JPH10331798A - Ejector - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent impurities containing corrosive material from being concentrated and adhered by providing a jacket for cooling at the outer circumference of a diffuser, thereby bringing the inner wall surface of the diffuser wet at all times. SOLUTION: An ejector 11 is used for the extruction of air in a condenser in a geothermal power generation plant, and geothermal steam is bown into the ejector 11 from a steam nozzle 12 inserted in the axial direction of a diffuser 15 and expanded at the diffuser 15 to reduce the pressure, and gas in the condenser is forcibly sucked in to a flange 14 on the side of cooling tower from a flange on the side of the condenser to thereby decrease the pressure in the condenser. To the ejector 11 a water cooling type jacket 17 is mounted on the outer periphery of the diffuser 15, and cooling water is made to flow in the jacket 15 in order to decrease the temperature of the inner wall surface of the diffuser 15 more than that of saturation steam pressure in geothermal steam, thereby making the inner wall surface of the diffuser part 15 wet at all times.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an ejector applied to a chemical plant in addition to the extraction of a condenser in a geothermal power plant.

[0002]

2. Description of the Related Art FIG. 3 is an explanatory view of a conventional ejector used for bleeding a condenser in a geothermal power plant. In the figure, in a geothermal power plant, an ejector using geothermal steam may be installed in order to decompress a condenser.

The ejector 01 in the geothermal plant is depressurized by blowing geothermal steam 06 from a steam nozzle 02 inserted in the ejector 01 in the axial direction of the diffuser unit 05 and expanding the diffuser in the diffuser unit 05.
The gas 07 in the condenser (not shown) is forcibly sucked from the condenser side flange portion 03 to the cooling tower side flange portion 04 to reduce the pressure inside the condenser.

[0004]

In the conventional ejector described above, heat is generated when the geothermal steam 06 blown from the steam nozzle 02 into the diffuser portion 05 expands rapidly. Due to the generated heat, the geothermal steam 06 is dried, and impurities including corrosive substances such as salt contained in the geothermal steam 06 and the gas 07 in the condenser are concentrated and adhere to the inner wall surface of the diffuser unit 05. In some cases, the corrosive substance may significantly accelerate the corrosion of the diffuser portion 05 or cause the diffuser portion 05 to crack.

[0005]

SUMMARY OF THE INVENTION An ejector according to the present invention has an object to solve the above-mentioned problems. An ejector in which the pressure is reduced by blowing steam from a steam nozzle inserted in an axial direction of a diffuser portion to the diffuser portion is provided. A cooling jacket is provided on the outer periphery of the diffuser portion.

As described above, the cooling jacket is provided on the outer periphery of the diffuser portion, cooling water or the like is flowed through the jacket to cool the wall surface of the diffuser portion, and the temperature of the wall surface of the diffuser portion is controlled by the steam flowing through the inside of the diffuser portion. By cooling below the temperature of the saturated vapor pressure of
Condensed water is constantly generated on the inner wall of the diffuser. Thereby, the inner wall surface of the diffuser portion is always in a wet state, and it is possible to prevent impurities including corrosive substances from concentrating and adhering to the inner wall surface of the diffuser portion.

Further, the ejector according to the present invention is provided with an injection nozzle for injecting a fluid into the diffuser portion of the ejector which performs pressure reduction by blowing steam into the diffuser portion from a steam nozzle inserted in the axial direction of the diffuser portion. I have.

[0008] Thus, the injection nozzle is provided in the ejector,
By continuously or intermittently injecting the fluid from the injection nozzle to the diffuser and dispersing the water, the scale attached to the inner wall surface can be washed with the injected fluid, and the vapor in the diffuser can be moistened. It is possible to prevent the impurities including the corrosive substance from concentrating and adhering to the inner wall surface of the diffuser portion by keeping the state, thereby suppressing the drying.

[0009]

FIG. 1 is an explanatory view of an ejector according to an embodiment of the present invention, and FIG. 2 is an explanatory view of an ejector according to another embodiment of the present invention. In the figure, the ejector according to these embodiments can be used not only for the extraction of a condenser in a geothermal power plant but also for a chemical plant and the like, and the reference numeral 11 in the figure is an ejector, and 12 is a steam nozzle of the ejector 11. , 13 is a flange portion on the condenser side of the ejector 11, 14 is a flange portion on the cooling tower side of the ejector 11, 15 is a diffuser portion of the ejector 11, 16 is a water injection nozzle attached to the diffuser portion 15 of the ejector 11, Reference numeral 17 denotes a water-cooled jacket attached to the outer periphery of the diffuser 15 of the ejector 11.

