KR101569574B1 - Evaporation accelerator - Google Patents

Abstract

The present invention relates to a water evaporation accelerator, and more particularly, to a water evaporation accelerator which is installed in a wastewater treatment facility containing a salt or salt and rotates a scattered plate at high speed by a high pressure brine pumped by water evaporation in a saline or salt- And the salt water is scattered like fog to maximize the air contact area of the salt water, thereby accelerating the evaporation of the water, so that the salt crystals can be rapidly obtained in the case of the salt water, and the salt can be separated by the evaporation of the water in the case of the wastewater containing the salt. To a water evaporation accelerator.

Description

{EVAPORATION ACCELERATOR}

The present invention relates to a water evaporation accelerator, and more particularly, to a water evaporation accelerator capable of accelerating water evaporation in a wastewater containing salt water or salt, installed in a wastewater treatment facility containing salt water or salt, The present invention relates to a water evaporation accelerator capable of rapidly separating the salt by evaporating water.

The salty water for decontamination of salmon roe attracts salty water to salt, separates it into evaporation paper and crystallized paper, evaporates moisture in several evaporation paper for a certain time, concentrates the salt, and salt concentration (24 to 25 degrees) When concentrated, the concentrated brine is transferred to the crystal paper to further evaporate the water, thereby increasing the salt concentration and obtaining the salt crystals.

At this time, the evaporation of water depends entirely on the natural climate, and evaporation occurs due to contact with solar wind, wind and dry air. It has been recognized that it is impossible to exceed the climatic conditions and evaporate salt.

Also, in Korea, due to the limited salt area, a large amount of salt is imported.

Therefore, there have been many attempts to make a facility for the production of salt, but the production cost of the equipment, the energy cost, and the efficiency have not been put into practical use.

KR A No. 10-2008-0111363 (December 23, 2008)

Accordingly, the present invention has been made in order to solve the conventional problems, and it is an object of the present invention to maximize the contact area with air by scattering wastewater containing salty salt or saline in the air, To evaporate salt quickly and to accelerate the salt crystals to overcome the natural climatic conditions, to increase the amount of salt, or to separate the salt from the wastewater containing the salt in a short time, so that the salt can be evaporated at low cost and the wastewater containing the salt can be easily It has a purpose in processing.

In this case, when a separate motor is used to drive the apparatus, there is a problem of cooling of the motor and corrosion due to salt water. In order to solve this problem, the structure of the apparatus becomes very complicated and the cost of the apparatus becomes high. It acts as an obstacle factor.

According to an aspect of the present invention, there is provided a water evaporation accelerator comprising:

A pedestal mounted on the floor;

A scattering plate shaft mounted perpendicularly to the pedestal;

A non-acid dish provided horizontally at the upper end of the scatter plate shaft and provided with a scattering projection;

A scattering plate driving blade formed on a scattering plate;

A brine nozzle which rotates a scattering plate by colliding brine with a flying blade at high speed;

A pump for pumping brine or wastewater to feed the brine nozzle; And

A transfer pipe for transferring the pumped brine or wastewater to the nozzle; .

In addition, the scatterer is formed by scattering protrusions on the upper edge of the outer wall, discharged from a brine nozzle provided for rotating the scatterer, collided with a flying plate-driving wing and rotated by a scattering plate, By the centrifugal force due to the rotation of the dish, it ascends on the inner wall of the scattering dish and meets the scattering projections on the upper side of the outer wall. It collides with the scattering projections and becomes fine mist like salt mist. When this happens, So that the water evaporation takes place quickly.

According to another embodiment of the present invention, in the above-described embodiment, the flying plate driving wing is formed outside the flying plate, and the transfer pipe for guiding the wastewater containing salt or salt to the flying plate is branched in the middle, Or a structure in which saline-containing wastewater is supplied to a nozzle for impinging on a scattering-plate-driving wing, and the other is directly supplied to a central upper portion of a scattering dish to allow saline or wastewater to be scattered.

