KR101176113B1 - Evaporative condensing apparatus for waste water and system including the apparatus - Google Patents

Abstract

Wastewater evaporative condensation apparatus according to the present invention is a device for evaporating and condensing the transported wastewater, the first water tank for transporting to the post-treatment process while storing the transported wastewater, a blowing unit for supplying air, from the first water tank A plurality of diaphragms are provided for passing the transported wastewater, and the second water tank receiving the air from the blower unit to evaporate water from the waste water, the second water tank containing the waste water passed through the tubular water, and the waste water contained in the second water tank. Condenser tube and condenser tube for condensing and absorbing heat from the steam supplied from the tubular body by a plurality of microtubes arranged in a bundle form in which the waste water conveyed by the transfer pump is circulated through the connection pipe Air reaching the surface of the field is characterized in that it comprises a third tank for receiving the water formed by condensation. Thereby, the present invention can reduce the consumption of power for evaporation and condensation by increasing the evaporation rate of the wastewater passing through the diaphragm and increasing the condensation rate by the condensation tube of the bundle type.

Description

Wastewater evaporative condensation system and wastewater evaporative condensation system including the same {EVAPORATIVE CONDENSING APPARATUS FOR WASTE WATER AND SYSTEM INCLUDING THE APPARATUS}

The present invention relates to a wastewater evaporative condensation apparatus. In particular, the present invention relates to a wastewater evaporative condensation apparatus for treating by condensation of the conveyed wastewater.

Conventional wastewater evaporative condensation apparatus requires a process of evaporating and condensing wastewater in order to incinerate or cake the sludge, and to this end, conventional wastewater evaporative condensation apparatus evaporates by passing wastewater through a pipe of a boiler where steam or hot water is circulated. And a condensation method is used.

However, the conventional wastewater evaporative condensation apparatus has a disadvantage in that manufacturing costs are increased due to essential components to be installed such as steam or hot water generation and circulation means for evaporation and condensation, and power consumption for driving them is increased. .

In addition, the conventional wastewater evaporative condensation device has a need to install a separate device if additional processing is required for the result of the evaporation and condensation treatment is completed.

It is an object of the present invention to provide a wastewater evaporative condensation system and a wastewater evaporative condensation system capable of increasing the efficiency of evaporation and condensation while reducing power consumption and manufacturing costs by improving the components related to evaporation and condensation.

In order to solve the above problems, the wastewater evaporation condensation apparatus according to the present invention is a first receiving tank for transporting to the post-treatment process while storing the transported wastewater; A blowing unit for supplying air; A plurality of diaphragms provided with a plurality of diaphragms for passing the wastewater transferred from the first water tank to receive air from the blower unit and to evaporate water from the wastewater; A second accommodation tank accommodating wastewater that has passed through the clearance tube; A transfer pump for transferring wastewater contained in the second accommodation tank through a connection pipe; A condensation tube for absorbing and condensing heat from the steam supplied from the tubular body by a plurality of microtubes arranged in a bundle in which waste water transferred by the transfer pump is circulated; And a third water tank containing water formed by condensation of air reaching the surfaces of the condensation tube microtubes.

The diaphragms may have a bent shape to expand the contact area with the wastewater.

The diaphragms may be provided with a plurality of holes for expanding the contact area with the wastewater.

The wastewater transported to the outside through the condensation tube may be heated to a predetermined temperature and then transferred to the first receiving tank to be repeatedly processed by the wastewater evaporative condensation apparatus.

In addition, in order to solve the above problems, the wastewater evaporation condensation apparatus according to the present invention is a first receiving tank for transporting to the post-treatment process while storing the transported wastewater; A blowing unit for supplying air; A plurality of diaphragms provided with a plurality of diaphragms for passing the wastewater transferred from the first water tank to receive air from the blower unit and to evaporate water from the wastewater; A second accommodation tank accommodating wastewater that has passed through the clearance tube; A transfer pump for transferring wastewater contained in the second accommodation tank through a connection pipe; A condensation tube configured to bundle a plurality of heat pipes partially embedded in a fourth water tank in which waste water transferred by the transfer pump is accommodated, so as to absorb and condense heat with steam supplied from the tubular body; And a third water tank containing water formed by the condensation of air reaching the surface of the condensation tube heat pipe.

