KR102394064B1 - mixer for multi-fluid mixing with no internal blockage - Google Patents

Abstract

The present invention relates to a mixer for mixing multiple fluids without internal clogging, the purpose of which is to uniformly mix two or more fluids through centrifugal force generated while rotating along a screw disk and vortex generation by a blocker, and foreign substances contained in the fluid An object of the present invention is to provide a mixer for multi-fluid mixing without internal clogging, which is configured to mix stably and quickly without any jamming.
The configuration of the present invention includes a cylindrical case 11 for accommodating a fluid; a central tube 12 installed in the horizontal direction inside the cylindrical case; a screw 13 continuously formed along the circumference of the central tube to stir the two or more fluids introduced therein by centrifugal force; a blocker 14 installed on the inner wall of the case between the pitches of the screws to collide with the two or more fluids introduced thereinto and mix; a curved inlet pipe 15 positioned so that the inlet of one end is connected to the fluid supply pipe 30 in the inside of the central pipe and the outlet of the other end protrudes into the center pipe and the inner space of the case through the central pipe; One end of the inlet protrudes into the center tube and the inner space of the case, and the other end of the outlet passes through the center tube and is connected to the fluid transfer tube 501 from the inside of the center tube. For this reason, it has the advantage of high space utilization because the overall size of the device is not large while adjusting the degree of fluid mixing by installing a screw whose pitch is increased or decreased according to the type of fluid to be mixed.

Description

Mixer for multi-fluid mixing with no internal blockage

The present invention relates to a mixer for mixing multiple fluids without internal clogging, and more particularly, uniformly through centrifugal force generated while two or more fluids are introduced under the pressure of a pump and then rotate along a screw disk and vortex generation by a blocker It relates to a mixer that mixes well.

In general, mixers having various types are used in industrial sites. For example, various types of mixers are used depending on the fluid to be mixed, such as a form in which a container rotates, a form in which agitating blades rotate, a form of circulating or spraying a liquid by a pump, a form of stirring using air, and the like.

These mixers usually have a role of uniformly mixing two or more fluids and supplying them to the device of the next process.

However, conventional mixers do not care when a uniform fluid is supplied, but when a fluid containing foreign substances in the fluid is supplied, the mixing performance falls sharply and the mixing quality is poor for supply to the next process.

For example, in the case of a fluid containing foreign substances such as sludge, food, or compost, there are many problems such as foreign substances getting caught in the rotating stirring blades, etc. and a rotational load is applied. There is a problem that high-purity, high-quality production cannot be achieved even in the following process equipment, for example, a centrifuge, a chemical reaction device, and the like.

On the other hand, there are cases such as line mixers or static mixers in a form in which the stirring blades do not rotate. However, these mixers also have structural characteristics of individual blades. There are structural disadvantages and disadvantages in which a space of a certain size or more is necessarily required.

Accordingly, there is a need for a mixer capable of uniformly mixing two or more fluids containing foreign substances or fluids having different properties.

Korea Patent Publication No. 10-1063743 (2011.09.02.) Korea Patent Publication No. 10-1432185 (2014.08.13.) Korea Patent Laid-Open Publication No. 10-2013-0118456 (2013.10.30.) Korean Utility Model Gazette Registration No. 20-0439085 (2008.03.13.)

It is an object of the present invention to solve the above problems through centrifugal force generated while rotating two or more fluids supplied with the pressure of a pump or two or more fluids containing foreign substances along a screw disk and vortex generation by a blocker It is to provide a mixer for mixing multiple fluids without internal clogging, which is configured to mix quickly and stably without jamming of foreign substances contained in the fluid.

