KR102204424B1 - Foam removing pan of vacuum evaporation concentrator - Google Patents

Abstract

The present invention relates to a fan for removing bubbles of a vacuum evaporative concentrator, which produces a horizontal wing in a hollow tubular shape to prevent bending, reduces rotational resistance by forming a resistance reduction hole to reduce the resistance on front and back sides of the horizontal wing, and removes bubbles while trapping the bubbles with a plurality of vertical wings by installing the plurality of vertical wings on the horizontal wing.

Description

Foam removal fan of vacuum evaporation concentrator {FOAM REMOVING PAN OF VACUUM EVAPORATION CONCENTRATOR}

The present invention relates to a fan for removing bubbles of a vacuum evaporation concentrator, in detail, by manufacturing a horizontal blade in a hollow tubular shape to prevent bending, and forming a resistance reducing hole to reduce resistance at the front and rear surfaces of the rotating pipe. The present invention relates to a defoaming fan for a vacuum evaporation concentrator to reduce rotational resistance and remove bubbles while confining bubbles by installing horizontal and vertical blades on a rotating pipe.

In general, evaporative concentrators apply heat to highly concentrated wastewater generated from livestock manure, domestic sewage, industrial wastewater, etc., and condensate the vapor generated therefrom to recover and reuse or discharge distilled water having a certain level of water quality. As it has low operating cost, high treatment efficiency and environmental safety, it is used in various fields such as livestock manure treatment, household sewage treatment, industrial wastewater treatment and resource recycling, as well as electroplating, pharmaceutical, food, textile, dyeing industries, etc. It is used in various ways.

These evaporation and concentrators are classified in various ways according to operating conditions, evaporation methods, and energy reuse methods. For example, depending on the operating conditions, evaporation is performed at atmospheric pressure and vapor is discharged to the atmosphere; There is a vacuum method, and depending on the evaporation method, a horizontal tube impact flow type in which evaporation and condensation are simultaneously performed on the heat transfer surface configured inside the evaporator, and a heat exchanger and evaporator are separately configured and evaporation while lowering the boiling point by decompressing at high temperature and high pressure. ) To separate the water contained in the raw water and discharge the raw water in high concentration.

As an example, a vacuum evaporation concentrator will be described as follows, and FIG. 1 is a view showing the configuration of a conventional vacuum evaporation concentrator.

The vacuum evaporation concentrator 1 includes an evaporator 10, a compressor 20, a condenser 30, a condensate heat exchanger 40, and a concentrate heat exchanger 50.

The evaporator 10 is connected to the raw water pipe L1 supplying raw water to the lower part in a sealed structure, and a fan 11 for removing the foam layer on the upper part, and an eliminator 13 on the upper steam discharge side are provided. When raw water (livestock manure, domestic sewage, industrial wastewater, etc.) is introduced into the interior through the raw water pipe (L1), it is circulated through the raw water circulation pipe (L2), and heated with superheated steam discharged from the compressor (20) to evaporator (10). ) Rises to a temperature that can evaporate. At this time, the concentrated solution is discharged to the outside through the concentrated solution pipe (L3). In addition, the raw water of the evaporator 10 is circulated to the evaporator 10 through the condenser 40 through the raw water inlet L1, and the concentrated liquid is transferred to the concentrate heat exchanger 50 by the concentrate pipe L3 and the concentrate pump P2. ), and then discharged to the outside.

The compressor 20 is a blower and compresses the vapor discharged from the evaporator 10 and discharges it as superheated vapor.

When the superheated steam discharged from the compressor 20 flows into the high temperature side and the raw water circulated by the circulation pump P1 in the evaporator 10 flows into the low temperature side, the condenser 30 exchanges heat to condense the superheated steam.

The condensate heat exchanger 40 heats the raw water by heat exchange when the condensed condensed water discharged from the condenser 30 flows into the high temperature side, and when the raw water flows into the low temperature side through the raw water pipe L1, the high temperature condensate is heated to a low temperature. Discharge. At this time, the condensed water discharged from the condensate heat exchanger 40 is collected in the condensate drain tank 60 and discharged from the condensate drain pump P3, and some condensed water is circulated to the compressor 20. Here, the condensate drain tank 60 is provided with a water level sensor LS for sensing the level of condensate water.

In the concentrate heat exchanger 50, when the raw water flows into the low temperature side, and the concentrate from the evaporator 10 flows into the high temperature side through the concentrate pipe (L3) and the concentrate pump (P2), heat exchange is performed to heat the raw water and discharge the concentrate. do.