The diaphragms may have a bent shape to expand the contact area with the wastewater.

The diaphragms may be provided with a plurality of holes for expanding the contact area with the wastewater.

The wastewater transported to the outside through the condensation tube may be heated to a predetermined temperature and then transferred to the first receiving tank to be repeatedly processed by the wastewater evaporative condensation apparatus.

In addition, in order to solve the above problems, the wastewater evaporation condensation apparatus is installed to penetrate up and down in the center of the condensation tube to be a rotation axis of the condensation tube; A joint coupled to the top and bottom of the rotation shaft to rotate the condensation tube; And a motor providing rotational force to the rotating shaft via a pulley and a belt.

In order to solve the above problems, the wastewater evaporative condensation system according to the present invention includes a plurality of wastewater evaporative condensation apparatuses, and the wastewater evaporative condensation apparatuses are connected to each other, and are transported from the condensation tube of the wastewater evaporative condensation apparatus arranged at the front end. Characterized in that for conveying the wastewater to the first water tank of the wastewater evaporative condensation apparatus disposed at the rear end.

Wastewater evaporative condensation system and wastewater evaporative condensation system according to the present invention by introducing a curved structure in the plate flowing wastewater to increase the evaporation rate of the wastewater and condensation tube in the form of a plurality of pipes to increase the condensation rate wastewater treatment process Can reduce energy consumption for evaporation and condensation.

In addition, the bent structure of the diaphragm and the multi-pipe structure of the condensation pipe applied in the wastewater evaporative condensation system and the wastewater evaporative condensation system according to the present invention can reduce the manufacturing cost by changing the simple structure.

1 is a block diagram of a wastewater evaporative condensation apparatus according to a first embodiment of the present invention.
FIG. 2 is a cross-sectional view taken along line II ′ of FIGS. 1 and 4.
Figure 3 is a flow chart showing the wastewater treatment operation of the wastewater evaporative condensation apparatus according to the present embodiment.
4 is a block diagram of the wastewater evaporation condensation apparatus according to the second and third embodiments of the present invention.
5 is a block diagram of a wastewater evaporative condensation system according to another embodiment of the present invention.

Hereinafter, a wastewater evaporative condensation apparatus and a wastewater evaporative condensation system including the same will be described in detail with reference to the accompanying drawings.

1 and 2, a wastewater evaporative condensation apparatus 100 according to a first embodiment of the present invention will be described. 1 is a block diagram of a wastewater evaporative condensation apparatus according to a first embodiment of the present invention, Figure 2 is a cross-sectional view taken along the line II 'of FIG.

As shown in FIG. 1, the wastewater evaporative condensation apparatus 100 according to the first embodiment of the present invention includes a first water tank 110, a tubular body 120, a second water tank 130, and a connection pipe ( 140), the condensation tube 150, the transfer pump 160, the blowing unit 170, the third receiving tank 180, the blowing connection tube 190 and the like.

The first receiving tank 110 supplies the clearance body 120 while storing the wastewater transferred from the outside. The waste water may be directly transferred to the first water tank 110 from the outside, or may be transferred to the first water tank 110 while being heated by a heating means (not shown). The heating means not shown may be provided in the first receiving tank 110 as necessary.

The first water tank 110 is formed with a wastewater conveyance port 115 for transferring the stored wastewater to the clearance body 120. As shown in FIG. 1, the wastewater conveying port 115 is formed in the form of a plurality of holes in the lower surface of the first receiving tank 110, and the wastewater passing through the plurality of holes is introduced into the tubular body 120. Supplied.

The size of the wastewater feed port 115 formed in the first receiving tank 110 may vary depending on the structure of the diaphragm 125 shown in FIG. 2. This is because the evaporation rate of the wastewater evaporative condensation apparatus 100 according to the first embodiment of the present invention is affected by the structure of the diaphragm 125, and according to the structure of the diaphragm 125 through the wastewater feed port 115. This is to adjust the amount of wastewater transferred to the diaphragm 125.

