KR20190076662A - apparatus and method for managing performance of a condenser - Google Patents

Abstract

The present invention relates to an apparatus for managing performance of a condenser and a method thereof capable of grasping real-time performance increase. The apparatus for managing performance of a condenser comprises: a vacuum level prediction model generation unit using a factor related to a vacuum level of a collected condenser to generate a condenser vacuum level prediction model; and a vacuum increase amount calculation unit using a difference value between a vacuum level optimum value and a real-time measurement vacuum level which are calculated based on the vacuum level prediction model to calculate a vacuum level increase amount. The method for managing performance of a condenser comprises the steps of: using a factor related to a vacuum level of a collected condenser to generate a condenser vacuum level prediction model; and using a difference value between a vacuum level optimum value and a real-time measurement vacuum level which are calculated based on the vacuum level prediction model to calculate a vacuum level increase amount.

Description

Apparatus and method for managing performance of a condenser

The present invention relates to an apparatus and method for controlling performance of a condenser applied to a steam turbine of a generator.

The steam turbine condenser is a kind of condenser which is made of a closed container and takes the heat of evaporation of the steam flowing by the supplied cooling water to reduce the steam to water.

This steam turbine condenser accounts for the largest portion (about 24%) of the energy loss (waste heat) of the power plant, and is a key element of power generation efficiency management. These condenser performances are operating at ± 3% of design criteria due to various influencing factors, accounting for ± 1.5% of total power generation.

As described above, the steam turbine condenser is a core facility for performance management of the power plant, but performance was managed by the experiential judgment of the operator due to absence of a driving guide corresponding to the field conditions outside the design standard.

Therefore, conventionally, it has been difficult to judge the optimum degree of vacuum of the condenser in real time and to analyze the deterioration factor.

In addition, since the performance of the condenser is influenced by various factors such as seawater temperature / flow rate and tube pollution, it is difficult to diagnose the problem of the element when the performance deterioration occurs. Since the optimal performance of the condenser is changed according to the ambient conditions, There is a problem in that it is difficult to optimize the maintenance period and it is difficult to grasp the amount of real-time performance improvement according to each task when performance management work is performed.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and it is an object of the present invention to provide a method and apparatus for measuring a vacuum degree of a condenser in real time, extracting factors of the degree of vacuum reduction, It has its purpose.

According to an aspect of the present invention, there is provided a performance management apparatus for a condenser, including: a degree of vacuum prediction model generation unit for generating the condensation degree prediction model using the collected degree of vacuum factor; And a degree of vacuum degree updatability calculation unit for calculating a degree of elevation of vacuum degree using the difference between the optimum degree of vacuum degree calculated based on the degree of vacuum degree prediction model and the real time measurement degree of vacuum.

In another aspect of the present invention, there is provided a method for managing performance of a condenser, the method comprising: generating the condensation degree prediction model using the acquired condensation degree factor; And calculating the degree of vacuum degree elevation using the difference between the optimum degree of vacuum degree calculated based on the degree of vacuum degree prediction model and the real time measured degree of vacuum degree.

According to the present invention, it is possible to present the maintenance effect such as the degree of vacuum and the rise of the output through the operation / maintenance, the maintenance effect, and the optimum driving point by analyzing the factors related to the degree of vacuum of the condenser and implementing a prediction model.

1 is a block diagram schematically showing a configuration of a combined power generation system.
2 is a configuration diagram of a performance management apparatus according to an embodiment of the present invention.
3 is a configuration diagram of a control unit of the performance management apparatus according to an embodiment of the present invention.
4 is a flowchart of a method for managing performance of a condenser in accordance with an embodiment of the present invention.
5 is a flowchart of a method for managing performance of a condenser according to an embodiment of the present invention.
6A to 6C are exemplary condenser performance ascendability display screens according to one embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The present invention is capable of various modifications and various embodiments, and specific embodiments are illustrated in the drawings and described in detail in the detailed description. It is to be understood, however, that the invention is not to be limited to the specific embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS In the following description of the present invention, detailed description of known related arts will be omitted when it is determined that the gist of the present invention may be blurred.

The terminology used in this application is used only to describe a specific embodiment and is not intended to limit the invention. The singular expressions include plural expressions unless the context clearly dictates otherwise. In the present application, the terms "comprises" or "having" and the like are used to specify that there is a feature, a number, a step, an operation, an element, a component or a combination thereof described in the specification, But do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Referring to the accompanying drawings, the same or corresponding components are denoted by the same reference numerals, .

First, the steam turbine to which the present invention is applied is a device for converting thermal energy into mechanical energy in the process of converting thermal energy-> mechanical energy-> electrical energy, and the high temperature / high pressure steam generated in the boiler turns the steam turbine to generate electricity do.

