JP3929874B2 - High-pressure single-fluid atomizing nozzle for increased output of gas turbines - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a high-pressure one-fluid atomizing nozzle for gas turbine increase output that sprays fine water droplets during intake into a compressor of a gas turbine power generation system, lowers temperature to increase intake density, and increases power generation output. .
[0002]
[Prior art]
In recent years, combined cycle power generation systems using gas turbines have been widely adopted from the viewpoint of overall thermal efficiency. However, the power generation system using such a gas turbine tends to have a lower output due to an increase in intake air temperature at a high temperature such as summer. In order to deal with the effects of such a rise in intake air temperature, spraying and increasing the amount of fine water droplets on the intake air upstream of the compressor suppresses the rise in intake air temperature due to the evaporation heat and further increases the mass flow rate. A method of obtaining an increased output is employed.
[0003]
There are the following proposals in the literature for output recovery and output improvement in summer.
First, as a one-fluid (single water) atomizing nozzle, Japanese Patent Application Laid-Open No. 9-303160 and Japanese Patent Application Laid-Open No. 8-284585 disclose that water is sprayed at the discharge pressure of a water pump into an intake chamber upstream of a compressor. The structure which installed the 1 fluid water single atomization nozzle to perform is described. Japanese Patent Application Laid-Open No. 11-93692 describes a system using an air cooler using a heat exchanger and a one-fluid atomizing nozzle. As a one-fluid nozzle for spraying water alone, Japanese Patent Application Laid-Open No. 10-238365 has a configuration in which a one-fluid atomizing nozzle having a spray structure using a gas flow is arranged in a pipe for the purpose of increasing the gas flow. Are listed.
[0004]
On the other hand, at present, it is difficult to atomize a large amount of water with a single fluid atomizing nozzle using water alone (the water droplet diameter is set to about 20 μm or less on the Sauter average), and therefore, air is extracted from the compressor. In many cases, a two-fluid atomizing nozzle using air is employed. As those using the two-fluid (water-air) atomizing nozzle, Japanese Patent Application Laid-Open No. 9-236024, Japanese Patent Application Laid-Open No. 11-13486, Japanese Patent Application Laid-Open No. 11-72029, etc. A configuration is described in which a two-fluid spray nozzle is provided that atomizes and sprays water with the discharge pressure of the water pump and the air at the outlet of the compressor. Further, Japanese Patent Laid-Open No. 9-94487 discloses that a small amount of high-pressure water is ejected from one hole for indoor / outdoor space production or indoor / outdoor humidification, although it is not intake air humidification of a gas turbine power generation system. A structure in which a flat inclined surface is made to collide is described.
[0005]
[Patent Document 1]
JP-A-9-303160
[Patent Document 2]
Japanese Patent Laid-Open No. 8-284485
[Patent Document 3]
Japanese Patent Laid-Open No. 11-93692
[Patent Document 4]
Japanese Patent Laid-Open No. 10-238365
[Patent Document 5]
Japanese Patent Laid-Open No. 9-236024
[Patent Document 6]
Japanese Patent Laid-Open No. 11-13486
[Patent Document 7]
Japanese Patent Laid-Open No. 11-72029
[Patent Document 8]
JP-A-9-94487
[0006]
[Problems to be solved by the invention]
In order to suppress the gas turbine output decrease due to the rise in intake air temperature in summer, the following issues are encountered when spraying fine water droplets on the intake air upstream of the compressor using an atomizing nozzle. It is done.
[0007]
First, the purpose of using the atomizing nozzle is to prevent a decrease in turbine output in summer and the like, and system loss due to the use of the atomizing nozzle must be avoided as much as possible. Therefore, the first problem is to minimize the system loss due to the provision of the atomizing nozzle.
[0008]
Secondly, since the nozzle is installed in a limited space in the air chamber arranged at the compressor inlet, when the spray amount of the nozzle is small, in order to ensure the desired spray amount in total, The number of installations increases accordingly. As a result, not only is the cost high, but there is a possibility that air flow resistance will be generated and the amount of air flowing into the compressor will be reduced. Therefore, the second problem is to make it possible to atomize as much water as possible into small water droplets with a small size.
[0009]
Third, if the water droplet diameter is large, the airflow flowing into the compressor will not be satisfactorily applied, and if the water droplets flow into the compressor with large water droplets, erosion at the compressor blades will be caused. Furthermore, in this case, the evaporation in the compressor is delayed, the effect of vaporization latent heat is reduced, and the contribution to improving the thermal efficiency is reduced. That is, the third problem is that the size of the sprayed water droplets is 20 μm or less in terms of the Sauter average diameter. The Sauter average particle size is a general index representing the sprayed water particle size measured by the laser measurement method, and is usually used as the water droplet size.
[0010]
In response to the above problems, first, in the two-fluid atomizing nozzle, for example, when spraying an amount of 42 liters of water per hour, the amount of air used is 350 NL / min. The amount of water sprayed in the air chamber upstream of the compressor is about 1% in terms of the weight ratio of the spray water to the intake air. Accordingly, although the amount of water sprayed by the nozzles depends on the capacity of the gas turbine, a considerably large amount of water is required, and spraying is performed simultaneously using a large number of nozzles. For example, in a 100 megawatt gas turbine power generation system, when a two-fluid atomizing nozzle with a sprayed water amount of 42 liters per hour is used, about 200 nozzles are required and the amount of air used is 70 Nm.³/ Min. The loss caused by extracting the air used at this time from the compressor corresponds to about 2% of the output, which is a large output loss of about 2 megawatts in terms of electrical output. Therefore, a two-fluid atomizing nozzle for increasing the output of a gas turbine currently used and a two-fluid atomizing nozzle described in JP-A-9-236024, JP-A-11-13486, and JP-A-11-72029 Then, the first problem cannot be solved.