Another object of the present invention is to adjust the mixing degree by installing a screw having an appropriate pitch according to the type of fluid to be mixed inside, and the internal clogging configured to have high installation space utilization due to the small change in the size of the cylindrical case according to the screw with increased or decreased pitch To provide a mixer for multi-fluid mixing without

In the mixer for mixing two or more fluids containing two or more fluids or foreign substances, the present invention, which achieves the object as described above and performs a task for eliminating the drawbacks of the prior art,

a cylindrical case accommodating two or more fluids introduced by the pump pressure;

a central tube installed in a horizontal direction inside the cylindrical case;

a screw which is continuously formed along the circumference of the central tube and stirs two or more fluids introduced therein by centrifugal force;

a blocker installed on the inner wall of the case between the pitches of the screws to collide with the two or more fluids introduced thereinto and mix;

a curvature-type inlet pipe positioned so that an inlet at one end is connected to the fluid supply pipe inside the central pipe and the outlet at the other end protrudes into the central pipe and the case interior space through the central pipe;

One end of the inlet protrudes into the center tube and the case inner space, and the other end of the outlet passes through the center tube and is a curved discharge tube connected to the fluid transfer tube inside the center tube; This is achieved by providing a mixer for mixing multiple fluids.

In a preferred embodiment, the fluid supply pipe for supplying a fluid to the multi-fluid mixing mixer includes: a main fluid supply pipe for supplying a first fluid to a curved inlet pipe; It may consist of one or more other fluid supply pipes communicating with one or more points of the main fluid supply pipe.

In a preferred embodiment, the fluid supply pipe for supplying a fluid to the multi-fluid mixing mixer includes: a main fluid supply pipe for supplying a first fluid to a curved inlet pipe; It may be composed of one or more other fluid supply pipes that communicate with the disk-shaped cover member formed at the front end of the cylindrical case and directly supply the fluid therein.

In a preferred embodiment, the blocker protrudes from the inner wall surface of the case toward the central tube to have a 'V' cross section or a 'U' cross section to cause a collision at the front and a vortex at the rear to cause multiple mixing action. can be

In a preferred embodiment, the blocker may be configured in two or more per pitch of the screw.

In a preferred embodiment, the blocker may be configured by arranging a plurality of embossed shapes protruding toward the central tube on the inner wall surface of the case, or plate-like or polygonal protrusion shapes protruding at an arbitrary inclination angle.

In a preferred embodiment, it may be configured to further include an auxiliary obstruction formed in the longitudinal direction between the screw pitches around the center tube.

In a preferred embodiment, the auxiliary blocker is formed to protrude in the outer diameter direction to have an 'inverted V'-shaped cross-section or an 'inverted U'-shaped cross-section welded to the circumferential surface of the central pipe, causing a collision at the front and generating a vortex at the rear. It is configured so that multiple mixing action occurs, and may be configured with two or more per pitch of the screw.

In a preferred embodiment, the screw is formed in any one of pitches or more depending on the type of fluid to be mixed with screw blades having a continuous shape along the circumference of the central tube, and the outer diameter of the screw blade is configured to face the inner diameter of the cylindrical case can be

The mixer for multi-fluid mixing according to the present invention having the above characteristics is centrifugal force and obstruction generated while rotating along the screw disk while supplying two or more fluids containing foreign substances or two or more fluids containing foreign substances with the pressure of the pump. By uniformly mixing through flow control and vortex generation, which is generated by the

In addition, the mixer for multi-fluid mixing according to the present invention has the advantage that the mixing efficiency is increased by the vortex generated in the wake because the shape of the rear end of the blocker has an inclined structure in the two or more fluids introduced therein.

In addition, the mixer for multi-fluid mixing according to the present invention has the advantage that the mixing efficiency can be adjusted according to the adjustment of the pitch of the screw installed therein.

In addition, the mixer for multi-fluid mixing according to the present invention has the advantage of being able to adjust the degree of mixing by selecting a pitch that is optimally increased or decreased according to the type of fluid to be mixed and installed therein.

In addition, the mixer for multi-fluid mixing according to the present invention has the advantage of high installation space utilization because the size of the cylindrical case according to the increase or decrease of the pitch is small while adjusting the mixing degree by installing a screw having an appropriate pitch therein.

In addition, the mixer for multi-fluid mixing according to the present invention has the advantage that the mixing and vortex generation efficiency can be increased by installing the blocker not only on the outer wall having a cylindrical structure but also on the central part.

In addition, the multi-fluid mixing mixer according to the present invention is applied to various process devices installed at the rear stage, for example, a centrifugal dehydrator, a centrifugal concentrator, a three-phase separator, or other process devices. has the advantage of being able to

The present invention is a useful invention having various advantages as described above, and is an invention widely expected to be used in industry.