As shown in FIG. 2, the tubular body 120 includes a plurality of diaphragms 125 for evaporating while passing the wastewater conveyed from the first water tank 110. These diaphragms 125 are supported by an outer body, not shown, of the clearance body 120. Wastewater transferred into the clearance body 120 flows along the diaphragm 125. Wastewater descending along the diaphragm 125 is deprived of heat by the air introduced into the diaphragm 125 while flowing along the diaphragm 125. Most wastewater deprived of heat while passing through the clearance body 120 is accommodated in the second water tank 130. Air introduced into the diaphragms 125 is transferred to the condensation tube 150 along with the heat absorbed while passing through the diaphragms 125. This movement is made by the blowing unit 170.

The diaphragm 125 has a curved shape as shown in FIG. Due to such a curved shape, the wastewater flowing along the diaphragm 125 is relaxed to increase the time for staying in the diaphragm 125, and the contact area between the wastewater and the diaphragm 125 is widened, thereby facilitating evaporation of moisture. The curved shape of the diaphragm 125 may be variously changed to promote evaporation from the wastewater. In addition, a plurality of holes (not shown) may be formed in the diaphragm 125 to increase the evaporation rate of moisture. Multiple holes further mitigate the flow of wastewater and further increase the contact surface area.

The second water tank 130 accommodates the wastewater passing through the clearance body 120 above. In the first embodiment of the present invention, when the temperature of the wastewater before passing through the tubular body 120 is 50 ° C, the temperature of the wastewater accommodated in the second water tank 130 may be lowered to 30 ° C. This is the temperature that the waste water is lowered while passing through the diaphragm 125 in the clearance body 120, the magnitude of the temperature drop is changed by the blowing amount of the air blowing unit 170, the temperature / humidity of the air, the structure of the diaphragm 125 Can be.

The connection pipe 140 performs a function of connecting the waste water accommodated in the second water tank 130 to the condensation pipe 150 and moves the waste water to the condensation pipe 150 by the transfer pump 160.

The condensation tube 150 condenses steam and recovers heat, and serves to transfer the wastewater moved through the connection pipe 140 to the outside.

The condensation tube 150 may be formed of about 900 microtubes 154, and a conveying tube 152 is formed to transfer wastewater transferred to the condensation tube 150 to the outside. The number of the microtubes 154 and the heat pipes 154a in the second embodiment to be described later, and the gap therebetween may vary depending on the processing capacity, efficiency, and the like. The plurality of microtubules 154 promote the condensation of the vapor to maximize the contact surface of the vapor and the outer surface of the condensation tube 150, including the heat absorbed while passing through the diaphragm (125). In addition, it is possible to maximize the contact area by additionally installing a heat radiation fin (not shown) in the condensation tube (150).

In the above condensation process, the condensation tube 150 absorbs heat from the steam reaching the surface of the microtube 154 and performs a function of fruit (熱 媒) to transfer heat to the wastewater flowing therein. In general, fruit means the wall between a high temperature fluid and a low temperature fluid. As a result, the temperature of the wastewater passing through the condensation tube 150 increases slightly.

In addition, the wastewater evaporative condensation apparatus 100 according to the first embodiment of the present invention may include a condensation tube body 156 housing the outer surface of the condensation tube 150. The condensation tube body 156 seals the surroundings of the condensation tube 150, and may receive moisture generated by the condensation of the sealed vapor into the third water tank 180.

The transfer pump 160 transfers the wastewater contained in the second water tank 130 to the condensation tube 150, and transfers the wastewater transferred to the condensation tube 150 to the outside. The wastewater transported to the outside may be heated by a heating means (not shown) such as a boiler or a heater according to a user's need, and then transferred to the first water tank 110 to undergo a reprocessing process.

As shown in FIG. 1, the transfer pump 160 may be integrally formed to be connected to the connection pipe 140.

The air blowing connection tube 190 is disposed between the tubular body 120 and the condensation tube 150 as shown in FIG. 1, and condenses the steam absorbing heat from the waste water in the course of passing through the diaphragms 125. (150) Connect to reach the surface of the microtubule 154. Blowing connection pipe 190 should be sealed so as not to leak steam in the process of moving from the tube body 120 to the condensation pipe 150.