[0011]
On the other hand, JP-A-9-303160, JP-A-8-284665, and JP-A-11-93692 disclose a one-fluid atomizing nozzle, but there is no disclosure of a specific nozzle structure. It cannot be said that the second and third problems are achieved.
[0012]
Also, the one-fluid atomizing nozzle described in JP-A-10-238365 cannot achieve the second and third problems. That is, it is difficult to realize a large amount of fine water droplet spraying with the single-fluid atomizing nozzle having a spray structure described in Japanese Patent Laid-Open No. 10-238365, and the water droplet size is reduced to 20 μm or less in terms of the Sauter average diameter. It is also difficult to do.
[0013]
Further, the one-fluid atomizing nozzle described in the above-mentioned Japanese Patent Application Laid-Open No. 9-94487 is not for increasing the output of a gas turbine. Even if this nozzle is applied for increasing the output of a gas turbine power generation system, a single spray atomizing nozzle is used. Since the amount is small, the required number of nozzles is increased, resulting in problems such as an increase in equipment cost and a decrease in the amount of air flowing into the compressor, and the second problem cannot be solved. In addition, when the nozzle is used in the intake air flow of a compressor having a wind speed of about 5 m / s in the air chamber, the air flow causes the support member (J-shaped bending pin) on the downstream side of the collision surface. The splashed water droplets hit each other, and the water droplets adhere to each other, resulting in an increase in water droplets having a Sauter average diameter of more than 20 μm. That is, as a result, the third problem cannot be solved.
[0014]
An object of the present invention is to provide a high-pressure one-fluid atomizing nozzle for gas turbine increase output capable of atomizing a large amount of water into fine water droplets with a small size and minimal system loss.
[0015]
[Means for Solving the Problems]
  (1) AboveNoteIn order to achieve the objective, the present invention is installed in a gas turbine power generation system that rotates a turbine by combustion gas generated by burning intake air from a compressor together with fuel and converts the rotational energy of the turbine into electric energy. In a high-pressure one-fluid atomizing nozzle for increasing output of a gas turbine that sprays liquid during intake of air into the compressor and lowers intake air temperature of the compressor and increases intake air density, a liquid introduction pipe portion that introduces high-pressure liquid; , A plurality of orifices for injecting high-pressure liquid from the liquid introduction pipe portion as jet streams in the axial direction, and a plurality of orifices that interfere with the jet streams ejected from the orifices and atomize the colliding jet streams to form fine droplets A gap through which the fine droplets pass between the nozzle portion having the target and the target so as not to interfere with the atomized fine droplets And a cylindrical cover portion that covers the circumferential direction of the nozzle portion as via integrally constituted formedThe number of the orifices and the corresponding targets corresponding to the required spray flow rate are provided, and the jet pressure of the jet flow is adjusted within a range of 5 MPa or more..
[0016]
In the present invention, each of the plurality of targets has an inclined surface inclined toward the tip of the target, and the jet flow of high-pressure liquid ejected from the orifice collides with the target inclined surface, so that the jet flow instantaneously becomes the Sauter average. The fine droplets that are atomized into fine droplets of 20 μm or less and bounce off the inclined surface are sprayed continuously from between the targets and the cover portion toward the outside of the nozzle. And in this invention, size reduction is achieved by connecting and integrating said liquid introduction pipe | tube part, a nozzle part, and a cover part by welding etc., for example.
[0017]
Further, even when the atomizing nozzle is installed in a narrow installation space such as an intake pipe, the atomizing nozzle includes the cover portion, so the atomizing nozzle is installed in a mounting hole drilled in the intake pipe. By inserting the tip and welding the cover to the intake pipe with the nozzle tip slightly facing the intake pipe, there is almost no flow resistance in the intake pipe at the tip of the nozzle, causing pressure loss of the intake. It can be suppressed as much as possible. Further, since the nozzle itself is miniaturized by adopting an integrated structure, the pressure loss is very small because the flow path resistance is small even if it is installed without taking up installation space. Furthermore, when considering the system loss of the gas turbine power generation system, since the present invention is a one-fluid atomizing nozzle, the system loss is extremely small compared to a two-fluid atomizing nozzle that requires extraction from the compressor. can do.
[0018]
  In addition, since there are a plurality of orifices and targets corresponding thereto, a large amount of spray water can be secured per nozzle as compared to the case where there is only one orifice and one target, and the number of installations is small. Even a large amount of water can be sprayed with fine water droplets.
  In addition, the inventors of the present application have found that in the atomization nozzle of the present invention, when the injection pressure is 5 MPa or more, the Sauter average water droplet diameter is approximately 20 μm or less. Therefore, according to the present invention, the spray flow rate can be easily adjusted while maintaining fine water droplets.
  (2) In order to achieve the above object, the present invention also provides a gas turbine that rotates a turbine by combustion gas generated by burning intake air from a compressor together with fuel, and converts the rotational energy of the turbine into electric energy. A high-pressure liquid is introduced into a high-pressure one-fluid atomizing nozzle for gas turbine increase output that is installed in a power generation system and sprays liquid during intake of the compressor to lower the intake temperature of the compressor and increase the intake density. A liquid introduction pipe section, a plurality of orifices that inject high-pressure liquid from the liquid introduction pipe section as jet streams in the axial direction, and the jet streams ejected from the orifices, respectively. In order to prevent interference with the atomized fine liquid droplets and the nozzle part having a plurality of targets to be liquid droplets, the fine liquid And a cylindrical cover portion covering the circumferential direction of the nozzle portion so as to pass through a gap through which the nozzles pass, and the tip portions of the plurality of targets with which the jet flow collides are directed toward the tips. The inclined surface is inclined in the jet direction of the jet flow, and the inclined surface of the target is flat mirror-finished.