In FIG. 1, an ejector 11 according to the present embodiment is used for bleeding a condenser in a geothermal power plant, and a steam nozzle 12 inserted in the ejector 11 in an axial direction of a diffuser portion 15 is used to output geothermal heat. The steam is blown and expanded by the diffuser portion 15 to reduce the pressure, and the gas in the condenser (not shown) is forcibly sucked from the condenser side flange portion 13 to the cooling tower side flange portion 14 to thereby reduce the pressure inside the condenser. Is reduced in pressure.

The ejector is made of SUS316L,
As shown in the figure, a water-cooled jacket 17 is attached to the outer periphery of the diffuser section 15 in order to prevent the geothermal steam from drying, and the water-cooled jacket 17 causes the inner wall surface of the diffuser section 15 to pass through the diffuser section 15 through geothermal heat. By cooling the vapor at a temperature lower than the saturated vapor pressure of the steam, the inner wall surface of the diffuser unit 15 is always wet, and impurities including corrosive substances are concentrated and adhere to the inner wall surface of the diffuser unit 15. Preventing.

In geothermal steam, impurities such as chlorine ions contain N
Although about 20 to 30 ppm is mixed as aCl,
8 kgf / cm pressure at Zecta^TwoAbout geothermal steam
Blows into the ejector 11 from the nozzle 12 and diffuses
0.5 kgf / cm inside the part 15 ^TwoDecompress to about
To suck the gas in the condenser. At this time, geothermal steam
Temperature rises to about 200 ° C and becomes dry.
Water-cooled jacket 1 attached to outer periphery of fuser section 15
Flowing the cooling water through the inside of the diffuser part 15
The temperature of the wall surface can be reduced to about 50 ° C.

In a conventional ejector, heat is generated when geothermal steam blown from a steam nozzle into a diffuser portion expands rapidly. The generated heat dries the geothermal steam, condensing impurities including corrosive substances such as salt contained in the geothermal steam and the gas in the condenser, and adheres to the inner wall surface of the diffuser, causing As a result, corrosion of the diffuser portion may be remarkably accelerated or the diffuser portion may be cracked.

On the other hand, in the present ejector, a water-cooled jacket 17 is attached to the outer periphery of the diffuser section 15, and cooling water is caused to flow through the water-cooled jacket 17 so that the temperature on the inner wall surface of the diffuser section 15 is reduced by the geothermal steam Condensed water is constantly generated on the inner wall surface of the diffuser portion 15 at a temperature lower than the temperature at the saturated vapor pressure, so that the geothermal steam in the diffuser portion 15 can be made wet.

When a comparison is made after venting geothermal steam to an ejector installed for decompressing the inside of a condenser in a geothermal power plant for about three months, the conventional ejector without the water-cooled jacket 15 shows that chlorine ions that are most affected corrosion attached considerable scale on the inner wall surface of the diffuser section (Cl ^-) concentration of about 0.2%
Concentrate to a degree. In contrast, the water-cooled jacket 1
In the case where the inner wall surface of the diffuser portion 15 is maintained at about 50 ° C. by adopting the structure provided with the inner wall 7, the amount of scale adhering to the inner wall surface is extremely small, and the concentration of chlorine ions (Cl ⁻ ) is reduced to the ordinary geothermal temperature It remained at a level of several tens of ppm which was almost the same as in steam. Thus, it was confirmed that the provision of the water-cooled jacket 17 prevented the impurities including corrosive substances from being concentrated and attached to the inner wall surface of the diffuser 15.

In FIG. 2, an ejector 11 according to the present embodiment is used for bleeding a condenser in a geothermal power plant, and a steam nozzle 12 inserted into the ejector 11 in an axial direction of a diffuser section 15 is used to extract geothermal energy. The steam is blown and expanded by the diffuser portion 15 to reduce the pressure, and the gas in the condenser (not shown) is forcibly sucked from the condenser side flange portion 13 to the cooling tower side flange portion 14 to thereby reduce the pressure inside the condenser. Is reduced in pressure.

Also, this ejector is made of SUS316L,
As shown in the figure, the geothermal steam is dried to prevent impurities including corrosive substances from concentrating and adhering to the inner wall surface of the diffuser section 15 and to remove the attached scale at three places of the diffuser section 15. An injection nozzle 16 for dispersing moisture into the diffuser section 15 is attached. By injecting 1 kgf of water per minute from each injection nozzle 16, the geothermal steam in the diffuser section 15 can be made wet. Has become.

