JP2004270485A - Air cooled condenser, vacuum control system and control method therefor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To perform condenser vacuum control solely by automatic operation and to obtain a highly accurate degree of vacuum. <P>SOLUTION: This air cooled condenser is equipped with a tube bundle 27 for heat exchange, a plurality of blowers 31 supplying air for cooling, and a vacuum control device 33 for controlling the vacuum degree of condenser. The vacuum control device 33 is equipped with a vacuum detector detecting the degree of vacuum by an exhaust steam line 24, an atmospheric pressure compensation means 35 determining the actual vacuum by compensating the detected signal for atmospheric pressure, a required-vacuum indicating means 36 outputting required-vacuum indicating signals set along the optimum points of condenser vacuum which vary according to the operating condition of a steam turbine 22, an air quantity control value calculating means 37 determining the control values of the air quantity to be supplied by the blowers 31, with actual vacuum signals and required-vacuum indicating signals as the elements, and a supplied air quantity control means 38 controlling the air quantity supplied from the plurality of blowers based on the air quantity control values. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an air-cooled condenser provided in a steam turbine plant, a vacuum control system and a vacuum control method for the condenser.
[0002]
[Prior art]
The air-cooled condenser is applied to a steam turbine plant using low-temperature steam, such as a geothermal power plant, or a steam turbine plant installed in a mountainous area or other area where application of the water-cooled condenser is difficult or undesirable. Is done.
[0003]
FIG. 4 is a system configuration diagram showing a conventional example of an air-cooled condenser in such a steam turbine plant.
[0004]
The steam turbine plant includes a main steam pipe 1, a steam turbine 2, and a generator 3. Steam generated by a steam generator (not shown) is supplied to the steam turbine 2 via the main steam pipe 1, and the generator 3 Provided for rotating work. The steam used for this work is discharged to an air-cooled condenser 5 through an exhaust communication pipe 4 which is an exhaust steam line.
[0005]
The air-cooled condenser 5 includes an upper header 6a, which is an exhaust steam introduction section connected to the exhaust communication pipe 4, and a heat-exchange tube bundle 7 having, for example, a roof-type inclined arrangement and an upper end connected to the upper header 6a. And a lower header 6b for drainage connected to the lower end of the tube bundle 7. A condensate tank 9 and a condensate pump 10 are sequentially connected to the lower header 6b via a collecting pipe 8.
[0006]
Below the tube bundle 7, a plurality of blowers 11 for supplying cooling air to the tube bundle 7 as an upward flow are arranged. Conventionally, these blowers 11 are generally single-rotation type axial flow blowers driven by a single-rotation electric motor 12, and are supported on a stand (not shown).
[0007]
During operation, exhaust steam discharged from the steam turbine 2 is introduced into the tube bundle 7 via the exhaust communication tube 4 and the upper header 6a, and air as a cooling medium is supplied from the blower 11 to the outer surface side of the tube bundle 7. The supplied steam flowing through the tube bundle 7 is deprived of latent heat by air, is efficiently condensed, and is condensed. The condensate is stored in a condensate tank 9 via a lower header 6b and a collecting pipe 8, and is supplied to a steam generator by a condensate pump 10 through a water supply line (not shown).
[0008]
Conventionally, in such an air-cooled condenser 5, in order to ensure a predetermined condenser efficiency and equipment safety, a vacuum controller 13 is provided to control the condenser vacuum.
[0009]
In the example shown in FIG. 4, as the degree of vacuum control device 13, a degree of vacuum detector 14 provided in the exhaust pipe 4 and a control calculation along the target degree of vacuum using the value detected by the degree of vacuum detector 14 as an element. And an operation unit 15 for performing the operation. The arithmetic unit 15 is driven by a control pattern program 16 in which a specific target degree of vacuum is set, and has an input device 17 for manual input. The electric motors 12 of the blowers 11 are connected to the calculator 15 by individual control lines 18a.
[0010]
During the operation of the condenser, a detection signal is input from the vacuum detector 14 to the calculator 15, and the calculator 15 performs calculation based on a control pattern program 16 in which a specific target vacuum is set. In accordance with the calculation result, a command such as start / stop is output to each axial blower 11 via each control line 18a.