  In the case of the present invention, since the inclined surface of the target is mirror-finished flat, the thickness of the liquid film can be reduced and atomization into fine water droplets is promoted.
  (3) In order to achieve the above object, the present invention also provides a gas turbine for rotating a turbine by combustion gas generated by burning intake air from a compressor together with fuel, and converting the rotational energy of the turbine into electric energy. A high-pressure liquid is introduced into a high-pressure one-fluid atomizing nozzle for gas turbine increase output that is installed in a power generation system and sprays liquid during intake of the compressor to lower the intake temperature of the compressor and increase the intake density. A liquid introduction pipe section, a plurality of orifices that inject high-pressure liquid from the liquid introduction pipe section as jet streams in the axial direction, and the jet streams ejected from the orifices, respectively. In order to prevent interference with the atomized fine liquid droplets and the nozzle part having a plurality of targets to be liquid droplets, the fine liquid And a cylindrical cover portion covering the circumferential direction of the nozzle portion so as to pass through a gap through which the nozzles pass, and the tip portions of the plurality of targets with which the jet flow collides are directed toward the tips. The inclined surface is inclined in the jet direction of the jet flow, and the inclined surface of the target has an inclination angle corresponding to a required spray angle of fine droplets.
  In the case of the present invention, since the inclined surface of the target has an inclination angle corresponding to the required spray angle of fine droplets, the spray range can be arbitrarily adjusted.
[0019]
  (4In (1) above, preferably, the tip portions of the plurality of targets with which the high-pressure liquid collides form an inclined surface inclined in the jet direction of the jet flow toward the tips.
[0020]
  (5) Above (2)To any of (4)Preferably, the tip end portion of the inclined surface is formed in a substantially semicircular shape, and the jet flow collides with a substantially central position of the substantially semicircular tip portion.
[0021]
According to the present invention, since the collision position of the jet flow on the inclined surface is substantially the center position of the semicircular target tip, the distance from the collision to the tearing of the liquid film becomes almost uniform, and the high pressure liquid is It can be atomized almost uniformly. At this time, since the cover portion is provided in the present invention, the jet flow from the orifice is covered even if the jet flow must be installed so that the jet flow direction is substantially perpendicular to the flow of the intake air. Since it is protected by the portion, the jet flow can be accurately collided with the substantially central position of the tip of the target without being influenced by the flow of the intake air, and a stable spray state can always be ensured.
[0028]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1A is an axial sectional view of a high-pressure one-fluid atomizing nozzle for increasing output of a gas turbine according to the first embodiment of the present invention, and FIG. 1B is a view from the right side of FIG. FIG. 1A and 1B, a high-pressure one-fluid atomizing nozzle 100 according to the present embodiment includes a liquid introduction pipe section 2 that guides the high-pressure water 1 and the inside of the tip of the liquid introduction pipe section 2. And a cylindrical cover portion 4 fitted to the outside of the tip end of the liquid introduction tube portion 2 so as to surround the nozzle portion 3 from the circumferential direction. These liquid introduction tube portions 2, the nozzle part 3 and the cover part 4 are integrated by welding the nozzle part 3 and the cover part 4 to the liquid introduction pipe part 2 together.
[0029]
The liquid introduction pipe section 2 is connected to a pipe (not shown), and the high-pressure water 1 from the pipe is guided to the nozzle section 3. At this time, the connection structure between the pipe and the liquid introduction pipe portion 2 is not particularly limited. For example, a structure in which a screw portion is provided to connect each other via a nipple or the like may be used. It is good also as a connection structure via a coupling component. It is also conceivable to provide a filter for removing dust in the high-pressure water 1 in the liquid introduction pipe portion 2.
[0030]
FIG. 2 is a perspective view illustrating a schematic configuration of the nozzle unit 3.
As shown in FIG. 2 and FIG. 1A and FIG. 1B, the nozzle portion 3 is provided at the tip of the orifice portion 5 fitted to the liquid introduction tube portion 2 and the tip of the high-pressure one-fluid atomizing nozzle 100. It is comprised by the target part 6 located, and the axial part 7 which connects these orifice parts 5 and the target part 6. FIG.
[0031]
A plurality of (four in this example) axial directions of small-diameter orifices 8 are formed in the orifice portion 5 at substantially equal pitches in the circumferential direction. However, each orifice 8 needs to be finished with a machining accuracy as high as possible in order to make the jet stream 9 to be injected into a thin thread shape, and is preferably finished by, for example, electric discharge machining. Further, each orifice 8 is provided with an introduction water rectification unit 10 having an enlarged diameter on the upstream side facing the liquid introduction pipe unit 2. The set length of the introduced water rectifying unit 10 is preferably long.
[0032]
As shown in FIG. 2, the target portion 6 includes a base portion 11 connected to the orifice portion 5 via the shaft portion 7, and a plurality of (four in this example) radially projecting from the base portion 11. And the target 12. Each of these targets 12 is provided such that its tip part interferes with the jet flow 9 ejected from each orifice 8.
[0033]
FIGS. 3A and 3B are a front view and a side view, respectively, in which the tip of the target 12 indicated by part A in FIG. 2 is enlarged.
As shown in FIG. 3A and FIG. 3B, an inclined surface 13 that is inclined by an angle B with respect to the axial direction is provided at the tip of the target 12. The inclined surface 13 is mirror-finished flat, and its tip is formed in a semicircular shape with a radius R. The jet stream 9 ejected from each orifice 8 collides with the substantially central position (specifically, the distance from the tip is 2 / R) of the semicircular tip of the inclined surface 13 of each target 12 and is atomized. At the same time, spraying is performed outward from between the tip of each target 12 and the cover portion 4 according to the inclination angle B of the inclined surface 13. The spray angle of the fine water droplets 14 to be sprayed can be adjusted by adjusting the tilt angle B of the tilted surface 13.