1 is a perspective view showing a mixer for mixing multiple fluids according to an embodiment of the present invention;
2 is an exploded perspective view showing the internal configuration of a mixer for mixing multiple fluids according to an embodiment of the present invention;
3 is a side view illustrating the inside of a mixer for mixing multiple fluids according to an embodiment of the present invention;
4 is an exemplary view showing a mixed flow structure of a fluid introduced into a multi-fluid mixing mixer according to an embodiment of the present invention;
5 is a cross-sectional view taken along line AA of FIG. 4 .
6 is an exemplary view illustrating a mixed flow structure when multiple fluids are supplied through multiple flow paths to a multi-fluid mixing mixer according to another embodiment of the present invention.

Hereinafter, the configuration and operation of an embodiment of the present invention will be described in detail in connection with the accompanying drawings. Also, in describing the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted.

1 is a perspective view showing a mixer for mixing multiple fluids according to an embodiment of the present invention, FIG. 2 is an exploded perspective view showing the internal configuration of a mixer for mixing multiple fluids according to an embodiment of the present invention, and FIG. 3 is this view It is an exemplary side view showing the inside of the multi-fluid mixing mixer according to an embodiment of the present invention, and FIG. 4 is an exemplary view showing the mixed flow structure of the fluid introduced into the multi-fluid mixing mixer according to an embodiment of the present invention. , FIG. 5 is a cross-sectional view taken along line A-A of FIG. 4 .

The mixer for multi-fluid mixing according to the present invention shown is a centrifugal force generated while rotating two or more fluids supplied with the pressure of a pump or two or more fluids containing foreign substances along a screw disk and flow control and vortex generation by a blocker. It is a mixer that is configured to mix uniformly through the passage and to mix stably and quickly without getting caught by foreign substances contained in the fluid. Consists of an inlet pipe 15 and a curved discharge pipe 16 .

The configuration as described above is that one end of the multi-fluid mixing mixer is connected to the fluid supply pipe 30 to receive two or more fluids, and the uniformly mixed fluid is used in connection with the rear end process device connected to the other end. It is common. If the process device is not connected to the rear end of the multi-fluid mixing mixer, it may be stored in a storage tank (not shown).

The fluid supply pipe 30 has a configuration in which the first fluid, the second fluid, the third fluid, and the n-th fluid are supplied by the pressure of a pump (not shown) that supplies the fluid. (1) is supplied and mixed, and the supply method can be configured in various ways.

For example, two or more fluids may be introduced in a mixed state to be uniformly mixed in the mixer for multi-fluid mixing of the present invention, or configured to be mixed after each flows into the mixer for multi-fluid mixing in an unmixed state. there is.

The cylindrical case 11 has a structure in which both ends are welded and blocked with a disk-shaped cover member 11b having an opening 11a formed therein, so that two or more fluids mixed therein supplied by the pressure of a pump (not shown) are accommodated. do.

At this time, one or a plurality of openings 11a on the side through which the fluid flows may be configured according to the flow method of the fluid.

A curved inlet pipe 15 protrudes through the opening on one side of the cylindrical case and is inserted and coupled to one side of the fluid supply pipe 30 , and the curved discharge pipe 16 faces the fluid transport pipe 501 at the other side.

In this case, the curved inlet pipe 15 may have a different configuration of the fluid supply pipe 30 according to a method of supplying the inflowing fluid.

That is, when configured so that all fluids are supplied to the curved inlet pipe 15, the main fluid supply pipe to which the mixed fluid is supplied is connected to the curved inlet pipe 15, and a plurality of It may be configured to supply in a way that forms another fluid supply pipe,

In another way, for example, when all the fluids are configured to directly flow into the cylindrical case, the main fluid supply pipe is connected so that one fluid is supplied to the curved inlet pipe 15, and other fluids or fluids are separate other fluid supply pipes. It can be configured to be supplied in direct communication with the cylindrical case.

The central pipe 12 is located in the inner center of the cylindrical case 11 and is installed horizontally, ie, in the longitudinal direction, on the same axis as the fluid supply pipe. The central tube 12 is welded and fixed in accordance with the openings formed at both ends of the cylindrical case.