Blowing unit 170 is a predetermined intensity so that the air flows into the diaphragm 125 and the steam passing through the diaphragm 125 reaches the surface of the condensation tube 150 and the microtubule 154 through the air blowing connection tube 190. Raises the wind. As shown in FIG. 1, the blower unit 170 introduces air 'A' into the diaphragms 125 and passes through the diaphragms 125, and the steam 'B' passed through the diaphragms 125. ) Blows to reach the outer surface of the condensation tube 150 through the air blowing connector 190. The blowing amount generated by the blowing unit 170 may be changed by the diaphragm 125 structure as shown in FIG. 2. If the number of the diaphragm 125 is large or the bending formed in the diaphragm 125 is dense, the airflow amount should be increased.

And, as shown in Figure 1, the blowing pipe 175 is installed to guide the wind generated in the blowing unit 170 to the clearance body 120 without loss.

The third water tank 180 serves to receive the water condensed on the outer surface of the condensation tube 150. Moisture contained in the third receiving tank 180 is transferred to a purified water storage tank (not shown) through the purified water pipe 185. In this case, it is possible to further install a purified water pipe valve 187 for controlling whether to transfer the water contained in the third receiving tank 180 to the purified water storage tank.

That is, the steam passing through the diaphragm 125 by the blower unit 170 reaches the surface of the microtube 154 of the condensation tube 150 by the blower connection tube 190 and condenses. It is accommodated in the third receiving tank 180, and is transferred to the purified water storage tank depending on whether the water purification valve 187 is opened or closed.

Hereinafter, the operation of the wastewater evaporative condensation apparatus 100 according to the first embodiment of the present invention will be described in detail with reference to FIG. 3.

First, the first water tank 110 of the wastewater evaporative condensation apparatus 100 transfers the stored wastewater to the clearance body 120 by a predetermined amount through the wastewater transfer port 115 while storing the wastewater transferred from the outside (S210).

The wastewater transported to the clearance body 120 flows along the surfaces of the diaphragms 125, and the wastewater flowing through the diaphragms 125 is deprived of heat by the introduced air. It moves to the condensation tube 150 through the air blowing connector 190 (S220). The movement of the steam from the diaphragm 125 to the outer surface of the condensation tube 150 is caused by wind generated by the blowing unit 170.

Wastewater deprived of heat while passing through the diaphragms 125 is received by the second receiving tank 130 (S230). The received waste water is transferred to the outside via the connection pipe 140 and the condensation pipe 150 by the transfer pump 160 (S240).

In the first embodiment of the present invention, when the wastewater stored in the first water tank 110 is approximately 50 ° C., the wastewater that has passed through the diaphragm 125 of the clearance body 120 has a temperature lowered to approximately 30 ° C. to accommodate the second water. Housed in tank 130. The temperature drop of the waste water is because waste water passing through the diaphragm 125 is deprived of heat by the air introduced by the blower unit 170.

The waste water at 30 ° C. accommodated in the second water tank 130 rises about 10 ° C. while passing through the condensation tube 150. This is because the steam moved through the air connection pipe 190 increases the temperature of the wastewater flowing therein while contacting the outer surface of the condensation pipe 150.

The steam moved to the condensation tube 150 in step S220 is condensed, and the water formed by condensation is received by the third water tank 180 (S250). The water contained in the third water tank 180 is transferred to a purified water storage tank not shown through the purified water pipe 185.

As such, the wastewater evaporative condensation apparatus 100 according to the first embodiment of the present invention may improve the evaporation rate by passing the wastewater through the curved diaphragm 125, and vaporizes on the outer surface of the condensation tube 150. By contacting the temperature of the wastewater passing through the inside of the condensation tube 150 can be raised.

The wastewater evaporative condensation apparatus 100 according to the first embodiment of the present invention transfers the wastewater transferred to the outside through the condensation tube 150 to the first water tank 110 again according to the first embodiment of the present invention. Re-treatment by the wastewater evaporative condensation apparatus 100 may be performed. In this case, since the temperature of the wastewater transferred back to the first receiving tank 110 is elevated by the condensation tube 150 of the pretreatment step, the temperature of the wastewater before being transferred to the first receiving tank 110 is increased. It is possible to reduce the power consumed.