The water evaporation accelerator according to the present invention is dispersed like mist in the air due to the salty water or saline-containing wastewater that rotates in the air, thereby maximizing the contact area with the air, thereby accelerating the evaporation of water in the saline or wastewater, There is no need to solve the problem of sealing to prevent motor corrosion and the problem of motor cooling due to the fact that a separate motor for rotating the flying saucer is not used, It is possible to commercialize it with low cost, it can be commercialized economically. It is expected to increase the cost of salt substitution by increasing the cost of salt, and it is expected that salt water containing wastewater such as Kimchi factory, There is an effect that the wastewater can be treated inexpensively and easily.

1 is a perspective view illustrating a structure of a water evaporation accelerator according to an embodiment of the present invention.
Fig. 1A is a detailed view showing the action of a flying blade driving wing and a nozzle seen from "A" to "A"
FIG. 2 is a perspective view illustrating a water evaporation accelerator structure according to another embodiment of the present invention. FIG.
3 is a sectional view showing the structure of a rotating part between a scattering plate and a scattering plate shaft according to the present invention.
4 is a cross-sectional view showing a structure in which a rotating portion is formed at a joint portion between a scatterer shaft and a pedestal.

Hereinafter, a water evaporation accelerator according to the present invention will be described in detail with reference to the accompanying drawings.

One embodiment includes a pedestal 10 mounted on the bottom of a water evaporator according to the present invention as shown in these figures (Figures 1 and 1a), a scattered dish shaft 20 mounted vertically to the pedestal 10 A scattering plate 30 provided rotatably and horizontally on the upper end of the scattering dish shaft 20 and provided with a scattering protrusion 30-1 for scattering saline water by colliding the scattering dish 30 with the brine during rotation, A scattering plate driving blade 40 formed inside the scattering plate 30 for rotating the scattering plate, a brine nozzle 50 installed to rotate the scattering plate, a pump 70 for pumping saline water, And a transfer pipe 60 for guiding the saline water pumped by the pump 70 to the brine nozzle 50.

The pedestal 10 is installed on the floor and may be fixed on the floor or may be placed on the floor without any fixing.

The scattering principle of the brine is detailed in that the scattering dish 30 is installed horizontally rotatably on the upper end of the scattering dish shaft 20 and the scattering dish 30 is formed with a wall having a predetermined height on the outer circumference, Scattering protrusions 30-1 are formed so that the brine discharged from the brine nozzle 50 collides against the scattering plate drive vane 40 for rotating the scattering plate 30 fixed inside the scattering plate, And moves on the inner wall of the scattering dish 30 at a high speed in the outer circumferential direction of the scattering dish 30 and collides with the scattering protrusions 30-1 formed on the wall upper end portion of the scattering dish 30 rotating at high speed, And it becomes scattered.

A pump 70 for raising salt water is provided on one side of the pedestal 10 and a transfer pipe 60 is connected to the pump 70. The other end of the transfer pipe 60 is connected to the inside of the scatterer 30 The salt water pumped from the pump 70 is connected to the brine nozzle 50 located above the scatterer plate driving vane 40 and reaches the brine nozzle 50 through the transfer pipe 60, The salt water discharged at a high pressure collides with the flyer plate driving vane 40 at a high speed to rotate the flyer plate 30. The fine salt water droplets such as mist scattered by the rotation of the flyer plate 30 have a surface area It is maximized and comes into contact with the air, and rapid evaporation occurs.

Another embodiment of the present invention includes a pedestal 10 installed on the bottom of a water vaporizer according to the present invention as shown in these figures (Fig. 2), a scatterer shaft 20 mounted perpendicularly to the pedestal 10, And a scattering plate 30 provided horizontally rotatably on the upper end of the scattering plate shaft 20 and having scattering protrusions 30-1 for scattering the saline water by colliding with the saline water when the scattering plate 30 is rotated, A scattering plate driving blade 40 formed outside the scattering plate 30 for rotating the scattering plate, a brine nozzle 50 installed to rotate the scattering plate, a pump 70 for pouring brine, And a transfer pipe 60 for transferring the brine pumped by the pump 70 to the brine nozzle 50 and the center upper end of the scatterer 30.