[0034]
Further, since the fine water droplets 14 to be sprayed are sprayed with a spread of an angle W, a tapered portion 15 is provided on the inner wall of the distal end portion of the cover portion 4 so that the inner diameter spreads toward the distal end. Consideration is made so as not to interfere with the fine water droplets 14.
[0035]
If the distance between each orifice 8 and the inclined surface 13 (collision surface) of the target 12 is too short, a part of the fine water droplet 14 that has bounced off is scattered on the inner wall of the cover portion 4 or the orifice portion 5, resulting in a water droplet having a large particle size. This may cause a dripping phenomenon. Therefore, it is desirable that the distance between the small hole orifice 8 and the inclined surface 13 of the target 12, that is, the length of the shaft portion 7, be a distance that does not cause such a liquid dripping phenomenon.
[0036]
Next, the operation of the high-pressure one-fluid atomizing nozzle 100 for increasing output of the gas turbine according to the present embodiment having the above-described configuration will be described.
In FIG. 1, the high-pressure water 1 introduced into the liquid introduction pipe portion 2 from a pipe (not shown) flows from the introduction water rectification portion 10 and is jetted in the axial direction through the orifice 8. The jet stream 9 ejected from each orifice 8 is made into fine water droplets by colliding with the inclined surface 13 of the target 12 on the path, and the gap between the tip of the target 12 and the cover portion 4 as the sprayed water droplet 9. Is sprayed (sprayed).
The power generation system using a gas turbine has a tendency that the output decreases due to an increase in the intake air temperature when the temperature is high such as in summer, but such atomized water droplets 9 are sprayed on the intake air upstream of the compressor. As a result, the intake air is increased and the heat of evaporation lowers the intake air temperature, increasing the mass flow rate of the intake air and increasing the output of the system.
[0037]
Hereinafter, the operational effects obtained by the present embodiment will be sequentially described.
(1) The effect of integrally configuring the liquid introduction pipe, nozzle and cover
FIG. 4 is a cross-sectional view showing a state where the high-pressure one-fluid nozzle 100 is installed in a narrow gas flow path such as an intake pipe. In FIG. 4, the high pressure one-fluid nozzle 100 is welded to the intake pipe 20 by welding the cover part 4 and the outer periphery of the intake pipe 20 with the tip part slightly facing the inside of the intake pipe 20. It is fixed against. Then, the intake air flows in the direction of the arrow 21 in the intake pipe 20 together with the fine water droplets 14 sprayed from the high-pressure one-fluid nozzle 100.
[0038]
When a nozzle is installed in such a narrow space, the tip of the nozzle must face the flow path of the intake pipe 20, so that the larger the nozzle itself, the greater the flow resistance in the flow path, The pressure loss increases. Further, if the cover portion 4 is not provided, the high-pressure one-fluid nozzle 100 is such that the liquid introduction pipe portion 2 welds the nozzle portion 3 to the intake pipe 20, and the tip protrudes greatly into the intake pipe 20. It will be.
[0039]
On the other hand, the high-pressure one-fluid nozzle 100 of the present embodiment is reduced in size (for example, with the diameter of the cover portion 4) by integrally forming the liquid introduction pipe portion 2, the nozzle portion 3, and the cover portion 4 by welding them together. About 7 mm).
[0040]
Further, since the high-pressure one-fluid nozzle 100 has the cover portion 4 at the tip, the tip portion slightly faces the intake pipe 20 by welding the cover portion 4 to the intake pipe 20. Even if installed, there is almost no flow resistance in the intake pipe 20, and the pressure loss of the intake can be remarkably reduced as compared with the case where a nozzle without a cover is installed.
[0041]
Furthermore, since the nozzle part 3 is surrounded by the cover part 4, the jet flow 9 injected from the orifice 8 is protected by the cover part 4, and a lateral force acts on the jet flow 9 by the flow of the intake air. Therefore, each jet stream 9 collides with a predetermined position of the target 12 precisely corresponding to each other, and a stable spray state of the sprayed water droplets 9 can be maintained regardless of the low flow velocity area and the high flow velocity area of the intake air.
[0042]
Further, since there are no components on the downstream side of the target portion 6, the fine water droplets 14 that are sprayed by colliding with the target 12 collide with some components after spraying and the water droplets adhere to each other to form large particles. It will not become. Therefore, the fine water droplets 14 can be sprayed in the intake air to the compressor while maintaining a very small particle diameter, and can be efficiently vaporized there.
[0043]
(2) Action by the introduced water rectification unit 10
In the high-pressure one-fluid atomizing nozzle 100 of the present embodiment, the jet flow 9 from the orifice 8 becomes high speed, and therefore, when the upstream flow is disturbed, the jet flow 9 is affected by this, and the jet flow 9 to be ejected is a fine thread shape. It does not flow in the form of water alone, but becomes thick with air. As a result, the collision range of the jet stream 9 on the target 12 becomes wide and the collision energy is dispersed, so that the water droplet diameter required as the fine water droplet 14 cannot be obtained.
[0044]
Therefore, in the present embodiment, since the introduction water rectification unit 10 having an enlarged diameter is provided on the upstream side of the orifice 8, the flow resistance becomes smaller than that in which high pressure water is directly guided to the orifice 8, and the orifice Since the high-pressure water 1 introduced into the water 8 is rectified here, a fine-filament jet stream 9 with a small amount of air can be ejected from the orifice 8 and fine water droplets 14 having a desired water droplet diameter can be obtained. .
[0045]
(3) Action by electric discharge machining of orifice 8
If the orifice 8 is finished by drilling, the inner wall surface of the orifice 8 becomes rough, and the jet stream 9 is disturbed. Therefore, a thick jet stream 9 in which air is mixed is injected, and a collision site with respect to the target 12 is generated. Becomes a wide range, and the collision energy is dispersed.
