KR20110080215A - Water furification plant adopting vacuum evaporation method - Google Patents

Abstract

PURPOSE: A vacuum evaporating type water purifying facility is provided to reduce cost required for installation and maintenance and simplify the structure of the facility. CONSTITUTION: An inlet(12) introduces raw water by being installed an evaporator body(11). A vapor outlet(14) is arranged at the upper side of the evaporator body. A heating unit(3) supplies hot water or steam to a heating coil(13) in order to heat the raw water in a evaporator(1). A vapor pipe(6) connects the evaporator and a condenser(2). A vacuum pump(4) is arranged in the vapor pipe and inhales vapor generated from the evaporator. A compressor(5) is arranged at the lower side of the vacuum pump and transfers the vapor from the vacuum pump to the condenser.

Description

Water Furification Plant Adopting Vacuum Evaporation Method

The present invention relates to a water purification facility that cleans contaminated rainwater or seawater and uses it as drinking water, and more particularly, to a water purification facility having a vacuum evaporator.

In recent years, droughts frequently occur due to global warming, and thus, many regions lack water for drinking water in coastal or island areas. And there are many water shortage countries all over the world. In such an area where water is scarce, seawater is desalted to produce drinking water, or rainwater is used as drinking water.

The reverse osmosis method using a semipermeable membrane and the ion exchange method using an ion exchange membrane are widely used as a method of desalination of sea water or water purification of contaminated water. The administration cost is very high. And even though these methods are expensive equipment, the desalination efficiency is very low.

As a method of desalination of seawater or purification of contaminated water, a multistage flush (MSF) evaporation method for producing fresh water by evaporating seawater is known. This method passes heated seawater (approximately 90 to 110 ° C) into a series of pipes at a pressure lower than atmospheric pressure, and the heated seawater evaporates to generate water vapor, and condenses the water vapor again to produce fresh water. to be.

However, since the desalination apparatus using the multi-stage flash evaporation method also needs to heat the seawater at about 90 to 110 ° C., it consumes a lot of energy and thus requires a high operating cost, and thus economical efficiency. And there is a problem that the maintenance of the maintenance is difficult because the seawater scale is deposited on the pipe in which the seawater flows and the pipe is frequently blocked.

As described above, there are many problems in the desalination or contaminated water purification device of the seawater, which requires breakthrough seawater desalination and contaminated water purification methods.

New seawater desalination and contaminated water purification methods require simple installation, low initial installation costs, and low risk of failure. And it should consume less energy and lower the cost of producing fresh water.

In the vacuum evaporation water purifying apparatus of the present invention, a vacuum pump is used to maintain the pressure inside the evaporator as a vacuum, and a heating device is provided inside the evaporator to evaporate the seawater or contaminated water to be treated while boiling. .

The water vapor evaporated from the evaporator was pressurized using a compressor to pressurize the condenser, and a heat exchanger was provided inside the condenser, thereby allowing the water vapor to easily condense.

A heating coil is provided for evaporation, and the heating coil circulates water or steam heated in a heating apparatus such as a boiler or a solar heater to easily boil the water to be treated by heating it to a predetermined temperature.

The vacuum evaporation water purification system of the present invention allows the water to boil and evaporate in a vacuum, thereby minimizing the energy consumed to desalination sea water or to clean up contaminated water, thereby lowering the production cost of fresh water or purified water. In addition, the vacuum evaporative water purification equipment of the present invention has a relatively simple configuration, and the initial installation cost is low, and there is less fear of failure, so the maintenance cost is low.

And the vacuum evaporation water purification equipment of the present invention can be constructed in a relatively small, it can be installed in a small village unit of the island area.

1 is an overall configuration diagram of the present invention.
2 is a state diagram of water near an operating point of the evaporator.

As shown in FIG. 1, the vacuum evaporation water purification system of the present invention includes an evaporator 1, a condenser 2, a heating device 3, a vacuum pump 4, a compressor 5, and a steam engine 6. It is configured to include.