[0011]
As another conventional example, in a case where the degree of vacuum is reduced due to an increase in the outside air temperature and the condensing efficiency is reduced, a mechanism for promoting cooling by spraying cooling water is provided to increase the degree of vacuum of the condenser. And the like have been proposed (see Patent Document 1).
[0012]
[Patent Document 1]
JP-A-9-159378
[Problems to be solved by the invention]
In the above-described conventional air-cooled condenser, various problems occur because a specific target vacuum degree is set in the arithmetic unit of the vacuum degree control device 13.
[0014]
This will be described with reference to FIG. FIG. 5 is a characteristic diagram showing an optimum point (optimum vacuum degree) of the condenser vacuum degree for setting the target vacuum degree. As shown in FIG. 5, when the horizontal axis represents the condenser vacuum degree and the vertical axis represents the plant loss (turbine loss), the plant efficiency changes in a quadratic curve with the change in the condenser vacuum degree. And there is a valley of the condenser vacuum at which the plant loss is minimized. The smallest point of the plant loss is the optimum degree of vacuum. By setting the vicinity of the optimum degree of vacuum as the target degree of vacuum, efficient plant operation becomes possible and high-precision control can be performed.
[0015]
However, in an actual air-cooled condenser, the plant loss changes due to the operating condition of the steam turbine, for example, a load change, an atmospheric temperature change, a secular change of plant equipment, and the like, and the optimal vacuum degree changes accordingly. For this reason, in order to realize truly high-precision control, it is necessary as a control element to change the target vacuum degree corresponding to each optimum vacuum degree that changes depending on the turbine load and the like (hereinafter, such a setting is necessary). The variable target vacuum degree corresponding to the changing optimal vacuum degree is referred to as "necessary vacuum degree").
[0016]
On the other hand, in the above-described conventional general technique, a control pattern program 16 in which a specific target degree of vacuum is set without using a change in the optimum degree of vacuum is actually used. For this reason, when the plant operation situation changes significantly, it is impossible to obtain an arbitrary degree of vacuum corresponding to the plant operation, and the arithmetic unit 15 is switched from the automatic condition to the manual operation, and the target by the manual input device 17 is set. It was necessary to input the set value of the degree of vacuum.
[0017]
In addition, since automatic switching cannot be performed for each blower operation, it is necessary to individually perform ON / OFF switching operation for each blower by manual input.
[0018]
As described above, conventionally, control along a specific target vacuum degree set in advance can only be automatically performed, and when the target vacuum degree is changed, control efficiency is low, such as switching from automatic conditions to manual operation, and the like. There were problems such as difficulty in obtaining a high degree of vacuum.
[0019]
The present invention has been made in view of such circumstances, and provides an air-cooled condenser capable of controlling a condenser vacuum degree only by automatic operation and obtaining a high-precision vacuum degree. With the goal.
[0020]
Another object of the present invention is to provide a vacuum control system and a vacuum control method for automatic control applied to the air-cooled condenser.
[0021]
[Means for Solving the Problems]
In order to achieve the above object, in the invention according to the first aspect, a tube bundle for heat exchange into which exhaust steam discharged from a steam turbine is introduced, and a plurality of tubes for supplying cooling air to an outer surface portion of the tube bundle. In an air-cooled condenser comprising a blower and a vacuum control device for controlling a condenser vacuum degree by controlling an amount of air supplied from the blower, the vacuum control device converts the exhaust steam into A vacuum detector for detecting the degree of vacuum in an exhaust steam line leading from the steam turbine side to the tube bundle side, and atmospheric pressure correcting means for correcting the detection signal of the vacuum detector to atmospheric pressure to obtain the actual vacuum degree; A required degree of vacuum indicating means for outputting a required degree of vacuum indicating signal set along an optimum point of the degree of vacuum of the condenser, which varies according to the operating condition of the steam turbine, and an actual pressure corrected by the atmospheric pressure correcting means. Vacuum signal And an air amount control value calculating means for obtaining an air amount control value to be supplied by the blower using the necessary vacuum degree indicating signal output from the required vacuum degree indicating means as an element, and the air amount control value calculating means. An air-cooled condenser comprising: a supply air amount control unit that controls an amount of air supplied from the plurality of blowers based on an air amount control value.