On the other hand, as schematically shown in FIG. 3A, in the present embodiment, the orifice 8 is finished with high precision by electric discharge machining or the like, so that the inner wall surface of the orifice 8 is roughened. A smooth surface with a very low degree can be finished. Therefore, the jet stream 9 ejected from the orifice 8 can be accurately collided with a predetermined collision position of the jet stream 9 to the target 12 (that is, a position at a distance R / 2 from the tip of the target 12).
[0046]
If the orifice 8 is drilled, since the jet stream 9 becomes thick, the drilling position of each orifice 8 in the orifice portion 5 is slightly shifted inward in the radial direction, and the tip end of the target 12 than shown in FIG. It is preferable to make the jet stream 9 collide with the inside of the position.
[0047]
(4) Action by the taper portion 15 of the cover portion 4
If the fine water droplet 14 colliding with the target 12 collides with the cover portion 4, the water droplet adheres to the cover portion 4 and the sprayed water droplet becomes large and liquid dripping occurs. Further, the cover 4 covers the side of the jet flow 9 and prevents the collision position of the jet flow 9 on the target 12 from being shifted from the specified position due to the influence of the intake air flow. Is a position corresponding to the tip position of the nozzle tip 5 at a minimum. Further, as shown in FIG. 1, the front end position of the cover portion 4 needs to be provided so as not to interfere with the fine water droplets 14 generated after the jet stream 9 collides with the target 12. In addition, since the outer diameter of the cover part 4 becomes the maximum diameter of the high-pressure one-fluid atomizing nozzle 100 as it is, the smaller one is preferable.
[0048]
In consideration of the above conditions, if the cover portion 4 does not have the taper portion 15, the gap between the target 12 and the target 12 must be made large so as not to interfere with the spray width W of the fine water droplets 14, and the cover is covered accordingly. The diameter of the part 4 must be increased. On the other hand, in the present embodiment, since the tapered portion 15 is provided on the inner peripheral side of the front end portion of the cover portion 4, even if the cover portion 4 having a small diameter is used compared to the case without the tapered portion 15, the cover portion It is possible to prevent 4 from interfering with the fine water droplets 14.
[0049]
(5) Action by the inclined surface 13 of the target
In the present embodiment, the spray angle of the fine water droplets 14 can be adjusted by changing the inclination angle of the inclined surface 13 of the target 12. Therefore, the fine water droplets 14 can be sprayed at the required spray angle by adjusting the tilt angle B of the inclined surface 13 of each target 12 according to the spray angle of the fine water droplets 14 required in advance. Further, the closer the surface of the inclined surface 13 of each target 12 is to a mirror surface, the thinner the water film that is formed and the finer the water droplets 14 become. Therefore, in the present embodiment, the fine water droplets 14 having a very small particle diameter can be sprayed by mirror-finishing the inclined surface 13.
[0050]
(6) Suppress system loss
Here, FIG. 5 is a graph showing the spray water droplet size distribution, in which the horizontal axis represents the radial distance from the center of the spray distribution, and the vertical axis represents the Sauter average water droplet size. In FIG. 5, curves a and b indicate the water droplet distribution when the spray pressure is 5 MPa to 9 MPa and 4 MPa, respectively, and the dotted arrows indicate the end of the reach range of the fine water droplets. However, the measurement position was 50 mm from the nozzle tip.
As shown in FIG. 5, in the present embodiment, it is understood that fine water droplets having a Sauter average water droplet diameter of 20 μm or less can be sprayed by spraying at a spray pressure of 5 MPa to 9 MPa.
[0051]
FIG. 6 is a graph showing the flow characteristics of the high-pressure one-fluid atomizing nozzle 100 according to the present embodiment having four targets. The horizontal axis represents the spray pressure (nozzle internal pressure), and the vertical axis represents the amount of spray water. ing. However, FIG. 6 shows a case where the spray pressure of 7 MPa is the rated flow rate of the nozzle.
As shown in FIG. 6, when the spray pressure is 5 MPa to 9 MPa, the amount of spray water becomes 1.00 L / min to 1.36 L / min, and the rated flow rate (7 MPa) is adjusted by adjusting the spray pressure between 5 MPa and 9 MPa. It can be seen that the spray water amount can be adjusted to ± 15% in the center.
[0052]
As described above, the present embodiment employs a one-fluid atomizing nozzle and can spray fine water droplets 14 that are sufficiently miniaturized. When a two-fluid atomizing nozzle that requires extraction from a conventional compressor is used, power generation output loss corresponding to about 2% of the total is generated by extraction from the compressor. In this embodiment, the compressor Therefore, there is little system loss of the gas turbine power generation system, and more efficient operation is possible. For example, the output loss when the high-pressure one-fluid atomizing nozzle 100 of the present embodiment is used in a 100 megawatt gas turbine power generation system is the power used by the high-pressure pump for pumping the high-pressure water 1 (for example, about 25 kilowatts). ) Only. This is about 1.25% of the electric power used (for example, about 2 megawatts) when using a two-fluid atomizing nozzle that requires bleed air from the compressor. 025%, which is very small compared to the power generation output loss (about 2%) when the conventional two-fluid atomizing nozzle is used.
[0053]
In this embodiment, since a plurality of targets 12 (four in this embodiment) are provided, four jet streams 9 can be atomized simultaneously, and a large number of fine water droplets 14 can be obtained with one nozzle. Is obtained. As a result, the number of nozzles installed can be reduced, the system cost can be reduced, and the intake pressure relative to the air flow can be reduced even if the nozzle is arranged in the flow of intake air as described in FIG. Loss can be reduced. In addition, since sufficiently fine water droplets 14 can be sprayed, erosion of the blades of the compressor can be avoided, and evaporation within the compressor can be performed quickly, and the effect of latent heat of vaporization can be obtained efficiently. , Improve thermal efficiency.
