Is provided.

Here, the injection hole 310 is formed in the opposite direction in which the fluid (W) is rotated by the first fluid rotating means 210 to inject the drug (A) and the injection hole 310 is the injection The diameter of the cross section is formed to increase in the direction in which the pipe 300 is injected into the inside of the part 300.

That is, as shown, the injection hole 310 is in the shape of a trumpet and is formed such that the portion injected into the pipe 100 becomes wider. Therefore, it is configured to be evenly mixed with the fluid (W) while spreading wide at the moment when the drug (A) injected through the injection port 310 is injected.

On the other hand, the injection hole 310 is upstream in the longitudinal direction of the pipe 100, as well as the opposite direction in which the fluid (W) is rotated by the first fluid rotating means 210 on the inlet (300). And it may be further provided to spray the drug (A) in the downstream direction.

The injection hole 310 is composed of a plurality of spaced apart at a predetermined interval is also provided in the upstream and downstream direction of the pipe 100, thereby injecting a larger amount of the drug (A) through the inlet 300 can do.

It will be apparent to those skilled in the art that the present invention may be embodied in other specific forms without departing from the spirit or scope of the invention as defined in the appended claims. . Therefore, the above-described embodiments are to be considered as illustrative rather than restrictive, and the invention is not limited to the above description, but may be modified within the scope of the appended claims and equivalents thereof.

100: pipe 200: mixing part
210: first fluid mixing means 220: second fluid mixing means
300: injection unit 310: injection hole
400: concentration sensor W: fluid
A: Drug

Claims (8)

A pipe through which fluid flows through a flow path formed therein;
A first fluid rotating means which protrudes along an inner circumference of the pipe and rotates the fluid along a moving direction of the fluid, and a fluid that is located downstream of the first fluid rotating means along a movement path of the fluid A mixing part including a second fluid rotating means rotating in an opposite direction; And
An injection unit provided in the pipe and injecting chemicals from the outside into the pipe; Mixing apparatus comprising a. The method of claim 1,
The first fluid rotation means,
And a first blade composed of at least two and protruding from the inner wall of the pipe such that the flowing fluid rotates in the circumferential direction along the cross section of the pipe. 3. The method of claim 2,
And the first blade is twisted from the inner circumference of the pipe. The method of claim 1,
The second fluid rotation means,
Comprising at least two and comprises a second blade protruding from the inner wall of the pipe so that the flowing fluid rotates in the circumferential direction along the cross section of the pipe,
And the second blade is twisted from the inner circumference of the pipe. The method of claim 1,
Wherein,
Mixing apparatus is formed so as to cross-section from the side of the pipe to the central portion and injects the chemical to the fluid that is rotated by the first fluid rotation means. 6. The method of claim 5,
The injection unit includes a plurality of injection holes for injecting the medicine spaced apart at regular intervals along the longitudinal direction,
The injection port is a mixing device is formed so that the diameter is increased from the inside to the outside. The method of claim 1,
The mixing unit is disposed between the first fluid rotation means and the second means along the longitudinal direction of the pipe. The method of claim 1,
And a concentration measuring sensor disposed downstream of the second fluid rotating means along the longitudinal direction of the pipe through which the fluid flows to measure the concentration of the fluid mixed with the medicine.

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