[0022]
In the invention according to claim 2, a single-rotation type axial flow blower driven by a single-rotation speed motor is provided as the blower, and the single-rotation type axial flow blower is provided as the supply air amount control means. The air-cooled condenser according to claim 1, further comprising a blower selecting means for selecting a specific one to be operated from among them.
[0023]
In the invention according to claim 3, a variable speed type axial flow blower driven by a variable speed electric motor is provided as the blower, and the rotation speed of the variable speed type axial flow fan is controlled as the supply air amount control means. An air-cooled condenser according to claim 1, further comprising a blower rotation speed control means for controlling.
[0024]
In the invention according to claim 4, a variable blade type blower having a variable blade opening degree is provided as the blower, and a blade opening degree control means for controlling a blade opening degree of the variable blade type blower as the supply air amount control means. An air-cooled condenser according to claim 1, 2 or 3, comprising:
[0025]
In the invention according to claim 5, there is provided a louver mechanism attached to the blower for opening and closing an air flow path to the tube bundle side, and the air flow path for controlling an opening degree of the louver mechanism as the supply air amount control means. An air-cooled condenser according to any one of claims 1 to 4, further comprising control means.
[0026]
In the invention according to claim 6, a vacuum detector for detecting the degree of vacuum in an exhaust steam line that guides exhaust steam of the steam turbine to the heat exchange tube bundle side of the air-cooled condenser, and an output from the vacuum detector. Atmospheric pressure is corrected by inputting the detected signal, and the atmospheric pressure correcting means for outputting the actual vacuum degree signal is set along the optimum point of the condenser vacuum degree which changes according to the operating condition of the steam turbine. A required degree of vacuum indicating means for outputting a required degree of vacuum indicating signal, and an actual vacuum degree signal corrected by the atmospheric pressure correcting means and a required degree of vacuum indicating signal output from the required degree of vacuum indicating means; The air amount control value calculating means for obtaining the air amount control value to be supplied and outputting the air amount control value signal, and the air amount control value signal output from the air amount control value calculating means, Previous based on control value Supply air amount control means for individually outputting an operation control signal to a plurality of blowers, and automatically changing a condenser necessary vacuum degree in response to a change in the operating condition of the steam turbine, thereby providing a plurality of blowers. The present invention provides a vacuum control system for an air-cooled condenser characterized by simultaneously controlling the operations of the air-cooled condenser.
[0027]
In the invention according to claim 7, a degree of vacuum detection step of detecting a degree of vacuum in an exhaust steam line that guides exhaust steam of the steam turbine to a heat exchange tube bundle side of the air-cooled condenser; Atmospheric pressure correction step of obtaining the actual vacuum degree by atmospheric pressure correction, and output of a required vacuum degree instruction signal set along the optimum point of the condenser vacuum degree which changes according to the operating condition of the steam turbine. A degree of vacuum instructing step, an air amount control value calculating step of obtaining an air amount control value to be supplied by the blower using the actual vacuum degree signal and the required degree of vacuum indicating signal as elements, and an air amount control value calculating step. A blower operation control step of individually outputting an operation control signal to the plurality of blowers based on the obtained air amount control value. To provide a control method.
[0028]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, an embodiment of the present invention will be described with reference to FIGS. FIG. 1 is a system configuration diagram (front view) showing a steam turbine plant provided with an air-cooled condenser, and particularly shows a vacuum control system in detail. FIG. 2 is a configuration diagram (side view) illustrating the tube bundle, the blower, and the like illustrated in FIG. 1 from a direction different from FIG. 1. FIG. 3 is a flowchart showing the procedure of the vacuum control method.
[0029]
As shown in FIGS. 1 and 2, the steam turbine plant of the present embodiment includes a main steam pipe 21, a steam turbine 22, and a generator 23, and steam generated by a steam generator (not shown) passes through the main steam pipe 21. The electric power is supplied to the steam turbine 22 via the steam turbine 22 and used for rotating the generator 3. The steam provided for this work is discharged to an air-cooled condenser 25 through an exhaust communication pipe 24 which is an exhaust steam line.