In geothermal steam, impurities such as chlorine ions are N
Although about 20 to 30 ppm is mixed as aCl,
8 kgf / cm pressure at Zecta^TwoAbout geothermal steam
Blows into the ejector 11 from the nozzle 12 and diffuses
0.5 kgf / cm inside the part 15 ^TwoDecompress to about
To suck the gas in the condenser. At this time, geothermal steam
Temperature rises to about 200 ° C and becomes dry.
Each injection nozzle 16 attached to three places of the fuser part 15
1kgf of water per minute into the diffuser part 15
By entering, the geothermal in the diffuser part 15
The steam can be moistened.

In the conventional ejector, heat is generated when the geothermal steam blown from the steam nozzle into the diffuser portion expands rapidly. The generated heat dries the geothermal steam, condensing impurities including corrosive substances such as salt contained in the geothermal steam and the gas in the condenser, and adheres to the inner wall surface of the diffuser, causing As a result, corrosion of the diffuser portion may be remarkably accelerated or the diffuser portion may be cracked.

On the other hand, in the present ejector, an injection nozzle 16 for injecting moisture into the diffuser section 15 is provided in the diffuser section 15, and the injection nozzle 16 continuously or intermittently enters the diffuser section 15 from the injection nozzle 16. Spraying water to diffuser part 1
5 to keep the inner surface of the diffuser portion 15 wet by making the geothermal steam wet, to prevent impurities including corrosive substances from concentrating and adhering to the inner wall surface of the diffuser portion 15, and Fifteen
Even if the scale adheres to the inner wall surface, the attached scale can be washed away. The injection nozzle 16 to be installed is 1 to
About three places are suitable, and the amount of water sprayed from each injection nozzle 16 is suitably about 1 to 5 kg / min. However, when the amount of adhered scale is large, it can be further increased. Further, even if water is injected continuously or intermittently, the effect is hardly changed.

A comparison was made after venting geothermal steam for about three months to an ejector installed for depressurizing the inside of a condenser in a geothermal power plant. In this case, a considerable scale adheres to the inner wall surface of the diffuser portion, and the concentration of chlorine ion (Cl ⁻ ), which has the greatest influence on corrosion, is about 0.2.
Concentrate to about%. On the other hand, when the structure in which the injection nozzle 16 for injecting and spraying water into the diffuser unit 15 is adopted and the geothermal steam in the diffuser unit 15 is kept wet, the amount of scale adhering to the inner wall surface is reduced. significantly less, chloride ion - remained the concentration of almost the same number does 10ppm normal geothermal steam level ^(Cl). By providing the diffuser unit 15 with the injection nozzle 16 for injecting and spraying water, impurities including corrosive substances are concentrated and the diffuser unit 1 is inflated.
The effect of preventing adhesion to the inner wall surface of No. 5 was confirmed.

[0022]

The ejector according to the present invention is constructed as described above. A cooling jacket is provided on the outer periphery of the diffuser, and cooling water or the like is flowed through the jacket to cool the wall of the diffuser. By cooling the temperature of the wall surface of the unit to a temperature equal to or lower than the temperature of the saturated vapor pressure of the steam flowing inside the diffuser unit, dew water is constantly generated on the inner wall surface of the diffuser unit. As a result, the inner wall surface of the diffuser portion is constantly wet, and it is possible to prevent impurities including corrosive substances from being concentrated and attached to the inner wall surface of the diffuser portion,
Corrosive substances do not significantly accelerate the corrosion of the diffuser portion and do not crack the diffuser portion.

The ejector according to the present invention is configured as described above. The ejector is provided with an injection nozzle, and the fluid is sprayed from the injection nozzle to the diffuser portion continuously or intermittently by injecting a fluid. As a result, the scale attached to the inner wall surface can be washed with the injected fluid, and the vapor in the diffuser portion is kept wet to suppress drying, and impurities including corrosive substances are concentrated on the inner wall surface of the diffuser portion. Therefore, it is possible to prevent the corrosive substance from significantly accelerating the corrosion of the diffuser portion and prevent the diffuser portion from being cracked.

[Brief description of the drawings]

FIG. 1 is a sectional view of an ejector according to an embodiment of the present invention.

FIG. 2A is a sectional view of an ejector according to another embodiment of the present invention, and FIG.
FIG.

FIG. 3 is a sectional view of a conventional ejector.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 11 Ejector 12 Steam nozzle 13 Flange part 14 Flange part 15 Diffuser part 16 Injection nozzle 17 Water-cooled jacket

Claims (2)

[Claims] 1. An ejector for reducing pressure by blowing steam into a diffuser portion from a steam nozzle inserted in an axial direction of the diffuser portion, wherein a cooling jacket is provided on an outer periphery of the diffuser portion. . 2. An ejector for depressurizing by blowing steam into said diffuser portion from a steam nozzle inserted in an axial direction of said diffuser portion, wherein an ejector nozzle for injecting a fluid into said diffuser portion is provided. .