Hereinafter, a wastewater evaporative condensation apparatus according to a second embodiment of the present invention will be described with reference to FIG. However, the same reference numerals are assigned to some of the same components as the first embodiment, and detailed description thereof will be omitted. 4 is a block diagram of a wastewater evaporative condensation apparatus according to a second embodiment of the present invention.

As shown in FIG. 4, the wastewater evaporative condensation apparatus 200 according to the second embodiment of the present invention includes a first water tank 110, a tubular body 120, a second water tank 130, and a transfer pump 160. ), A blower unit 170 and the like are the same as those of the first embodiment of FIGS. 1 and 2.

The transfer pump 160 in the first embodiment circulates the wastewater of the second receiving tank 130 to the microtube 154 of the condensation pipe 150 through the connecting pipe 140, but in the second embodiment The transfer pump 160 temporarily receives the wastewater of the second accommodation tank 130 in the fourth accommodation tank 157a through the connection pipe 140 and then discharges the wastewater to the outside through the transfer pipe 152a.

Waste water transferred from the fourth tank 157a through the transfer pipe 152a is heated by an unshown heating means such as a boiler or a heater according to a user's need, and then transferred to the first tank 110 again. Reprocessing may take place. Here, in the first embodiment, the wastewater is directly heated by heat obtained in the process of condensing the steam supplied from the tube 120 in the first embodiment, but in the second embodiment, the steam supplied from the tube 120 is condensed. The heat of the heat pipe 154a is heated by the heat obtained in the process of making it, and the wastewater accommodated in the 4th water tank 157a is heated again using the heat of this heat pipe 154a.

In the second embodiment, the condensation tube 150a is arranged in a bundle such that a plurality of heat pipes 154a are partially inserted into the lower end of the fourth accommodation tank 157a. Waste water from the second water tank 130 is introduced by the transfer pump 160. Since the plurality of heat pipes 154a have a structure for maximizing the contact area between the steam including heat absorbed while passing through the diaphragms 125 and the surface of the heat pipe 154a of the condensation tube 150a, the condensation of steam To promote.

In addition, the heat pipe 154a may be formed in a heat radiation fin shape to maximize the contact area between the heat pipe 154a and air containing moisture.

In the above condensation process, the heat pipe 154a absorbs heat from the steam reaching the surface of the heat pipe 154a and transfers the heat to the wastewater contained in the fourth water tank 157a. As a result, the temperature of the wastewater accommodated in the fourth accommodation tank 157a increases slightly.

In addition, the wastewater evaporative condensation apparatus 200 according to the second embodiment of the present invention may include a condensation tube body 156a housing the outer surface of the condensation tube 150a. The condensation tube body 156a seals the circumference of the condensation tube 150a and accommodates the moisture generated by the condensation of the sealed steam into the third water tank 180.

As shown in FIG. 4, the blower connection pipe 190 is disposed between the tubular body 120 and the condensation pipe 150a, and the steam absorbing heat from the waste water in the course of passing through the diaphragms 125 includes a condensation pipe ( 150a) to the surface of the heat pipe 154a. Blowing connection pipe 190 should be sealed so as not to leak steam in the process of moving from the tube body 120 to the condensation pipe (150a).

The third water tank 180 serves to receive moisture condensed on the surface of the heat pipe 154a of the condensation tube 150a. Moisture contained in the third receiving tank 180 is transferred to a purified water storage tank (not shown) through the purified water pipe 185. In this case, it is possible to further install a purified water pipe valve 187 for controlling whether to transfer the water contained in the third receiving tank 180 to the purified water storage tank.

That is, the steam generated while passing through the diaphragm 125 by the blowing unit 170 is condensed by reaching the surface of the heat pipe 154a of the condensation tube 150a by the blowing connecting tube 190, and formed by condensation. Moisture flows down to be accommodated in the third receiving tank 180, and is transferred to the purified water storage tank according to whether the purified water pipe valve 187 is opened or closed.

Hereinafter, with reference to Figure 3, the operation of the wastewater evaporation condensation apparatus 200 according to the second embodiment of the present invention will be described in detail.