The evaporator 1 is a place where contaminated water or seawater (hereinafter referred to as "raw water") to be purified or desalted and inflows into water vapor and evaporates into water vapor. , A heating coil 13 provided in the evaporator body 11, and a steam outlet 14 through which the vaporized water vapor is discharged.

 The evaporator body 11 is a pressure vessel, and when the inside is vacuumed, a pressure of up to 1 atmosphere is applied from the outside so that the material is made of stainless steel with high strength and strong corrosion resistance. The evaporator body 11 may reduce the heat loss by forming a heat insulating layer 15 on the outer surface of a heat insulating material, such as glass wool (Glass Wool), it is preferable to have a see-through window 16 to monitor the state inside the evaporator.

The heating coil 13 is arranged in a zigzag copper tube or aluminum tube with good thermal conductivity, so that the heat of hot water or steam flowing therein is well transmitted to the raw water.

The steam outlet 14 is provided at the upper end of the evaporator body 11, and the steam pipe 6 is connected thereto.

The condenser 2 is a function of condensing water vapor discharged by evaporation of raw water from the evaporator 1, and is connected to the evaporator 1 and the steam pipe 6. The condenser 2 is provided with a heat exchanger 22 inside the condenser body 21. Since the gas containing water vapor condenses as the pressure is higher and the temperature is lower, the water vapor evaporated in the evaporator 1 is pressurized by the compressor 5 and pressurized into the condenser 2. Therefore, the condenser body 21 is manufactured to withstand a certain pressure.

 The heat exchanger 22 has the same structure as a conventional radiator and is manufactured by attaching a plurality of heat radiating fins to a cooling water pipe. Cooling water having a low temperature flows into the cooling water pipe of the heat exchanger (22). The cooling water is first cooled in the cooling tower (23) and then secondly cooled to a very low temperature in the cooler (24), and circulated by a circulation pump (25). It can be produced in a structure to be. In addition, the cooling water may be cooled using only the cooling tower 23 or the cooler 24, or may use groundwater, deep sea water, and the like having a low temperature without using a separate cooling device.

The lower end of the condenser body 21 is provided with a water intake port 26, to take out the condensed condensed water to be used. If necessary, a filter 29 is further provided in the intake port 26, and the condensed water can be purified and used directly as drinking water. In addition, the upper end of the condenser body 21 is provided with an exhaust port 27 so that the condensed water vapor can be discharged to the outside, and the pressure gauge 28 is provided to check the pressure state inside the condenser 2. It is good to have. When the pressure inside the condenser 2 rises above a certain level, the exhaust port 27 may be opened to discharge water vapor to the outside.

The heating device 3 functions to heat the water (other liquids other than water), supply it to the heating coil 13 of the evaporator 1, and heat the evaporator 1. The heating device 3 may use a solar heater 31, or may use a boiler 32 using fossil fuels, or use the solar heater 31 and the boiler 32 together in the daytime when sunlight shines. By using hot air 31 and at night time when the sun is dark, the boiler 32 may be operated. Secondary heating of the water heated by the solar heater 31 to the boiler 32 at a higher temperature is performed. It can also be operated in a way that is used. The water can be heated in hot water or steam. The heating device 3 includes a plurality of valves 33 and a circulation pump 34 to circulate water.

The vacuum pump 4 is installed in the steam pipe 6 connecting the evaporator 1 and the condenser 2, forcibly discharging the vapor evaporated in the evaporator 1 to bring the evaporator 1 into a vacuum state. Keep it. As used herein, the term "vacuum state" does not mean a complete vacuum where the pressure is 0 atm, but a pressure state lower than 1 atm, which is atmospheric pressure.

FIG. 2 is a state curve of water near the triple point, where water boils at 100 ° C. to become water vapor at 1 atm, and condenses at 0 ° C. to form ice. However, if the pressure inside the evaporator 1 is lowered by the operating pressure of the operating point indicated in the graph, the water will boil at an operating temperature that is lower than 100 ° C. When the water reaches a boiling temperature, all liquid water in the evaporator 1 evaporates with water vapor, and thus the raw water evaporates rapidly.