The inner diameter of the central tube is formed to be larger than the diameter of the opening. By being configured in this way, a step does not occur when the fluid is supplied or discharged through the openings of both cases in a state in which the curved inlet pipe 15 and the curved discharge pipe 16 are inserted on both sides of the central pipe, respectively.

The screw 13 is formed with screw blades (or screw disks) having a continuous shape along the circumference of the central tube. For this purpose, the inner diameter (inside) of the screw blade is interviewed along the circumference of the central pipe and fixed by welding. As such, a screw having a continuous screw blade (or screw disk) is configured such that two or more fluids supplied through the fluid supply pipe 30 are rotated in a non-powered manner along the rotational direction of the screw by the supply pressure of a not shown pump. After mixing and stirring, it is discharged from the end.

The outer diameter (outer side) of the screw blade is configured to face the inner diameter of the cylindrical case. If there is a gap, the introduced fluid can pass directly to the next screw.

In some cases, it is possible to fix the case inner wall by welding the inlet and the end of the screw face-to-face with the case inner wall. By welding in this way, it is possible to fix the outer diameter of the screw, which can be shaken due to the centrifugal force of the fluid flowing along the screw surface, so that it is possible to respond to a larger pump pressure.

The pitch of the screw is configured to have a plurality of pitches of at least one pitch or more. If the pitch is not 1, it is because the mixing effect between two or more fluids is insufficient because it does not provide the time and area for sufficient stirring by centrifugal force.

Therefore, if a pitch of 1 pitch or more is provided, mixing efficiency can be increased by increasing the mixing time and mixing area between two or more fluids. That is, the mixing degree can be adjusted by installing a screw having an appropriate pitch according to the type of fluid to be mixed.

In addition, increasing the screw pitch increases the space efficiency of the multi-fluid mixing mixer. In other words, the size of the cylindrical case according to the increase or decrease of the pitch of the screw is small, so the installation space utilization can be high.

The baffle (14) is installed on the inner wall of the case between the pitches of the screws and is configured to collide with the two or more fluids introduced thereinto, thereby causing a mixing action. In some cases, the blocker may be installed by welding between opposite screws rather than the inner wall of the case.

In one embodiment, the blocker may be formed to protrude from the inner wall to the central tube across the screws facing each other. Such a configuration delays the flow of the two or more fluids rotating while having centrifugal force, thereby generating a relative velocity difference with the two or more fluids passing thereunder. This flow velocity mismatch provides an action of introducing the outer fluid of the two or more flowing fluids toward the inner fluid and mixing the two or more fluids.

The blocker according to the embodiment may be configured to protrude from the inner wall surface of the case toward the central tube to have a 'V'-shaped cross-section or a 'U'-shaped cross-section. It is preferable that the protruding size does not exceed 1/2 of the shortest distance between the inner wall of the case and the circumference of the central tube so as not to significantly impede the flow rate of the main flow for two or more fluids being rotated and supplied along the screw while receiving centrifugal force.

When configured with such a cross-section, it provides a relatively weak shock rather than a sudden shock to two or more fluids rotating at high speed and collides, causing the fluid to split through the inclined surface to disrupt the rotational flow and create a flow velocity difference to produce a primary mixing action. will do

In addition, in the region near the slope of the rear surface, the flow is rapidly reduced and a vortex is generated due to the difference in flow velocity with the surroundings, resulting in a secondary mixing action between two or more fluids. When mixed in this way, a more uniform mixing action occurs.

As shown in FIG. 5 , the vortex moves from a wide space to a narrow space based on the cross-sectional area formed by the cylindrical case and the blocker, and the flow speed increases and the vortex occurs as it goes back to the wide space.

Although only one blocker may be formed per pitch of the screw, it is preferable to configure two or more blockers per pitch of the screw to further increase the mixing efficiency.

On the other hand, the blocker shape may be configured by arranging a plurality of embossed shapes protruding from the inner wall surface of the case toward the central tube or plate-like or polygonal protrusion shapes protruding at an arbitrary inclination angle in addition to the structure and installation location as described above.