First, the first receiving tank 110 of the wastewater evaporative condensation apparatus 200 transfers the stored wastewater to the clearance body 120 by a predetermined amount through the wastewater conveyance port 115 while storing the wastewater transported from the outside (S210).

The waste water transferred to the clearance body 120 is deprived of heat by the air introduced while flowing down the surfaces of the diaphragms 125, and steam absorbing heat in this process is condensed through the air connection pipe 190. It moves to 150a (S220). The movement of steam from the diaphragm 125 to the surface of the heat pipe 154a of the condensation tube 150a is caused by wind generated by the blowing unit 170.

Wastewater deprived of heat while passing through the diaphragms 125 is received by the second receiving tank 130 (S230). The received waste water is transferred to the outside via the connection pipe 140 by the transfer pump 160 (S240).

Also in the second embodiment of the present invention, when the waste water stored in the first water tank 110 is approximately 50 ° C., the waste water that has passed through the diaphragm 125 of the clearance body 120 is lowered to approximately 30 ° C. so that the second water tank ( 130 is accommodated. The temperature drop of the waste water is because waste water passing through the diaphragm 125 is deprived of heat by the air introduced by the blower unit 170.

The steam moved to the condensation tube 150a in step S220 is condensed, and the water formed by condensation is received by the third water tank 180 (S250). The water contained in the third water tank 180 is transferred to a purified water storage tank not shown through the purified water pipe 185.

As such, the wastewater evaporative condensation apparatus 100 according to the second embodiment of the present invention may improve the evaporation rate by passing the wastewater through the curved diaphragm 125, and the heat pipe 154a of the condensation tube 150a. The temperature of the heat pipe 154a of the condensation tube 150a and the heat pipe 154a may be increased by contacting the surface of the steam, and the temperature of the wastewater accommodated in the fourth water tank 157a may be raised.

The wastewater evaporative condensation apparatus 200 according to the second embodiment of the present invention transfers the wastewater transported to the outside through the tubular body 120 to the first water tank 110 again according to the second embodiment of the present invention. Re-treatment by the wastewater evaporation condenser 200 may be performed. In this case, since the wastewater conveyed back to the first receiving tank 110 has a temperature of 20 ° C. lowered from the clearance body 120 of the pretreatment step, the wastewater temperature before being transferred to the first receiving tank 110 is determined. The power consumed to raise can be reduced.

The wastewater evaporative condensation apparatus according to the third embodiment of the present invention includes condensation tubes 150 and 150a in the wastewater evaporative condensation apparatus 100 and 200 of the first and second embodiments as shown in FIGS. 1 and 4. It further comprises a means for rotating while supporting, to increase the condensation rate of the water-containing steam supplied from the tube body 120.

To this end, rotating shafts 151 and 151a penetrating up and down in the center of the condensation tube 150 and 150a are installed, and upper and lower ends of the rotating shafts 151 and 151a include rotating shafts 151 and 151a. Joints 163 and 164 for smooth rotation of the condensation tube 150, 150a is provided. The rotating shafts 151 and 151a rotate by receiving rotational force from the motor 158 via the pulleys 161 and 162 and the belt 159.

The rotating shafts 151 and 151a should have strength enough to support the condensation tubes 150 and 150a including approximately 900 microtubes 154 or heat pipes 154a, and the rotating shafts 151 and 151a. Of course, the combination of the condensation tube 150 and 150a should be strong enough to withstand the load applied to the rotational force on the weight of the condensation tube 150 and 150a.

The rotating shafts 151 and 151a may be installed separately from the connection pipe 140 or the transfer pipes 152 and 152a, but the rotating shafts 151 and 151a in the present invention are as shown in FIGS. 1 and 4. It also serves as a connection pipe 140 and the transfer pipe 152 (152a).

To this end, a connecting pipe 140 for supplying wastewater is connected to the lower end of the rotary shafts 151 and 151a in the form of a tube, and a transfer pipe 152 for discharging the wastewater to the top of the rotary shafts 151 and 151a ( 152a) is connected.