Further, the present invention can be applied not only to a power generation system using only a steam turbine but also to a combined power generation system including a gas turbine and a steam turbine.

1 is a block diagram schematically showing a configuration of a combined power generation system. 1, the combined power generation system may include, for example, a gas turbine 110, a steam turbine 130, a boiler 120 (e.g., a batch recovery boiler), and a condenser 140. First, as described above, the gas turbine 110 rotates the turbine using a compressor and a combustor to primarily drive the generator. The high-temperature and high-pressure gas having the turbine rotated by the gas turbine 110 is supplied to the boiler 120. The steam turbine 130 rotates using the high-pressure and high-temperature steam supplied from the boiler 120, And is driven in the secondary. At this time, the high pressure turbine, the intermediate pressure turbine, and the low pressure turbine of the steam turbine 130 are sequentially cooled and condensed in the condenser 140, and the reduced water is returned to the boiler 120 for recycling. In this way, combined power generation is possible.

2 is a configuration diagram of a performance management apparatus 200 for a performance according to an embodiment of the present invention.

The performance management apparatus 200 includes a control unit 202, a display unit 204, and a communication unit 206. And receives a factor included in the factor of the degree of vacuum related to the factor and the real time condensate degree of vacuum through the communication unit 206 of the performance management device 200 of the condenser.

Here, the factor relating to the degree of vacuum of the condenser includes cooling water temperature-related factors, leakage-related factors, cooling water flow-related factors, generator load-related factors, pollution-related factors, vacuum pump-related factors and other related factors.

The cooling water temperature related factor may be, for example, the sum of the cooling water temperature (x1), the cooling water temperature ^ 2 (x2), and the cooling water temperature ^ 3 (x3).

The leak-related factors include, for example, the low-pressure steam bypass V / V front / rear end temperature difference (x20), the intermediate pressure steam bypass V / V front / rear end temperature difference (x21), the HP steam turbine bypass valve front / ), Leakage steam control valve position (x23), sealing vapor-condenser saturation temperature difference (x24), auxiliary steam temperature (x25), (auxiliary steam temperature-saturation temperature difference) ^ 2 (x26). Specifically, the formula for the leak factor is:

Ο Leak related factor = x20 + x21 + x22 + x23 + x24 + (x25 + x26 + x25 · x26)

Further, the cooling water flow rate-related factor may be, for example, the cooling water flow rate (x5), the cooling water flow rate ^ 2, the cooling water flow rate ^ 3, the cooling water flow rate control valve position (x8) And a cooling water auxiliary pump flow rate (x12). Specifically, the expression of the cooling water flow rate-related factor is as follows:

Ο Cooling water flow rate related factor = (x5 + x6 + x7) * x8 + (x11 * x12)

(Where A * B is A + B + A · B).

Further, the generator load-related factors include, for example, the cooling water temperature difference (x4) before and after the cooling water inflow, the combined output (x9), the steam turbine downstream (condenser inlet steam) steam flow rate (x10) x27). Specifically, the equation for the generator load-related factor is as follows:

Ο Generator load factor = x9 + x4 * x10 + x27

In addition, the pollution-related factors are as follows: the differential pressure (x13) of the cooling water pipe cleaning system, the differential pressure of the cooling water inlet pipe (x14), the differential pressure of the cooling water pipe (x15), the differential pressure before and after the cooling water pump, (30) after cleaning the vacuum pump heat exchanger coolant filter, and elapsed time (x31) after cleaning the vacuum pump heat exchanger coolant pipe. Specifically, the expression of the pollution-related factors is as follows:

Ο Pollution factor = x13 + x14 + x15 + x28 + x29 + x30 + x31

In addition, the vacuum pump-related factors include the vacuum pump heat exchanger water pressure differential (x 18) and the vacuum pump-condenser vacuum degree (x 19). Specifically, the equation of the vacuum pump-related factor is as follows:

Ο Vacuum pump related factor = x18 + x19

Further, other relevant factors include the multiple regeneration system front / rear differential pressure (x16) and the multiple regeneration system inlet valve position (x17). Specifically, the equations for other relevant factors are:

Ο Other related factors = x16 * x17

In the control unit 202, the related factor values are calculated using the factors included in the respective related factors. Also, the control unit 202 generates a condensation degree prediction model of the condensate using the calculated relevant factors. The condensate vacuum degree prediction model is generated as follows:

(Vacuum flow rate related factor) A (Cooling water temperature related factor) + B (Leakage related factor) + C (Cooling water flow rate related factor) + D (Generator load related factor) + E ) + G (Other related factors)

(Where A to G are coefficients reflecting the design capacity of each facility and the presence or absence of auxiliary equipment).