To explain the operation, raw water to be concentrated by the evaporator 10 is heated through the concentrate heat exchanger 50 and the condensate heat exchanger 40 and then flows in. At this time, the inside of the evaporator 10 is maintained in a low pressure state by the compressor 20, the raw water boils and evaporates in the form of water vapor, and the fan 11 of the evaporator 10 rotates to remove bubbles generated during heating. Is done.

The evaporated water vapor is discharged by the compressor 20 in a state of high-temperature and high-pressure superheated steam, and then flows back into the high-temperature side of the condenser 30. On the other hand, the raw water of the evaporator 10 has to be used as a driving heat source required for evaporation by recovering the heat of the superheated steam again because the heat of vaporization is deprived as moisture evaporates. Therefore, the raw water inside the evaporator 10 is circulated to the low temperature side of the evaporator 10 and the condenser 30 by the circulation pump P1.

The superheated steam that has been deprived of heat from the condenser 30 is condensed to enter the condensate heat exchanger 40 and undergoes heat exchange with the raw water injected into the evaporator 10 once more. This not only lowers the temperature of the discharged condensate, but also increases the efficiency.

Likewise, the concentrate is discharged from the evaporator 10 by the concentrate pump P2 to perform heat exchange with raw water injected by the concentrate heat exchanger 50.

On the other hand, such a vacuum evaporation concentrator generates bubbles explosively when raw water, which is a liquid mixture or compound, is boiled, and the generated bubbles cause clogging of pipes and equipment damage such as pumps. The outbreak must be suppressed or eliminated as it can have a lethal effect.

Conventionally, two methods are mainly used to suppress bubbles. A method of blocking the generation of bubbles by adding a defoaming agent or a physical removal method using a defoaming device is used. In the case of a defoaming agent, it is consumable and requires continuous injection. Because it is necessary, it is disadvantageous in terms of cost and management, and the defoaming device is mainly applied.

As an example of a defoaming device, a defoaming device for a stirrer, which is Korean Patent Publication No. 10-1615562, is disclosed.

As shown in Figs. 2 and 3, the foam removal device of the agitator is rotated by the storage tank 100 and the drive shaft 201 of the driving unit 200 to be discharged as much as the amount introduced while storing the incoming liquid. In the foam removing device of the stirrer consisting of a foam removing means 300 for removing liquid bubbles, the foam removing means 300 is fixedly installed at the lower end of the drive shaft 201 of the driving unit 200 For inflow and discharge of liquid, a plurality of bubble inlet 311 and outlet 312 are formed along the circumferential surface, and each bubble inlet 311 inside the bubble inlet 310 The discharge port 312 is installed radially so that each space (s) is formed, and then when the vacuum pressure is generated, the bubbles are crushed by colliding with each other, thereby guiding the liquid to be discharged. The outer wing 314 protrudes in the radial direction between the bubble inlet 311 and the outlet 312 to crush large diameter bubbles, and the outer wing 314 on the bottom surface of the foam inlet 310 Foam crushing portion (300a) consisting of a plurality of protruding lower wings 315 for crushing the large diameter bubbles located below; The upper end is fixedly installed on the drive part 200 so that the suction guide passage 321a is formed between the drive shaft 201 and the drive shaft 201 while being positioned coaxially with the drive shaft 201, while the lower end is the upper surface of the foam inlet 310 A gas guide pipe 320 to be sealed while sliding with the gas guide pipe 320, a vacuum guide pipe 330 connected to the vacuum pump 340 to generate a vacuum pressure at an upper side of the gas guide pipe 320, and a bubble inlet A gas discharge part (300b) consisting of a gas discharge hole (316), which is crushed when vacuum pressure is generated by opening between the bubble inlet pipe (310) and the gas guide pipe (320) at the top of 310, and discharges the remaining gas ); characterized by consisting of.

However, such a conventional agitator's foam removal device has a complicated structure and increases manufacturing cost, and in particular, the wing is bent or damaged due to continuous resistance due to collision with the foam, and the passage through which the liquid flows is narrow. Since the liquid is filled, the liquid cannot flow smoothly, and there is a problem that an overload occurs due to an increase in resistance.

Domestic Patent Publication No. 10-1615562

The present invention is to solve the above problems, to reduce rotational resistance by manufacturing a horizontal wing in a hollow tubular shape to prevent bending, and forming a resistance reduction hole to reduce resistance in the front and rear of the rotating pipe, An object thereof is to provide a fan for removing bubbles of a vacuum evaporation concentrator to remove bubbles while trapping bubbles by installing horizontal and vertical wings on a pipe.