In addition, the inlet 163 for injecting wastewater into the microtube 154 and the outlet 155 for discharging the wastewater of the microtube 154 to the outside are formed above and below the rotating shaft 151. The rotating shaft 151 between the injection port 163 and the discharge port 155 is blocked so that unheated waste water is not discharged to the outside.

In addition, the inlet 163a for injecting the wastewater into the fourth water tank 157a and the outlet 155a for discharging the waste water of the fourth water tank 157a to the outside are formed in the rotary shaft 151a. The rotary shaft 151a between the injection port 163a and the discharge port 155a is also blocked so that the waste water that is not heated is not discharged to the outside.

Here, the injection hole 163 of the rotary shaft 151 is on the rotary shaft 151 of the position in communication with the lower end of the microtube 154, the discharge port 155 is the rotary shaft of the position where the microtube 154 is in communication with the upper end ( 151, and the inlet 163a of the rotation shaft 151a is on the rotation shaft 151a at a position communicating with the bottom end of the fourth accommodation tank 157a, and the outlet 155a is the top end of the fourth accommodation tank 157a. It is preferably formed on the rotary shaft 151a at a position communicating with each other.

Therefore, as the condensation tube 150, 150a rotates, the path of the hot steam containing moisture introduced from the tubular body 120 is continuously changed, and the microtube 154 or the condensation tube 150a of the condensation tube 150 is changed. Since the heat pipe 154a of) is evenly heated, the condensation rate of steam is maximized.

Hereinafter, a wastewater evaporative condensation system 10 according to another embodiment of the present invention will be described with reference to FIG. 5. However, hereinafter, only the wastewater evaporative condensation system 10 including the wastewater evaporative condensation apparatus 100 of the first embodiment will be described, but the fourth embodiment is not limited thereto and the wastewater evaporative condensation apparatus of the second and third embodiments ( Wastewater evaporative condensation systems comprising 100) 200 are also possible.

As shown in Figure 5, the wastewater evaporative condensation system 10 according to the present embodiment is configured by connecting a plurality of wastewater evaporative condensation apparatus 100 described above as many as the number of wastewater evaporative condensation apparatus 100 used The evaporative condensation process proceeds. Therefore, an improved wastewater treatment effect can be expected than using one wastewater evaporative condenser 100.

5 shows the wastewater evaporative condensation system 10 using two wastewater evaporative condensation apparatus 100 for convenience, the number of wastewater evaporative condensation apparatus 100 can be variously changed as necessary.

In the wastewater evaporative condensation system 10 according to another embodiment of the present invention, two wastewater evaporative condensation apparatuses 100 and 100a are connected. Wastewater transferred from the transfer pipe 152 of the wastewater evaporative condenser 100 disposed at the front end is transferred to the first water tank 110 of the wastewater evaporative condenser 100a arranged at the rear end. The treatment of the transferred wastewater is made in the same manner as the operation of the wastewater evaporative condensation apparatus 100 described above.

Therefore, the wastewater evaporative condensation system 10 according to another embodiment of the present invention performs the wastewater treatment operation twice because the wastewater evaporative condensation system 10 performs the wastewater treatment operation twice. Wastewater treatment performance is improved than 200.

Meanwhile, the wastewater evaporative condensation apparatus 100 and 200 and the wastewater evaporative condensation system 10 according to the embodiments of the present invention have been introduced only to the treatment using wastewater, but are not wastewater such as river water and seawater. Naturally, it can be applied to other kinds of water.

10: wastewater evaporative condensation system 100, 100a, 200: wastewater evaporative condensation system
110: first receiving tank 115: wastewater transfer port
120: clearance 125: diaphragm
130: second tank 140: connector
150, 150a: condensation tube 151, 151a: rotating shaft
152, 152a: transfer pipe 153, 153a: discharge port
154: microtube 154a: heat pipe
155, 155a: inlet 156, 156a: condenser tube body
157a: fourth tank 158: motor
159: belt 161, 162: pulley
163, 164: joint 160: transfer pump
170: blower unit 180: third receiving tank
185: purified water pipe 187: purified water pipe valve
190 blower connector

Claims (10)