The pedestal 10 is installed on the floor and may be fixed on the floor or may be placed on the floor without any fixing.

The scattering principle of the brine is detailed in that the scattering dish 30 is installed horizontally rotatably on the upper end of the scattering dish shaft 20 and the scattering dish 30 is formed with a wall having a predetermined height on the outer circumference, The scattering protrusions 30-1 are formed and the brine discharged from the brine nozzle 50 is scattered and scattered by the scattering plate drive vane 40 for rotating the scattering plate formed on the outside of the scattering plate, And the brine supplied to the scattering dish 30 is moved at a high speed in the outer peripheral direction inside the scattering dish 30 by the centrifugal force, (30 - 1) formed on the upper part of the wall of the scattering dish (30) rotating at a high speed while riding on the inner wall of the scattering plate (30) and scattered like a fog in the form of fine brine droplets. This maximizes air and Catalyst, and rapid evaporation occurs is larger than the non-salt water droplets scatter plate driving changed by a small drop of the saline brine conflict for the wings 40 will facilitate the raising evaporation surface area of the brine.

A pump 70 for pouring salt water is provided on one side of the pedestal 10 and a transfer pipe 60 is connected to the pump 70. The other end of the transfer pipe 60 is connected to the outside of the scatterer 30 The salt water pumped from the pump 70 connected to the brine nozzle 50 located at the side of the formed scatterer plate driving vane 40 reaches the brine nozzle 50 through the transfer pipe 60 and flows into the brine nozzle 50, And the other end of the transfer pipe 60 is located at the upper center of the scatterer plate 30 so as to rotate the flyer plate 30 The salt water for scattering in the scattering dish 30 is supplied.

In other words, the microbes such as fog, which maximizes the surface area, repeatedly come into contact with the air repeatedly, so that the evaporation quickly occurs and the crystallization of the salt proceeds rapidly.

10: Stand
20: Scattering plate shaft
30: scattering dish, 30-1: scattering projection
40: Driven blade for scattering dish
50: brine nozzle
60: conveying pipe
70: Pump

Claims (4)

A pedestal 10 installed on the floor;
A scatterer plate shaft 20 installed vertically to the pedestal 10;
A scattering dish 30 horizontally installed on the upper end of the scattering dish shaft 20 and having a scattering protrusion 30-1 for scattering the saline water by colliding with the saline water when the scattering dish 30 is rotated;
A scattering plate drive blade (40) formed on a scattering plate;
A pump 70 for pumping saline or saline-containing wastewater; And
A transfer pipe (60) for guiding wastewater containing saline or saline pumped by the pump (70) to a scattering dish;
A brine nozzle 50 for impinging the saline-containing or wastewater containing wastewater transferred to the transfer pipe 60 against the scatterer-driving vane 40; Wherein the water evaporation accelerator comprises: 2. The water evaporation accelerator according to claim 1, wherein the scattering plate driving vane (40) is formed inside the scattering plate. [3] The apparatus according to claim 1, wherein the scattering plate driving vane (40) is formed outside the scattering plate and the conveyance pipe (60) for guiding the wastewater containing saline or salt to the scattering plate is branched in the middle, The water is supplied to the brine nozzle 50 for impinging the saline- or salt-containing wastewater on the scattering plate driving blades 40, and the other is supplied directly to the scattering dish to evaporate the water containing saline or saline, Accelerator. The water evaporation accelerator according to claim 1, wherein the scatterer (30) is fixed to the scatterer shaft (20), and a rotation part is formed where the support and the scatterer shaft (20) are coupled.

Images