Features of the present invention for achieving the above object,

In the foam removal fan installed at the top of the evaporator to remove bubbles generated in the evaporator of the vacuum evaporation concentrator and installed in a rotating motor with a rotating shaft vertically installed in the center of the evaporator, bubbles are removed while preventing bending A rotation pipe formed in a hollow tubular shape so as to have a resistance reducing hole to be symmetrical to each other on a front and a rear surface to reduce resistance, and having a central portion horizontally coupled to a rotation shaft of the rotation motor; A horizontal wing coupled to the rotating pipe; And vertical blades installed on the rotating pipe to collect bubbles toward the horizontal blades and remove them while preventing the bubbles from being scattered by rotation of the horizontal blades.

Here, the resistance reducing hole is formed in a linear shape or an oblique shape with respect to the rotation direction.

Here, the horizontal blades are respectively installed on the left and right sides of the rotation axis of the rotation motor, and are installed in front of the rotation direction, and are located in the center of the resistance reduction hole.

Here, the horizontal blade is formed in a plate shape or a saw blade shape.

Here, the vertical blade is formed in a plate shape, and an insertion hole into which the rotation pipe is inserted is formed on one side, and is inserted into the rotation pipe through the insertion hole to be welded.

Here, the vertical blades are arranged so that the vertical blades face the bottom of the rotating pipe so that bubbles rising from the evaporator are collected and trapped in the lower and upper portions of the rotating pipe. It is arranged so as to face the upper surface in the rotating pipe.

According to the vacuum evaporation concentration device capable of maintaining a stable water level according to the present invention configured as described above, a horizontal blade is manufactured in a hollow tubular shape to prevent bending, and a resistance reducing hole is formed to reduce resistance at the front and rear surfaces of the rotating pipe. It reduces rotational resistance, and can remove bubbles while confining bubbles by installing horizontal and vertical wings on the rotating pipe.

In addition, according to the present invention, the rotating pipe is formed in a tubular shape, and horizontal and vertical blades are installed on the rotating pipe, so that the occurrence of deformation of the rotating pipe, horizontal blade and vertical blade is minimized, and the structure is simple to reduce manufacturing cost. can do.

1 is a view showing the configuration of a general vacuum evaporation concentrator.
2 and 3 are views showing a foam removal device of a conventional stirrer.
4 is a front view showing a foam removal fan of the vacuum evaporation concentrator according to the present invention installed in the evaporator.
5 is a perspective view showing the configuration of a fan for removing bubbles of the vacuum evaporation concentrator according to the present invention.
6 is a plan view of FIG. 5.
7 is a perspective view showing the configuration of a fan for removing bubbles of a vacuum evaporation concentrator according to another embodiment of the present invention.
8 is a plan view of FIG. 7.

Hereinafter, the configuration of the fan for removing bubbles of the vacuum evaporation concentrator according to the present invention will be described in detail with reference to the accompanying drawings.

In the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, a detailed description thereof will be omitted. In addition, terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to the intention or custom of users and operators. Therefore, the definition should be made based on the contents throughout this specification.

Figure 4 is a front view showing a foam removal fan of the vacuum evaporation concentrator according to the present invention is installed in the evaporator, Figure 5 is a perspective view showing the configuration of the foam removal fan of the vacuum evaporation concentrator according to the present invention, 6 is a plan view of FIG. 5, FIG. 7 is a perspective view showing the configuration of a fan for removing bubbles of a vacuum evaporation concentrator according to another embodiment of the present invention, and FIG. 8 is a plan view of FIG. 7.

4 to 8, the fan 100 for removing bubbles of the vacuum evaporation concentrator according to the present invention is composed of a rotating pipe 110, a horizontal blade 120, and a vertical blade 130.

First, the rotating pipe 110 is formed in a hollow tubular shape to remove bubbles while preventing bending, and has a resistance reducing hole 111 to be symmetrical to each other on the front and rear surfaces to reduce resistance, and a vacuum evaporation concentrator ( It is installed on the top of the evaporator 10 to remove bubbles generated in the evaporator 10 of 1), and the rotating shaft is horizontally coupled with the rotating shaft of a rotating motor M installed vertically in the center of the evaporator 10. In this case, the resistance reduction hole 111 is preferably formed in a linear shape as shown in FIG. 5, and may be formed in an oblique shape with respect to the rotation direction.

And, the horizontal blade 120 is coupled to the rotation pipe 110, which is installed on the left and right sides of the rotation axis of the rotation motor M, respectively, is installed in the front of the rotation direction, and the resistance reduction hole 111 It is located in the center. At this time, the horizontal blade 120 may be formed in a plate shape as shown in FIGS. 5 and 6 or may be formed in a saw blade shape as shown in FIGS. 7 and 8.