[0054]
As described above, when the high-pressure one-fluid atomizing nozzle 100 of the present embodiment is installed in a gas turbine power generation system, power generation efficiency can be improved.
[0055]
7 (a) and 7 (b), respectively, a high-pressure one-fluid atomizing nozzle provided with eight targets 12, as shown in an axial sectional view and a view seen from the right side of the axial sectional view, respectively. In the case of 200, if the orifice 8 has the same diameter, the target 12 can obtain a spray flow rate twice that of the four high-pressure one-fluid atomizing nozzles 100. In FIG. 6, when the spray pressure is 7 MPa, the high-pressure one-fluid atomizing nozzle 100 can spray about 1.18 L / min of water. If it is the same, it is possible to spray a flow rate of about 2.36 L / min. Accordingly, when the number of targets is increased as in the high-pressure one-fluid atomizing nozzle 200 of FIG. 7, the number of nozzles can be reduced by the amount of increase in the spray flow rate per nozzle, so that there are four target nozzles. Compared with the high-pressure single-fluid atomizing nozzle 100, the system cost can be further reduced, and even if it is arranged in the flow of intake air, the number of arrangements can be reduced, so that the intake pressure loss with respect to the air flow is further reduced. be able to.
[0056]
▲ 7 ▼ Prevention of corn collapse
The sprayed water droplets 9 collide with the inclined surfaces 13 of the respective targets 12 and are each ejected outward in the radial direction while being inclined about the angle B to the angle B + W forward with respect to the axial direction. , Sprayed in a quadrangular pyramid shape (in the high-pressure one-fluid atomizing nozzle 200 of FIG. 7, an octagonal pyramid shape) instead of a conical shape. Therefore, a gap 22 is formed between each sprayed water droplet 9 that scatters in four directions (eight directions in the case of FIG. 7), and the center of the pyramid (spray region) formed by each sprayed water droplet 9 is formed through this gap 22. Outside air flows into the space in front of each target portion 6 in the portion (inner side). When the spray atmosphere is high temperature and high pressure, if the outside air does not flow into the spray water droplets, the central part of the spray region is often decompressed and the spray region itself shrinks, and the water droplets adhere to each other and the spray water droplet diameter increases. May occur (cone collapse phenomenon). On the other hand, in the present embodiment, since the outside air circulates in the spray region through the gap 22, it is possible to suppress the occurrence of the decompression region in the spray region and prevent the occurrence of the cone collapse phenomenon. Therefore, this embodiment has sufficient applicability even when sprayed in a high temperature and high pressure atmosphere.
[0057]
In the above, although the embodiment of the high-pressure one-fluid atomizing nozzle for gas turbine increase output of the present invention has been shown, hereinafter, the gas turbine power generation system in which the above-described high-pressure one-fluid atomizing nozzle 100 (or 200) is installed. explain.
[0058]
FIG. 8 is a schematic configuration diagram of a gas turbine power generation system including the high-pressure one-fluid atomizing nozzle for gas turbine increase output according to the present invention.
In FIG. 8, a gas turbine power generation system includes a compressor 31 that compresses intake air 30, a combustor 32 that injects fuel into the compressed air and burns, a turbine 33 that rotates by the energy of the combustion gas, A generator 34 that is driven by the rotation of the turbine 33 to generate electricity, an air chamber 35 installed at the inlet of the compressor 31, and a spray system 36 that sprays the fine water droplets 14 into the air chamber 35 are provided. .
[0059]
Here, the combustor 32 is provided with a burner 37 for combustion, and the combustion gas is discharged to the outside as an exhaust gas 39 via a silencer 38. The fuel stored in the fuel tank 40 is discharged and supplied to the combustor 32 by the fuel pump 41. A filter 42 is provided in the middle of the fuel supply system, and foreign matters in the supplied fuel are removed by the filter 42. Further, the flow rate of the supplied fuel is detected by the flow meter 43, and based on the detected value of the flow meter 43, the opening amount of the flow rate control valve 44 is adjusted by a control device (not shown) or the like, so that the fuel flow rate is desired. Controlled to be a value. The power generator 34 is connected to a power transmission end 45 that transmits electricity via a substation facility.
[0060]
In the spray system 36, water to be sprayed is stored in a water storage tank 47, discharged by a high-pressure pump 48 connected to the water storage tank 47, and a main supply pipe 49 and a plurality of branch pipes 50 connected thereto. It sprays from the high pressure 1 fluid atomization nozzle 100 (or 200) provided in each header 51 through the header 51. FIG. The discharge pressure from the high-pressure pump 48 is detected by the pressure sensor 52, and the pressure control valve 53 is controlled based on the detection value of the pressure sensor 52, so that the discharge pressure is adjusted to a desired value. The flow rate of water flowing through the main supply pipe 49 is detected by the flow meter 54, and the flow rate control valve 55 is operated based on the detected value of the flow meter 54, so that the flow rate is controlled to a desired value. ing. A filter 56 is provided on the downstream side of the flow rate control valve 55, and foreign matters mixed in the water flowing in the main supply pipe 49 are removed by the filter 56. The main supply pipe 49 and the branch pipe 50 are provided with a pressure sensor 57 and an ON / OFF motor valve 58 for detecting the supply water pressure, respectively. The air chamber 35 is provided with a drain valve 59 for discharging condensed water droplets of the sprayed fine water droplets 14.
[0061]
In operation of the gas turbine power generation system of the present embodiment configured as described above, first, a motor (not shown), which is a separate facility, is rotated in an initial state, and fuel is supplied from the fuel supply system to the combustor 32. The combustion burner 37 ignites and burns. When the steady state is reached, the motor, which is another facility, is disconnected and the combustion is continued to maintain the steady operation state. The exhaust gas 39 from the turbine 33 flows into a steam turbine boiler (not shown) and is reused, or NOx, SOx, etc. are removed by an exhaust gas treatment device (not shown) and released to the atmosphere. Is done.