The blocker having the plate-like or polygonal protrusion shape should be formed at an arbitrary inclination angle bent from the front to the rear in reference to the flow of the fluid so that foreign substances contained in the fluid are not caught.

The curved inlet pipe 15 is positioned so that an inlet at one end is connected to the fluid supply pipe 30 inside the central pipe, and an outlet at the other end passes through the central pipe to protrude into the central pipe and the inner space of the case.

In addition, the curved discharge pipe 16 has an inlet at one end protruding into the center pipe and the inner space of the case, and an outlet at the other end passes through the center pipe to face the fluid transfer pipe 501 inside the center pipe on the same axis. do.

The shape of the outlet direction of the curved inlet pipe is bent so that two or more fluids are discharged in the moving direction of the screw, and a part in the corresponding direction is cut off. It is bent so as to flow in from the moving direction, and is installed in a shape in which a part of the corresponding direction is cut.

Due to this, the curved inlet pipe and the curved outlet pipe have openings formed in different directions inside the case.

In addition, in the curved inlet pipe 15 and the curved outlet pipe 16, the portion protruding outward of the central pipe is in contact with the screw surface in both directions, respectively, and the protruding end surface is in contact with or almost close to the inner diameter surface of the case. It is processed so that two or more fluids being supplied do not flow into the space opposite to the outlet of the curved inlet pipe 15 and the opposite to the inlet of the curved outlet pipe 16 .

In addition, the center pipe 12 is configured to further include an auxiliary obstruction 17 installed in the longitudinal direction between the pitch of the screw.

The auxiliary obstruction is formed to protrude in the outer diameter direction to have a 'inverted V'-shaped cross-section or an 'inverted U'-shaped cross-section welded to the circumferential surface of the central pipe, and collides with two or more fluids at the front to interfere with the rotational flow and mix, It can be formed to generate a vortex at the rear side.

When configured in this way, the flow rate difference is generated while interfering with the rotational flow at the front, and two or more fluids are mixed firstly, and at the rear side, a vortex caused by the lowering of the flow rate is generated, resulting in a second mixing action between two or more fluids, resulting in a more uniform multi-layer will cause mixing.

Although only one auxiliary blocker may be formed per pitch of the screw, it is preferable to configure two or more auxiliary obstructions per pitch of the screw to further increase the mixing efficiency.

6 is an exemplary view illustrating a mixed flow structure when multiple fluids are supplied through multiple flow paths to a multi-fluid mixing mixer according to another embodiment of the present invention.

As shown, it can be seen that the configuration of the fluid supply pipe 30 is composed of one main fluid supply pipe 31 and two other fluid supply pipes 32 . At this time, the number of the other fluid supply pipes 32 is illustrated as two as an example, but the present invention is not limited thereto, and one or more may be configured.

To this end, looking at the configuration of the disk-shaped cover member 11b having the opening 11a formed at the front end of the cylindrical case 11, a plurality of openings 11a are formed and the main fluid supply pipe 31 is provided as the opening 11a in the center. It can be seen that this is connected and configured to supply the fluid to the curved inlet pipe 15, and the other fluid supply pipe 32 is connected to the other opening 11a to directly supply the fluid to the inner space of the cylindrical case 11. there is.

By configuring such a structure, the length of the fluid supply pipe 30 for supplying the fluid can be shortened, so that the space occupied by the entire configuration including the multi-fluid mixing mixer can be efficiently used and the fluid can be freely supplied.

If the configuration is as described above, only the inflow structure of the fluid is different, and the internal configuration or action of the remaining multi-fluid mixing mixer is the same, and thus the above-described contents are omitted.

The present invention is not limited to the specific preferred embodiments described above, and various modifications are possible by anyone with ordinary skill in the art to which the invention pertains without departing from the gist of the invention as claimed in the claims. Of course, such modifications are intended to be within the scope of the claims.