In addition, the vertical wing 130 is installed in the rotating pipe 110 to remove the bubbles while preventing the bubbles from being scattered by the rotation of the rotating pipe 110 by collecting the bubbles toward the horizontal wing, formed in a plate shape, and on one side An insertion hole 131 into which the rotating pipe 110 is inserted is formed and inserted into the rotating pipe 110 through the insertion hole 131 to be welded. At this time, the vertical blades 130 are arranged so that the bubbles rising from the evaporator 10 are collected and trapped in the lower and upper portions of the rotating pipe 110 so that the vertical blades face the bottom surface of the rotating pipe 110, and the other Arbitrary vertical blades are arranged to face the upper surface in the rotating pipe 110, and in the drawing, four are toward the lower side, and two are illustrated to face the upper surface. And, it is preferable that the length of the vertical wing 130 is adjusted according to the amount of foam generation.

Hereinafter, the operation of the fan for removing bubbles of the vacuum evaporation concentrator according to the present invention will be described in detail with reference to the accompanying drawings.

First, when raw water is circulated and heated while flowing into the evaporator 110, bubbles are generated and rises. When the rotation motor M is rotated, the rotation pipe 110 rotates. At this time, since the rotation pipe 110 has the resistance reduction hole 111 formed, the raw water is introduced and discharged through the resistance reduction hole 111 during rotation, so that the resistance applied to the rotation pipe 110 is relatively reduced, thereby reducing bending. Is prevented from occurring.

And when the rotating pipe 110 rotates, the horizontal blades 120 and the vertical blades 130 fixed thereto rotate, and bubbles generated by the vertical blades 130 are confined within the radius of the rotating pipe 110. You lose.

The generated bubbles are destroyed and removed while contacting the rotating pipe 110, the horizontal blade 120, and the vertical blade 130.

In addition, the bubbles rising above the rotating pipe 110 are also overflowed toward the rotating pipe 110 by the vertical blades 130 and are confined within the radius of the rotating pipe 110, and the rotating pipe 110 and the horizontal blade 120 And being destroyed while contacting the vertical wing 130 is removed.

The present invention may be variously modified and may take various forms, and in the detailed description of the present invention, only specific embodiments thereof have been described. However, it should be understood that the present invention is not limited to a particular form mentioned in the detailed description, but rather, it is understood to include all modifications, equivalents, and substitutes within the spirit and scope of the present invention as defined by the appended claims. Should be.

10: evaporator 110: rotating pipe
111: resistance reduction hole 120: horizontal wing
130: vertical blade M: rotary motor

Claims (6)

In the foam removal fan installed at the top of the evaporator to remove bubbles generated in the evaporator of the vacuum evaporation concentrator and installed on a rotary motor having a rotation shaft vertically installed at the center of the evaporator,
A rotating pipe formed in a hollow tubular shape to remove bubbles while preventing bending, having a resistance reducing hole so as to be symmetrical to the front and rear surfaces to reduce resistance, and having a central portion horizontally coupled to the rotation axis of the rotation motor;
A horizontal wing coupled to the rotating pipe; And
It is installed on the rotating pipe to collect bubbles toward the horizontal blades and remove them while preventing the bubbles from being scattered by rotation of the horizontal blades, and to collect bubbles rising from the evaporator and trap them in the lower and upper portions of the rotating pipe. The fan for removing bubbles of a vacuum evaporation concentrator, characterized in that it comprises vertical blades arranged to face the bottom surface of the rotating pipe, and vertical blades arranged to face the upper surface of the rotating pipe. The method of claim 1,
The resistance reduction hole,
A fan for removing bubbles of a vacuum evaporation concentrator, characterized in that it is formed in a linear shape or in a diagonal shape with respect to the rotation direction. The method of claim 1,
The horizontal wing,
A fan for removing bubbles of a vacuum evaporation concentrator, characterized in that it is installed on the left and right sides of the rotation axis of the rotation motor, respectively, installed in front of the rotation direction, and located in the center of the resistance reduction hole. The method of claim 1,
The horizontal wing,
A fan for removing bubbles of a vacuum evaporation concentrator, characterized in that it is formed in a plate shape or a saw blade shape. The method of claim 1,
The vertical wing,
A fan for removing bubbles of a vacuum evaporation concentrator, characterized in that it is formed in a plate shape and has an insertion hole on one side into which the rotation pipe is inserted, and is inserted into the rotation pipe through the insertion hole and welded. delete

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