JPH1028805A - Membrane degassing apparatus using sealing water in circulating state - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent corrosion in a sealing water circulating line in a membrane degassing apparatus using sealing water in a circulating state. SOLUTION: In the membrane degassing apparatus, a vacuum pump 9 is connected to supply raw water to a membrane module 7 divided into a passage side and a vacuum side by a gas-liquid separation membrane and dissolved air in raw water is sucked to the vacuum side. In this case, a sealing water circulating line 14 having a heat exchanger 8 performing the heat exchange with raw water sent to a membrane module 7 and a sealing water tank 10 provided with a water level adjusting means adjusting the water level in a tank is connected to the vacuum pump 9 to use sealing water so as to circulate the same. A part of circulating water returned to the sealing water tank 10 from the vacuum pump 9 is branched from the sealing water circulating line 14.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a membrane deaerator for circulating and using sealed water.

[0002]

2. Description of the Related Art Degassing is performed by using a membrane module divided into a flow path side and a decompression side by a gas-liquid separation membrane, and using a water-sealed vacuum pump connected to the decompression side of the membrane module to vacuum-dissolve dissolved gas in a liquid. Processing methods are widely used. As described in Japanese Utility Model Application Laid-Open No. 3-59004, the water sealed in the vacuum pump is circulated and reused to save water. However, since the circulating water returned from the vacuum pump to the water sealing tank is returned in a state of being mixed with the gas degassed by the membrane module, gases such as chlorine gas and carbon dioxide gas must be redissolved in the circulating water. Then, by repeating the circulation, the dissolved gas concentration increased, and a corrosive environment was created in the sealing water circulation line.

[0003]

SUMMARY OF THE INVENTION An object of the present invention is to provide a membrane deaerator that circulates and uses sealed water.
An object of the present invention is to prevent corrosion in a sealing water circulation line.

[0004]

A vacuum pump is connected,
A membrane deaerator that supplies raw water to a membrane module divided into a flow path side and a decompression side by a gas-liquid separation membrane, and sucks dissolved gas in the raw water to a decompression side. A membrane that connects a heat exchanger that performs heat exchange with the raw water being sent and a sealing water circulation line that has a sealing water tank provided with a water level adjustment unit that adjusts the water level in the tank, and uses the sealing water in circulation. In the deaerator, a part of the circulating water returned from the vacuum pump to the water sealing tank is branched off from the water sealing circulation line and drained. During the operation of the vacuum pump, a small amount of sealed water is drained and fresh water is supplied to prevent the dissolved gas concentration in the sealed water from increasing.

[0005]

DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a flow sheet showing an outline of a membrane deaerator in which the inside of a container is partitioned into a flow path side and a decompression side by a gas-liquid separation membrane, and deaeration is performed by a membrane module 7 having a vacuum pump 9 connected to the decompression side. . A water level detecting device 2 and a raw water supply control valve 3 are provided in a deaerated water tank 1 for storing raw water passing through the deaerator and deaerated water subjected to a deaeration process, and a signal from the water level detecting device 2 is provided. By opening and closing the raw water supply control valve 3, the water level in the deaerated water tank is adjusted to a constant height. The raw water stored in the deaerated water tank 1 is transferred to the membrane module 7
A raw water inlet valve 4, a circulation pump 5, a pre-filter 6, a heat exchanger 8, and a membrane module 7 are provided in this order from the deaerated water tank 1 side. The piping is connected so that steam can be sent to both the degassed water usage side and the degassed water tank. The vacuum pump 9 is connected to the reduced pressure side of the membrane module 7 by a vacuum line 17, and a vacuum solenoid valve 18 is provided in the middle of the vacuum line 17. Between the pre-filter 6 and the heat exchanger 8 in the deaeration line 11, the water supply line 1 branched from the deaeration line 11
2, the water supply line 12 is connected to the water supply tank 10, and a ball tap 13 for opening and closing the valve according to the water level in the water supply tank 10 is provided in the water supply line 12.
Further, by providing an overflow pipe 15 for draining when the water level becomes higher than the overflow opening portion 19 in the water sealing tank 10, the water level in the water sealing tank 10 is kept constant. The sealed water stored in the sealed water tank 10 is sent to the heat exchanger 8 by the sealed water circulation line 14,
After the heat exchange with the water in the deaeration line 11 being sent to the membrane module 7, the water is sent to the vacuum pump 9 and used as water sealing. The used sealing water is returned into the sealing tank 10, and a circulating water discharge port 16 is provided near the tip of the sealing circulation line 14 provided in the sealing tank 10 at a portion directly above the overflow opening 19. Water sealing line 14
Is returned to the overflow pipe 15 from the circulating water discharge port 16.