[0030]
The air-cooled condenser 25 is composed of an upper header 26a, which is an exhaust steam introduction section connected to the exhaust communication pipe 24, and a heat exchange tube bundle 27, for example, which is inclined and arranged in a roof shape and whose upper end is connected to the upper header 26a. And a lower header 26b for drainage connected to the lower end of the tube bundle 27. A condensate tank 29 and a condensate pump 30 are sequentially connected to the lower header 26b via a collecting pipe 28.
[0031]
Below the tube bundle 27, a plurality of blowers 31 for supplying cooling air to the tube bundle 27 as an ascending flow are provided supported on a stand (not shown). Each of these blowers 31 is configured as an axial blower driven by an electric motor 32, and specifically, as described in the following <Examples 1 to 4>, a single-rotation axial blower ( (Example 1), a variable-rotation type axial flow blower (Example 2), a variable blade type axial flow blower motor (Example 3), one equipped with a louver mechanism (Example 4), a combination thereof, and the like. You.
[0032]
During the operation of the condenser, the exhaust steam discharged from the steam turbine 22 is introduced into the tube bundle 27 via the exhaust communication tube 24 and the upper header 26a, and the air as a cooling medium is supplied from the blower 31 to the outer surface side of the tube bundle 27. Is supplied, and the steam flowing in the tube bundle 27 is deprived of latent heat by air, efficiently condensed, and condensed. The condensate is stored in a condensate tank 29 via a lower header 26b and a collecting pipe 28, and is supplied to a steam generator by a condensate pump 30 via a water supply line (not shown).
[0033]
In this embodiment, such an air-cooled condenser 25 is provided with a vacuum controller 33 capable of controlling the condenser vacuum only by automatic operation. The vacuum control device 33 is configured as a computer system that executes a control operation using the detector and its detection value as elements, and includes a vacuum detector 34, an atmospheric pressure correction unit 35, a required vacuum degree indicating unit 36, an air amount control unit. It is configured to include a value calculation unit 37 and a supply air amount control unit 38. The vacuum controller 33 is connected to the electric motors 32 of the axial blowers through a control line 39 such as a bus.
[0034]
Hereinafter, regarding the configuration of the vacuum control device 33 and the function of the vacuum control method using the device, the signals (s1 to s5) shown in FIG. 1 and the procedure (steps S101 to S105) shown in FIG. Will be explained.
[0035]
The vacuum detector 34 is provided in the exhaust communication pipe 24 as an exhaust steam line that exhausts exhaust steam from the steam turbine 22 side. The vacuum degree detector 34 detects the degree of vacuum in the exhaust communication pipe 24, and outputs a detection signal s1 as an analog signal to the atmospheric pressure correcting means 35 (step S101).
[0036]
The atmospheric pressure correcting means 35 is configured as a converter having A / D conversion and pressure conversion functions. The atmospheric pressure correcting means 35 performs atmospheric pressure correction based on the detection signal s1 output from the vacuum degree detector 34. Then, the actual degree of vacuum is obtained, and the actual degree of vacuum signal s2 is output to the air amount control value calculating means 37 (step S102).
[0037]
Further, the required vacuum degree indicating means 36 is provided with various kinds of vacuum degree information obtained based on steam turbine operating condition data, such as design values, aging data, steam turbine load, atmospheric temperature, etc. of each device of the steam turbine plant. Holding. Then, in the required vacuum degree indicating means 36, the relation data between the plant efficiency (turbine loss and the like) and the optimum vacuum degree which change according to the operating condition is extracted, and it is necessary to set the data in accordance with the current optimum vacuum degree. The degree of vacuum instruction signal s3 is output to the air amount control value calculation means 37 (step S103).