[0062]
Further, the intake air 30 that is sucked into the compressor 31 through the air chamber 35 includes the fine water droplets 14 sprayed from the high-pressure one-fluid atomizing nozzle 100 (or 200) of the spray system 36, and the spray has an increased density. It becomes the finished intake air 60 and flows into the compressor 31. At this time, the weight flow rate of the fluid flowing into the compressor 31 increases simultaneously with the temperature of the intake air 30 being lowered.
[0063]
Next, the action of water droplets included in the intake air 30 and flowing into the compressor 31 will be described.
Water droplets flowing into the compressor 31 increase the weight flow rate of the working fluid and are vaporized in the compressor 31. The working fluid is further subjected to adiabatic compression when vaporization is completed. At that time, the constant-pressure specific heat of water vapor is about twice that of air in the vicinity of the typical temperature (about 300 ° C.) in the compressor 31, and the heat capacity is about twice as much as the weight of water droplets vaporized in terms of air. Equivalent to increased working fluid. The power of the compressor 31 is equal to the enthalpy difference of the working fluid at the inlet / outlet of the compressor 31 and the enthalpy of the working fluid is proportional to the temperature. Therefore, when the working fluid temperature at the outlet of the compressor 31 decreases, the required power of the compressor 31 also increases. It can be reduced accordingly. Therefore, it is important for efficiency improvement to keep the temperature of the outlet of the compressor 31 low by making the particle diameter of the water droplets flowing into the compressor 31 as small as possible and vaporizing as early as possible. The above-described high-pressure single-fluid atomizing nozzle 100 (or 200) according to the present invention is effective because the sprayed water droplet diameter can be reduced to about 20 μm or less.
[0064]
The working fluid pressurized by the compressor 31 is heated by combustion of fuel in the combustor 32 and then flows into the turbine 33 to expand and work. This work is called the axial output of the turbine 33 and is equal to the enthalpy difference of the inlet / outlet working fluid of the turbine 33.
[0065]
The amount of fuel input is controlled so that the gas temperature at the inlet of the turbine 33 does not exceed a predetermined temperature. For example, the fuel amount to the combustor 32 is controlled so that the working fluid temperature at the inlet / outlet of the turbine 33 becomes equal to the value before the high-pressure one-fluid atomizing nozzle 100 (or 200) of the present invention is installed. When such constant combustion temperature control is performed, the amount of fuel input is increased by the amount that the temperature at the outlet of the compressor 31 is lowered due to the spray water droplets as described above.
[0066]
Further, if the combustion temperature is constant and the weight ratio of the inflowing water droplets is about several percent of the sprayed intake air 30, the pressure at the inlet of the turbine 33 and the outlet pressure of the compressor 31 do not change approximately depending on whether water droplets are injected or not. The turbine outlet temperature T4 does not change. Therefore, the shaft output of the turbine 33 does not change with or without water droplet injection.
[0067]
On the other hand, since the net output of the turbine 33 is obtained by subtracting the power of the compressor 31 from the output of the turbine 33, the compressor is finally sprayed by the high-pressure one-fluid atomizing nozzle 100 (or 200) of the present invention. The net output of the turbine 33 can be increased by the amount by which the power of 31 is reduced.
[0068]
Here, assuming that the temperature of the sprayed intake air 30 is T1, the outlet temperature of the compressor 31 is T2, the temperature of the combustor 32 is T3, and the outlet temperature of the turbine 33 is T4, the electrical output E of the turbine 33 is It is obtained by subtracting the work Cp (T2-T1) of the compressor 31 from the shaft output Cp (T3-T4), and is approximately expressed by the following equation.
E = (T3-T4)-(T2-T1) (1)
Normally, the combustion temperature T3 is operated so as to be constant. Therefore, when the outlet temperature T2 of the compressor 31 is lowered to T2 ′ due to the injection of water droplets, the increased output Cp (T2 equivalent to the reduced work of the compressor 31 is obtained. -T2 ') is obtained.
[0069]
On the other hand, the efficiency η of the gas turbine power generation system is approximately given by the following equation.
η = 1- (T4-T1) / (T3-T2) (2)
From this, since T2 '<T2, the second term on the right-hand side becomes small, so that the efficiency is improved by water droplet injection.
[0070]
Therefore, according to the gas turbine power generation system of the present embodiment, a large amount of fine water droplets are sprayed to the intake air 30 of the compressor 31 by the spray system 36 including a plurality of high-pressure one-fluid atomizing nozzles 100 (or 200). Therefore, it is possible to suppress a decrease in gas turbine output accompanying an increase in intake air temperature in summer. As a result, it is possible to avoid a decrease in output due to a rise in intake air temperature in the summer of the gas turbine power generation system, so that highly efficient operation is possible regardless of the season.
[0071]
【The invention's effect】
According to the present invention, the liquid introduction tube portion, the nozzle portion, and the cover portion can be reduced in size by connecting and integrating them, for example, by welding or the like. Thereby, an installation space can be saved and the pressure loss in a nozzle attachment part can be reduced. In particular, since it is equipped with a cover, when installing in an intake pipe, etc., the nozzle tip into the pipe is welded to the pipe with the cover facing the pipe slightly with the tip facing the pipe side. The projecting portion can be made extremely small, and the flow path resistance can be suppressed as much as possible. Further, compared with a two-fluid nozzle that uses a bleed air from a compressor to make the liquid finer, fine droplets can be sprayed without using the bleed air. Therefore, system loss can be suppressed as much as possible. In addition, by providing a plurality of orifices and targets corresponding thereto, the amount of spray water per nozzle can be increased, and a large amount of water can be atomized into fine water droplets with a small number of nozzles.