A first accommodating tank 110 for storing the transferred waste water and transferring it to a post-treatment process;
A blowing unit 170 for supplying air;
A plurality of diaphragms 125 are provided for passing the wastewater transported from the first water tank 110 to receive air from the blower unit 170 to absorb heat from the wastewater to evaporate moisture. 120);
A second accommodating tank 130 accommodating wastewater that has passed through the clearance body 120;
A transfer pump 160 for transferring the wastewater contained in the second accommodation tank 130 through a connection pipe 140;
Condensation that absorbs and condenses heat from air containing moisture supplied from the tubular body 120 by waste water circulated through the plurality of microtubes 154 that are transported by the transfer pump 160 and arranged in a bundle form. Pipe 150; And
The third water tank 180 for receiving the water formed by the condensation of the air reaching the surface of the microtubes 154 of the condensation tube 150
Including;
Wastewater evaporative condensation apparatus, characterized in that the temperature of the wastewater in the clearance body 120 is deprived of heat by the air from the blower unit 170 and lower than before passing through the clearance body (120). The method of claim 1,
The diaphragm 125 is a condensation of the wastewater, characterized in that it has a bent shape to expand the contact area with the wastewater. The method of claim 1,
The diaphragm 125 is a condensation of the wastewater, characterized in that a plurality of holes are formed for extending the contact area with the wastewater. The method of claim 1,
The wastewater transported to the outside through the condensation tube 150 is heated to a predetermined temperature and then transferred to the first water tank 110 to be repeatedly processed by the wastewater evaporative condensation apparatus 100. Wastewater Evaporative Condensation Units. A first accommodating tank 110 for storing the transferred waste water and transferring it to a post-treatment process;
A blowing unit 170 for supplying air;
A plurality of diaphragms 125 for passing the wastewater transferred from the first water tank 110 are provided to receive air from the blower unit 170 to absorb heat from the wastewater to evaporate moisture ( 120);
A second accommodation tank 130 for receiving the wastewater that has passed through the clearance pipe 120;
A transfer pump 160 for transferring the wastewater contained in the second accommodation tank 130 through a connection pipe 140;
Contains water supplied from the tubular body 120 by waste water which is transported by the transfer pump 160 and circulated through the heat pipes 154a arranged in a bundle form in which a part of the fourth water tank 157a is incorporated. A condensation tube 150a that absorbs and condenses heat from the air; And
Third receiving tank 180 for receiving the water formed by the condensation of the air reaching the surface of the heat pipe 154a of the condensation tube 150a
Including;
Wastewater evaporative condensation apparatus, characterized in that the temperature of the wastewater in the clearance body 120 is deprived of heat by the air from the blower unit 170 and lower than before passing through the clearance body (120). The method of claim 5,
The diaphragm 125 is a condensation of the wastewater, characterized in that it has a bent shape to expand the contact area with the wastewater. The method of claim 5,
The diaphragm 125 is a condensation of the wastewater, characterized in that a plurality of holes are formed for extending the contact area with the wastewater. The method of claim 5,
Waste water transported to the outside through the condensation tube (150a) is heated to a predetermined temperature and then transferred to the first water tank 110 is characterized in that the waste water evaporative condensation apparatus 200 is repeatedly processed Wastewater Evaporative Condensation Units. 6. The method according to claim 1 or 5,
Rotating shafts 151 and 151a which are installed to penetrate up and down in the center of the condensation tube 150 and 150a to serve as the rotation centers of the condensation tube 150 and 150a.
Joints 163 and 164 coupled to the top and bottom of the rotation shafts 151 and 151a to rotate the condensation tubes 150 and 150a; And
A motor 158 which provides rotational force to the rotating shafts 151 and 151a through the pulleys 161 and 162 and the belt 159.
Waste water evaporative condensation device characterized in that it is further provided. Claims 1 and 5 and the wastewater evaporation condensation device of any one of claims 100, 200 comprising a plurality of,
The wastewater evaporative condensation apparatus 100 and 200 are connected to each other, and the wastewater evaporated from the condensation pipes 150 and 150a of the wastewater evaporative condensation apparatus 100 and 200 disposed at the front end is disposed at the rear end. Waste water evaporative condensation system, characterized in that the transfer to the first receiving tank (110) of the condenser (100) (200).

Images