[0038]
The air amount control value calculating means 37 is configured as a CPU circuit. In the air amount control value calculating means 37, the actual vacuum degree signal s 2 corrected by the atmospheric pressure correcting means 35 and the required vacuum degree indicating means 36 are provided. Using the output required vacuum degree instruction signal s3 as an element, an air amount control value to be supplied by the blower is obtained, and an air amount control value signal s4 is output to the supplied air amount control means 38 (step S104).
[0039]
The supply air amount control means 38 is configured as a means for outputting a control instruction of the supply air amount by each axial flow blower 31, for example, a start instruction, a stop instruction, a rotation speed instruction, etc., for example, as a selection relay. In the supply air amount control means 38, an air amount control value signal from the air amount control value calculation means 37 is input, and based on this input value, each of the electric motors 32 of the axial flow blowers 31 is activated or activated. An operation control command signal s5 such as a stop command is output via the control line 39 (step S105).
[0040]
Hereinafter, specific control configurations and control methods will be described with reference to first to fourth embodiments.
[0041]
<Example 1>
In the first embodiment, the above-described blower 31 is a single-rotation type axial flow blower driven by a single-rotation speed motor having a constant rotation speed. Then, the supply air amount control means 38 for outputting and controlling the operation control command signal s5 to the single speed type axial flow blower 31 is specified from among the single speed type axial flow fan 31 to be operated. Blower selection means for selecting a fan, for example, a selection relay. FIG. 1 shows a selection relay as the supply air amount control means 38.
[0042]
In the first embodiment, a start command (ON) is output from the blower selecting means to any single-rotation type axial flow blower 31 to be operated via the control line 39, and the other single-rotation type shafts are output. A stop command (OFF) is output to the blower 31 via the control line 39. Thus, by starting or stopping the axial blower 31 having an arbitrary single-rotation speed motor 32, the cooling air flow rate is controlled, and the condenser vacuum degree is controlled.
[0043]
In this case, in the air amount control value calculation means 37, the actual vacuum degree signal of the condenser whose atmospheric pressure has been corrected and the optimum point of the condenser vacuum degree that changes according to the operating condition such as the turbine load are set. A cooling air flow control value is calculated based on the necessary vacuum degree instruction signal, and the actual vacuum degree is directly controlled to follow based on the calculated value. Therefore, even in a case where the plant operating condition changes significantly, there is no need to switch to manual operation and input the set value of the target vacuum degree, and an efficient and highly accurate vacuum degree can be obtained only by automatic control. Become like
[0044]
The operation control command signal s5 from the supply air amount control means 38 is integrated by a blower selecting means for selecting a specific blower 31 to be operated from the axial flow blowers 31 via a control line 39 such as a bus. , And signal processing is performed, and automatic switching of each blower operation is performed, so that ON / OFF switching control can be individually performed for each blower by automatic operation without requiring manual input.
[0045]
Therefore, according to the first embodiment, even when the target degree of vacuum changes, the degree of vacuum with high control efficiency and high accuracy can be obtained only by the automatic condition.
[0046]
<Example 2>
In the second embodiment, all or a part of the above-described blower 31 is a variable-rotation type axial flow blower driven by a variable-rotation speed motor. The supply air amount control means 38 includes a blower rotation speed control means for controlling the rotation speed of the variable rotation speed type axial flow blower 31. This configuration can be implemented instead of the configuration of the first embodiment or as a combination with the configuration of the first embodiment.
[0047]
In the second embodiment, the rotation speed control command set to obtain the required degree of vacuum is output from the blower selecting means to all or some of the variable rotation speed type axial flow blowers 31, whereby The amount of air blown by the variable speed axial flow blower 31 is controlled.
[0048]
Therefore, according to the second embodiment, when the target degree of vacuum changes, it is possible to obtain a high degree of vacuum with high control efficiency and high accuracy only by the automatic condition. The control function is finely controlled by finely controlling the flow blower 31 within the range of the variable rotation speed, and each portion of the tube bundle is cooled by a predetermined air flow according to the rotation speed assigned to each variable rotation speed type axial flow blower 31. Therefore, not only when all of the blowers 31 are variable-speed axial flow fans, but also when some of them are variable-speed axial flow fans, more precise vacuum degree control can be performed. This makes it possible to more effectively perform the vacuum degree control with higher accuracy.