While operating the vacuum pump 4 to lower the pressure in the evaporator 1, the raw water in the evaporator 1 is displayed at a constant temperature of 100 ° C. or lower by the heating device 3 (“boiling temperature” in the graph of FIG. 2). If the pressure inside the evaporator 1 falls below the boiling pressure at the temperature, the raw water boils and evaporates rapidly. If the vacuum pump 4 is capable of discharging all vapors that are evaporated, the raw water is continuously boiled and discharged into steam.

If the vacuum pump 4 is not capable of discharging all of the vaporized water vapor, if the pressure inside the evaporator 1 falls below the boiling pressure, steam is generated while boiling the raw water, and the vaporized water vapor 1 ) When the internal pressure rises above the boiling pressure, the raw water stops boiling and the generation of water vapor stops. Then, when the pressure inside the evaporator 1 again falls below the boiling pressure, water is boiled again and steam is generated. That is, in this case, the raw water is discharged as water vapor while repeating boiling at a constant time difference.

The compressor 5 is attached downstream of the vacuum pump 4 of the steam engine 6 to press the steam discharged from the vacuum pump 4 into the condenser 2.

It is preferable to attach the pressure gauge 61 upstream of the vacuum pump 4 to the steam engine 6 so that the vacuum state inside the evaporator 1 can be monitored.

The vacuum evaporative water purification equipment of the present invention can be used in purified water or seawater desalination plants that purify contaminated water or seawater to drinking water.

1 evaporator, 2 condenser, 3 heating device, 4 vacuum pump, 5 compressor,
6: steam engine,
11: evaporator body, 12: inlet, 13: heating coil, 14: steam outlet,
15: heat insulation layer, 16: viewing window
21 condenser body, 22 heat exchanger, 23 cooling tower, 24 cooler,
25: circulation pump, 26: water intake port, 27: exhaust port, 28: pressure gauge, 29: filter
31: solar heater, 32: boiler, 33: valve, 34: circulation pump.
61: pressure gauge.

Claims (4)

The evaporator body 11, which is a container for evaporating raw water, is provided in the evaporator body 11, an inlet 12 through which raw water is introduced, a heating coil 13 wound around the outside of the evaporator body 11, and the evaporator. Evaporator 1, consisting of a steam outlet 14 provided on the upper end of the body (11);
The heat exchanger is connected to the evaporator 1 and the water vapor pipe 6 to condense the water vapor evaporated and discharged from the evaporator 1. The heat exchanger is provided in the condenser body 21 and the condenser body 21. A condenser 2 composed of a gas 22 and a water intake port 26 for taking out the condensed water;
A heating device (3) connected to the heating coil (13) of the evaporator (1) by a pipe and supplying hot water or steam to the heating coil (13) for heating raw water in the evaporator (1);
A steam pipe (6) connecting the evaporator (1) and the condenser (2);
A vacuum pump (4) provided in the steam pipe (6) to suck water vapor generated in the evaporator (1);
And a compressor (5) which is provided downstream of the vacuum pump (4) of the steam pipe (6) and presses water vapor discharged from the vacuum pump (4) into the condenser (2);
Consists of a vacuum evaporative water purification equipment. The method of claim 1, wherein the evaporator 1
The evaporator body (11) is provided with a heat insulating layer (15) outside, to prevent the heat of the evaporator from being lost to the outside, vacuum evaporative water purification equipment. According to claim 1, wherein the vacuum evaporation water purification equipment,
Additionally having either one of a cooling tower 23 and a cooler 24, or further comprising both a cooling tower 23 and a cooler 24;
Cooling water flowing in the cooling water pipe of the heat exchanger (22), characterized in that for cooling and circulating, vacuum evaporative water purification equipment. The method according to claim 1, wherein the heating device (3)
Solar heater (31), boiler 32, and the vacuum evaporative water purification equipment, characterized in that any one of using the solar heater (31) and the boiler 32 together.

Images