[Brief description of the drawings]
FIG. 1 is an axial sectional view of an embodiment of a high-pressure one-fluid atomizing nozzle for gas turbine increase output according to the present invention, and a diagram viewed from the right side of the figure.
FIG. 2 is a perspective view illustrating a schematic configuration of a nozzle portion.
FIGS. 3A and 3B are a front view and a side view in which a tip of a target shown by part A in FIG. 2 is enlarged.
FIG. 4 is a cross-sectional view showing a state in which the high-pressure one-fluid atomizing nozzle for gas turbine increase output according to the present invention is installed in a narrow gas flow path such as an intake pipe.
FIG. 5 is a graph showing the sprayed water droplet size distribution, wherein the horizontal axis represents the radial distance from the spray distribution center, and the vertical axis represents the Sauter average water droplet size.
FIG. 6 is a graph showing the flow characteristics of a high-pressure single-fluid atomizing nozzle for gas turbine increase output according to the present invention having four targets, where the horizontal axis indicates the spray pressure (nozzle internal pressure) and the vertical axis indicates the amount of spray water. ing.
FIG. 7 is an axial sectional view of an embodiment of a high-pressure one-fluid atomizing nozzle for gas turbine increase output according to the present invention having eight targets, and a diagram viewed from the right side in the figure.
FIG. 8 is a schematic configuration diagram of a gas turbine power generation system including a high-pressure one-fluid atomizing nozzle for gas turbine increase output according to the present invention.
[Explanation of symbols]
1 High-pressure water (high-pressure liquid)
2 Liquid inlet tube
3 Nozzle part
4 Cover part
8 Orifice
9 Jet flow
12 Target
13 Inclined surface
14 Fine droplets
31 Compressor
33 Turbine
100 High-pressure 1-fluid atomizing nozzle for gas turbine increased output
200 High-pressure 1-fluid atomizing nozzle for increased output of gas turbine

Claims (5)

It is installed in a gas turbine power generation system that rotates a turbine by combustion gas generated by combusting intake air from a compressor together with fuel, and converts the rotational energy of the turbine into electric energy, and liquid is introduced into the intake air to the compressor. In a high-pressure one-fluid atomizing nozzle for gas turbine increase output that sprays and lowers the intake air temperature of the compressor and increases the intake air density,
A liquid introduction pipe section for introducing a high-pressure liquid, a plurality of orifices for injecting the high-pressure liquid from the liquid introduction pipe section as a jet flow in the axial direction, and a jet colliding with and colliding with the jet flow ejected from each orifice The nozzle unit having a plurality of targets that atomize the flow to form fine droplets and the nozzle unit through a gap through which the fine droplets pass between the target and the target so as not to interfere with the atomized fine droplets A cylindrical cover part covering the circumferential direction of
The number of the orifices and the corresponding targets corresponding to the required spray flow rate is provided, and the jet pressure of the jet flow is adjusted within a range of 5 MPa or more, and the high pressure for increasing the gas turbine output power 1 fluid atomizing nozzle. It is installed in a gas turbine power generation system that rotates a turbine by combustion gas generated by combusting intake air from a compressor together with fuel, and converts the rotational energy of the turbine into electric energy, and liquid is introduced into the intake air to the compressor. In a high-pressure one-fluid atomizing nozzle for gas turbine increase output that sprays and lowers the intake air temperature of the compressor and increases the intake air density,
A liquid introduction pipe section for introducing a high-pressure liquid, a plurality of orifices for injecting the high-pressure liquid from the liquid introduction pipe section as a jet flow in the axial direction, and a jet colliding with and colliding with the jet flow ejected from each orifice The nozzle unit having a plurality of targets that atomize the flow to form fine droplets and the nozzle unit through a gap through which the fine droplets pass between the target and the target so as not to interfere with the atomized fine droplets A cylindrical cover part covering the circumferential direction of
The tip portions of the plurality of targets with which the jet flow collides are inclined surfaces inclined in the jet direction of the jet flow toward the tips,
A high-pressure one-fluid atomizing nozzle for increasing output of a gas turbine, wherein the inclined surface of the target is mirror-finished flat. It is installed in a gas turbine power generation system that rotates a turbine by combustion gas generated by combusting intake air from a compressor together with fuel, and converts the rotational energy of the turbine into electric energy, and liquid is introduced into the intake air to the compressor. In a high-pressure one-fluid atomizing nozzle for gas turbine increase output that sprays and lowers the intake air temperature of the compressor and increases the intake air density,
A liquid introduction pipe section for introducing a high-pressure liquid, a plurality of orifices for injecting the high-pressure liquid from the liquid introduction pipe section as a jet flow in the axial direction, and a jet colliding with and colliding with the jet flow ejected from each orifice The nozzle unit having a plurality of targets that atomize the flow to form fine droplets and the nozzle unit through a gap through which the fine droplets pass between the target and the target so as not to interfere with the atomized fine droplets A cylindrical cover part covering the circumferential direction of
The tip portions of the plurality of targets with which the jet flow collides are inclined surfaces inclined in the jet direction of the jet flow toward the tips,
An inclined surface of the target has an inclination angle corresponding to a required spray angle of fine droplets.   2. The high-pressure one-fluid atomization nozzle for gas turbine increase output according to claim 1, wherein tip ends of the plurality of targets with which the jet flow collides are inclined surfaces inclined in the jet direction of the jet flow toward the tip. A high-pressure one-fluid atomizing nozzle for increasing output of a gas turbine, characterized in that 5. The high-pressure one-fluid atomizing nozzle for gas turbine increase output according to claim 2, wherein a tip portion of the inclined surface is formed in a substantially semicircular shape, and the jet flow has a substantially semicircular shape. A high-pressure one-fluid atomizing nozzle for increasing output of a gas turbine, which collides with a substantially central position of a tip portion.

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