[0049]
<Example 3>
In the third embodiment, all or a part of the blower 31 described above is applied to a variable blade type blower having a variable blade opening, that is, a variable blade type blower in which the angle of the blade with respect to the axial direction can be adjusted by remote control. . The supply air amount control means 38 is provided with a blade opening control means for outputting a blade opening control command for controlling the blade opening of the variable blade blower 31. This configuration can be applied to either the single-rotation type axial flow blower of the first embodiment or the variable rotation type axial flow blower of the second embodiment.
[0050]
In the third embodiment, a blade opening control command set to obtain a required degree of vacuum is output from the blower selecting means to all or a part of the variable blade-type blowers 31, whereby each variable rotation is controlled. The amount of air blown by the multiaxial blower 31 is controlled.
[0051]
Therefore, according to the third embodiment as well, when the target degree of vacuum changes, it is possible to obtain a high degree of vacuum with high control efficiency and high accuracy only by the automatic condition, but it is the object of the blade opening degree control. By finely controlling the axial blower 31 within a range in which the blade opening can be controlled, the control function is made fine even in the case of a single rotation type axial flow blower, and furthermore, the variable rotation type axial flow In such a case, by performing the blade opening control together with the control of the rotational speed assigned to each of the variable-rotation type axial flow blowers, it is possible to perform a finer degree of vacuum control. Therefore, the accuracy of the vacuum control is more effectively improved.
[0052]
<Example 4>
In the fourth embodiment, as shown in FIG. 2, a louver mechanism 40 attached to the blower 31 for opening and closing the air flow path to the tube bundle side is provided. As the supply air amount control means 38, an air flow path control means for controlling the opening of the louver mechanism 40 is provided. This configuration can be applied to any of the configurations of the first to third embodiments, and the blower itself can be controlled even if the blower itself is kept constant, so that the blower itself is controlled. It is also possible to independently apply a configuration that does not use it.
[0053]
According to the fourth embodiment, an opening command is output from the air flow path control unit to the louver mechanism 40, and the amount of air supplied to the tube bundle from the blower 31 is controlled based on the opening command. In the case where the control is performed in combination with the blower controls 1 to 3, in addition to the functions of these embodiments, it is possible to perform an even more precise vacuum degree control.
[0054]
In addition, even in a configuration in which the blower itself is not controlled, as long as the degree of opening of the louver mechanism 40 can be adjusted, a manual operation or the like is not required, and only the automatic control is effective, and a highly accurate vacuum degree can be obtained. As specifically described in Examples 1 to 4, according to this embodiment, the actual vacuum degree is directly controlled to follow the optimum point of the condenser vacuum degree according to the turbine operation status. Thus, a highly accurate vacuum degree can be obtained only by automatic control.
[0055]
【The invention's effect】
ADVANTAGE OF THE INVENTION According to this invention, while controlling a condenser vacuum degree can be performed only by an automatic operation, the effect that high-precision vacuum degree is obtained is produced.
[Brief description of the drawings]
FIG. 1 is a system configuration diagram showing a steam turbine plant provided with an air-cooled condenser according to an embodiment of the present invention.
FIG. 2 is a configuration diagram showing a tube bundle, a blower, and the like shown in FIG. 1 from a direction different from FIG. 1;
FIG. 3 is a flowchart showing a procedure of a vacuum control method according to an embodiment of the present invention.
FIG. 4 is a configuration diagram showing a conventional example.
FIG. 5 is an explanatory diagram showing an optimum degree of vacuum.