When performing the deaeration process, first, raw water is stored in a deaerated water tank 1 through a raw water supply control valve 3. The raw water stored in the deaerated water tank 1 opens the raw water inlet valve 4,
By operating the circulation pump 5, the water is sent through the deaeration line 11, filtered by the prefilter 6, and passed through the heat exchanger 8 to the membrane module 7. In the membrane module 7, the decompression side is evacuated by the vacuum pump 9, and when raw water is passed through the flow path side, dissolved gas contained in the raw water is sucked to the decompression side through the gas-liquid separation membrane. The degassed water is sent to the degassed water use side. If the supply amount of the degassed water exceeds the demand, the degassed water is returned to the degassed water tank 1.

[0007] The water used in the vacuum pump 9 for evacuating the reduced pressure side of the membrane module is used by circulating the water in a water sealing tank 10 in order to prevent an increase in the water sealing temperature due to circulating use. Then, it is sent to the vacuum pump 9 after being cooled in the heat exchanger 8. In the vacuum pump 9, the gas in the membrane module 7 is sucked by the sealed water sent through the sealed water circulation line 14,
The gas and water from the membrane module 7 are sent to a water sealing tank 10. Part of the sealed water returned to the sealed tank 10 is sent from the circulating water drain port 16 to the overflow opening 19, and when the vacuum pump 9 is operated, part of the sealed water is always drained. Further, the gas sent to the water sealing tank 10 is also exhausted through the overflow pipe 15. When the water level in the water sealing tank 10 is reduced by draining the water, the ball tap 13 is opened and fresh water is supplied through the water supply line 12.

[0008]

By implementing the present invention, a very small amount of sealed water can be drained at all times when the vacuum pump is operating, and by performing drainage and replenishment, the dissolved gas concentration in the sealed water can be prevented from rising and the sealing water circulation line is corroded. Environment can be prevented. Also,
Since the drainage of the sealed water does not occur when the vacuum pump is stopped, the water is not wastefully drained.

[Brief description of the drawings]

FIG. 1 is a flowchart of an embodiment of the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Deaerated water tank 2 Water level detection device 3 Raw water supply control valve 4 Raw water inlet valve 5 Circulation pump 6 Prefilter 7 Membrane module 8 Heat exchanger 9 Vacuum pump 10 Water sealing tank 11 Deaeration line 12 Sealing replenishment line 13 Ball tap 14 Seal water circulation line 15 Overflow pipe 16 Circulating water drain 17 Vacuum line 18 Vacuum solenoid valve 19 Overflow opening

Claims (2)

[Claims] 1. A membrane deaerator connected to a vacuum pump, supplying raw water to a membrane module whose interior is divided into a flow path side and a decompression side by a gas-liquid separation membrane, and sucking dissolved gas in the raw water to the decompression side. The vacuum pump is connected to a water-sealing line having a heat-exchanger for performing heat exchange between raw water sent to the membrane module and a water-sealing tank provided with a water-level adjusting means for adjusting the water level in the tank. In the membrane deaerator using the sealed water in circulation, a part of the circulated water returned from the vacuum pump to the sealed tank is branched from the sealed water circulation line and provided with a circulating water discharge port. A membrane deaerator that circulates and uses sealed water. 2. The membrane deaerator according to claim 1, wherein the water discharged from the circulating water drain is sent to an overflow pipe provided in the water sealing tank. Membrane deaerator that circulates and uses sealed water.