(11): cylindrical case 11a; opening
(11b): cover member (12): central tube
(13): screw (14): jammer
(15): curved inlet pipe (16): curved outlet pipe
(17): auxiliary obstruction (30): fluid supply pipe
(31): main fluid supply pipe (32): other fluid supply pipe
(501): fluid transfer pipe

Claims (9)

In a mixer for mixing two or more fluids or two or more fluids containing foreign substances,
a cylindrical case 11 for accommodating two or more fluids introduced by the pump pressure; a central tube 12 installed in the horizontal direction inside the cylindrical case; a screw 13 continuously formed along the circumference of the central tube to stir the two or more fluids introduced therein by centrifugal force; a blocker 14 installed on the inner wall of the case between the pitches of the screws to collide with the two or more fluids introduced thereinto and mix; a curved inlet pipe 15 positioned so that the inlet of one end is connected to the fluid supply pipe 30 in the inside of the central pipe and the outlet of the other end protrudes into the center pipe and the inner space of the case through the central pipe; One end of the inlet protrudes into the inner space of the central tube and the case, and the other end of the outlet passes through the central tube and is connected to the fluid transfer tube 501 from the inside of the central tube.
The screw 13 is formed in any one of pitch or more according to the type of fluid to be mixed with screw blades of a continuous shape along the circumference of the central tube, and the outer diameter of the screw blade is configured to face the inner diameter of the cylindrical case, It is configured to be fixed by welding the beginning and the end of the screw that has been interviewed with the inner wall of the cylindrical case,
The central tube 12 is fixed by welding in accordance with the openings formed at both ends of the cylindrical case, and the inner diameter of the central tube is larger than the diameter of the opening,
The shape of the outlet direction of the curved inlet pipe 15 is bent so that the fluid is discharged in the moving direction of the screw and is installed in a shape in which a part in the corresponding direction is cut, and the shape of the inlet direction of the curved outlet pipe 16 is that the fluid is It is bent so that it flows in from the direction of the screw and is installed in a cut-out shape with a part in that direction, but the protruding part of the center tube in both directions is in contact with the screw face, and the protruding end face is the inner diameter face of the case Mixer for multi-fluid mixing without internal blockage, characterized in that the fluid being supplied does not flow into the space opposite to the outlet of the curved inlet pipe 15 and the opposite to the inlet of the curved outlet pipe 16 by processing in contact or close proximity .
The method according to claim 1,
The fluid supply pipe 30 for supplying a fluid to the multi-fluid mixing mixer includes: a main fluid supply pipe 31 for supplying a first fluid to the curved inlet pipe 15; A mixer for multi-fluid mixing without internal blockage, characterized in that it consists of one or more other fluid supply pipes (32) communicating with at least one point of the main fluid supply pipe (31).
The method according to claim 1,
The fluid supply pipe 30 for supplying a fluid to the multi-fluid mixing mixer includes: a main fluid supply pipe 31 for supplying a first fluid to the curved inlet pipe 15; A mixer for mixing multiple fluids without internal blockage, characterized in that it is composed of one or more other fluid supply pipes (32) that communicate with the disk-shaped cover member (11b) formed at the front end of the cylindrical case (11) and directly supply the fluid therein.
The method according to claim 1,
The blocker protrudes from the inner wall surface of the case toward the central tube to have a 'V'-shaped cross-section or a 'U'-shaped cross-section to cause a collision at the front and a vortex at the rear to generate multiple mixing actions. Clog-free mixer for multi-fluid mixing.
The method according to claim 1,
The mixer for multi-fluid mixing without internal clogging, characterized in that the blocker is configured at least two per pitch of the screw.
The method according to claim 1,
The blocker is a multi-fluid mixing mixer without internal clogging, characterized in that it is configured by arranging a plurality of embossed shapes protruding from the inner wall surface of the case toward the central tube or plate-like or polygonal protrusion shapes protruding at an arbitrary inclination angle.
The method according to claim 1,
A mixer for multi-fluid mixing without internal blockage, characterized in that it further comprises an auxiliary obstruction (17) formed in the longitudinal direction between the screw pitches around the central pipe.
8. The method of claim 7,
The auxiliary obstruction is formed to protrude in the outer diameter direction to have a 'inverted V'-shaped cross section or an 'inverted U'-shaped cross-section welded to the circumferential surface of the central pipe, causing a collision at the front and a vortex at the rear, resulting in multiple mixing action. A mixer for multi-fluid mixing without internal clogging, characterized in that it is configured to do so, and configured at least two per screw per pitch.
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