[Explanation of symbols]
21 Main steam pipe 22 Steam turbine 23 Generator 24 Exhaust connection pipe 25 Air-cooled condenser 26a Upper header 26b Lower header 27 Tube bundle 28 Collecting pipe 29 Condenser tank 30 Condensate pump 31 Blower 32 Motor 33 Vacuum control unit 34 Vacuum Degree detector 35 Atmospheric pressure correcting means 36 Required vacuum degree indicating means 37 Air amount control value calculating means 38 Supply air amount controlling means 39 Control line 40 Louver mechanism

Claims (7)

A heat exchanger tube bundle into which exhaust steam discharged from the steam turbine is introduced, a plurality of blowers for supplying cooling air to the outer surface of the tube bundle, and control of the amount of air supplied from these blowers to recover An air-cooled condenser provided with a vacuum control device for controlling a water vacuum degree, wherein the vacuum control device is provided with an exhaust steam line for guiding the exhaust steam from the steam turbine side to the tube bundle side. A vacuum detector for detecting the vacuum pressure, an atmospheric pressure correcting means for correcting the detection signal of the vacuum detector to the atmospheric pressure to obtain an actual vacuum degree, and a condenser vacuum which changes according to the operating condition of the steam turbine. Required vacuum degree indicating means for outputting a required vacuum degree indicating signal set along the optimum point of the degree, an actual vacuum degree signal corrected by the atmospheric pressure correcting means, and a required vacuum output from the required vacuum degree indicating means. Every time Air amount control value calculating means for obtaining an air amount control value to be supplied by the blower using the signal as an element, and supply from the plurality of blowers based on the air amount control value obtained by the air amount control value calculating means. An air-cooled condenser comprising: supply air amount control means for controlling an air amount. As the blower, a single-rotation type axial flow blower driven by a single-rotation speed motor is provided, and the supply air amount control means is a specific one to be operated from the single-rotation type axial flow blower. The air-cooled condenser according to claim 1, further comprising a blower selecting means for selecting the air conditioner. As the blower, a variable speed type axial flow blower driven by a variable speed motor is provided, and as the supply air amount control means, a blower speed control means for controlling the speed of the variable speed type axial flow blower is provided. The air-cooled condenser according to claim 1, further comprising: 3. The air blower according to claim 1, further comprising a variable blade type blower having a variable blade opening degree, wherein said air supply amount control unit includes a blade opening degree control unit configured to control a blade opening degree of said variable blade type blower. 3. The air-cooled condenser according to 3. The louver mechanism attached to the blower for opening and closing an air flow path to the tube bundle side, and the supply air amount control means includes an air flow path control means for controlling an opening degree of the louver mechanism. 4. The air-cooled condenser according to any one of 4 to 4. A vacuum detector that detects the degree of vacuum in an exhaust steam line that guides the exhaust steam of the steam turbine to the heat exchange tube bundle side of the air-cooled condenser, and a detection signal output from the vacuum detector is input. Atmospheric pressure correcting means for outputting an actual vacuum degree signal and an atmospheric pressure correcting means, and outputting a required vacuum degree instruction signal set along an optimum point of the condenser vacuum degree which changes according to the operating condition of the steam turbine. A required vacuum degree indicating means, an actual vacuum degree signal corrected by the atmospheric pressure correcting means and a required vacuum degree indicating signal output from the required vacuum degree indicating means, and an air amount control value to be supplied by the blower Calculating an air amount control value signal, outputting an air amount control value signal, and an air amount control value signal output from the air amount control value operation unit, and inputting the plurality of air amount control values based on the air amount control value. Luck individually to blower Supply air amount control means for outputting a control signal, and automatically changing the condenser necessary vacuum degree in response to a change in the operating condition of the steam turbine to simultaneously control all the operations of the plurality of blowers at the same time. A vacuum degree control system for an air-cooled condenser. A vacuum detection step of detecting the degree of vacuum in an exhaust steam line that guides exhaust steam of the steam turbine to a heat exchange tube bundle side of an air-cooled condenser, and correcting the detected vacuum degree detection signal to atmospheric pressure to obtain an actual vacuum. An atmospheric pressure correction step of obtaining a degree of vacuum, a required degree of vacuum instruction step of outputting a required degree of vacuum instruction signal set along an optimum point of the degree of vacuum of the condenser that changes according to the operating condition of the steam turbine, An air amount control value calculating step of obtaining an air amount control value to be supplied by the blower using the vacuum degree signal and the required vacuum degree indicating signal as elements, based on the air amount control value obtained by the air amount control value calculating step; And a blower operation control step of individually outputting an operation control signal to the plurality of blowers, the method for controlling the degree of vacuum in the air-cooled condenser.

Images