The control unit 202 derives the optimum value (y ') of the degree of vacuum of the condensate using the predictive model of the generated condensed degree of vacuum (y). The value at which the generated degree of vacuum (y) becomes the lowest value is the vacuum degree optimum value (y '). However, the coolant temperature-related factor and the generator load-related factor are set as fixed factors because the coolant temperature-related factor and the generator load-related factor are not controllable factors among the factors used in the prediction model of the degree of vacuum of the condenser. The minimum value of the degree of vacuum (y) according to the change of the factor other than the fixed factor is calculated to calculate the degree of vacuum optimum value (y '). The model of the calculated optimal degree of vacuum (y ') can be calculated as follows:

Y = A (cooling water temperature related factor) + B (leakage related factor) + C (cooling water flow rate related factor) + D (generator load factor) + E (pollution related factor) ') + G (other relevant arguments')

The control unit 202 also subtracts the vacuum degree y '' of the condenser received in real time via the communication unit 206 from the calculated vacuum degree optimum value y 'to calculate the difference value (Df value).

The control unit 202 calculates a model using the degree of vacuum related factor with respect to the calculated difference value. The difference value model is as follows:

ΟDf = A (Cooling water temperature related factor) + B (Leak related factor - Leak related factor) + C (Cooling water flow related factor - Cooling water flow related factor) + D (Generator load related factor) + E + F (Vacuum pump related factor - Vacuum pump related factor ') + G (Other related factor - Other related factor')

In addition, the control unit 202 calculates a value by which the difference value can be minimized when the respective vacuum degree related factor values are changed in the difference value model. Here, the related parameter values that can be changed exclude cooling water temperature related factors and generator load related factors. The difference value model is used to calculate the degree of vacuum elevation according to the change of the factor of each degree of vacuum. That is, the control unit 202 can calculate the degree of vacuum increase for each controllable related factor.

The output rise can be realized according to the calculated degree of vacuum degree rise.

The display unit 204 displays the degree of vacuum elevation by the calculated controllable related factors.

3 is a configuration diagram of the controller 202 of the performance management apparatus according to an embodiment of the present invention.

The control unit 202 includes a data collecting unit 300, a degree of vacuum prediction model generating unit 302, a degree of vacuum degree calculating unit 304, a degree of vacuum degree optimum-real-time degree of vacuum calculating unit 306, .

The data collecting unit 300 collects the factors included in the factor of the degree of vacuum and the real-time condensate degree of vacuum.

Here, the factor relating to the degree of vacuum of the condenser includes cooling water temperature-related factors, leakage-related factors, cooling water flow-related factors, generator load-related factors, pollution-related factors, vacuum pump-related factors and other related factors.

The cooling water temperature related factor may be, for example, the sum of the cooling water temperature (x1), the cooling water temperature ^ 2 (x2), and the cooling water temperature ^ 3 (x3).

The leak-related factors include, for example, the low-pressure steam bypass V / V front / rear end temperature difference (x20), the intermediate pressure steam bypass V / V front / rear end temperature difference (x21), the HP steam turbine bypass valve front / ), Leakage steam control valve position (x23), sealing vapor-condenser saturation temperature difference (x24), auxiliary steam temperature (x25), (auxiliary steam temperature-saturation temperature difference) ^ 2 (x26). Specifically, the formula for the leak factor is:

Ο Leak related factor = x20 + x21 + x22 + x23 + x24 + (x25 + x26 + x25 · x26)

Further, the cooling water flow rate-related factor may be, for example, the cooling water flow rate (x5), the cooling water flow rate ^ 2, the cooling water flow rate ^ 3, the cooling water flow rate control valve position (x8) And a cooling water auxiliary pump flow rate (x12). Specifically, the expression of the cooling water flow rate-related factor is as follows:

Ο Cooling water flow rate related factor = (x5 + x6 + x7) * x8 + (x11 * x12)

(Where A * B is A + B + A · B).

Further, the generator load-related factors include, for example, the cooling water temperature difference (x4) before and after the cooling water inflow, the combined output (x9), the steam turbine downstream (condenser inlet steam) steam flow rate (x10) x27). Specifically, the equation for the generator load-related factor is as follows:

Ο Generator load factor = x9 + x4 * x10 + x27

In addition, the pollution-related factors are as follows: the differential pressure (x13) of the cooling water pipe cleaning system, the differential pressure of the cooling water inlet pipe (x14), the differential pressure of the cooling water pipe (x15), the differential pressure before and after the cooling water pump, (30) after cleaning the vacuum pump heat exchanger coolant filter, and elapsed time (x31) after cleaning the vacuum pump heat exchanger coolant pipe. Specifically, the expression of the pollution-related factors is as follows:

Ο Pollution factor = x13 + x14 + x15 + x28 + x29 + x30 + x31

In addition, the vacuum pump-related factors include the vacuum pump heat exchanger water pressure differential (x 18) and the vacuum pump-condenser vacuum degree (x 19). Specifically, the equation of the vacuum pump-related factor is as follows:

Ο Vacuum pump related factor = x18 + x19

Further, other relevant factors include the multiple regeneration system front / rear differential pressure (x16) and the multiple regeneration system inlet valve position (x17). Specifically, the equations for other relevant factors are:

Ο Other related factors = x16 * x17

The vacuum degree predicting model generation unit 302 calculates the related factor values using the factors included in the respective correlation factors. Further, the vacuum degree predicting model generating unit 302 generates a plurality of vacuum degree predicting models using the calculated related factors. The condensate vacuum degree prediction model is generated as follows:

(Vacuum flow rate related factor) A (Cooling water temperature related factor) + B (Leakage related factor) + C (Cooling water flow rate related factor) + D (Generator load related factor) + E ) + G (Other related factors)

(Where A to G are coefficients reflecting the design capacity of each facility and the presence or absence of auxiliary equipment).

Subsequently, the vacuum degree optimum value calculation unit 304 derives the optimum value (y ') of the vacuum degree by using the generated vacuum degree prediction model. The value at which the generated degree of vacuum (y) becomes the lowest value is the vacuum degree optimum value (y '). However, the coolant temperature-related factor and the generator load-related factor among the factors used in the prediction model of the degree of vacuum of the condenser are set as fixed factors since they are not adjustable factors. The minimum value of the degree of vacuum (y) according to the change of the factor other than the fixed factor is calculated to calculate the degree of vacuum optimum value (y '). The model of the calculated optimal degree of vacuum (y ') can be calculated as follows:

Y = A (cooling water temperature related factor) + B (leakage related factor) + C (cooling water flow rate related factor) + D (generator load factor) + E (pollution related factor) ') + G (other relevant arguments')

The vacuum degree optimum value-real time degree of vacuum calculating unit 306 subtracts the degree of vacuum (y ") of the condenser received in real time from the calculated degree of vacuum degree value y 'to calculate the difference value (Df value). The model for the difference values is:

D is the cooling water temperature related factor + B (Leakage related factor - Leakage related factor) + C (Cooling water flow rate related factor - Cooling water flow rate related factor) + D (Generator load related factor) + E (Pollution related factor - + F (Vacuum pump related factor - Vacuum pump related factor ') + G (Other related factor - Other related factor')

Then, the degree-of-vacuum-up-capacity calculating unit 308 calculates a value by which the difference value can be minimized when the respective degree-of-vacuum-related factor values are changed in the difference value model. Here, the cooling water temperature-related factors and the oscillator load-related factors are excluded from the related factor values that can be changed. The degree-of-vacuum-up-able-amount calculating unit 308 calculates the degree of vacuum-rise capable of changing the degree of vacuum associated with each factor.

4 is a flowchart of a method for managing performance of a condenser in accordance with an embodiment of the present invention.

The real time degree of vacuum and the x factor value constituting the degree of vacuum factor are received through the communication unit 206 to collect necessary data (S400).

The factors related to the degree of vacuum are cooling water temperature related factors, leakage related factors, cooling water flow related factors, generator load related factors, pollution related factors, vacuum pump related factors and other related factors.

Here, the cooling water temperature related factor may be, for example, the sum of the cooling water temperature (x1), the cooling water temperature ^ 2 (x2), and the cooling water temperature ^ 3 (x3).

The leak-related factors include, for example, the low-pressure steam bypass V / V front / rear end temperature difference (x20), the intermediate pressure steam bypass V / V front / rear end temperature difference (x21), the HP steam turbine bypass valve front / ), Leakage steam control valve position (x23), sealing vapor-condenser saturation temperature difference (x24), auxiliary steam temperature (x25), (auxiliary steam temperature-saturation temperature difference) ^ 2 (x26).

Further, the cooling water flow rate-related factor may be, for example, the cooling water flow rate (x5), the cooling water flow rate ^ 2, the cooling water flow rate ^ 3, the cooling water flow rate control valve position (x8) And a cooling water auxiliary pump flow rate (x12).

Further, the generator load-related factors include, for example, the cooling water temperature difference (x4) before and after the cooling water inflow, the combined output (x9), the steam turbine downstream (condenser inlet steam) steam flow rate (x10) x27).

In addition, the pollution-related factors are as follows: the differential pressure (x13) of the cooling water pipe cleaning system, the differential pressure of the cooling water inlet pipe (x14), the differential pressure of the cooling water pipe (x15), the differential pressure before and after the cooling water pump, (30) after cleaning the vacuum pump heat exchanger coolant filter, and elapsed time (x31) after cleaning the vacuum pump heat exchanger coolant pipe.

In addition, the vacuum pump-related factors include the vacuum pump heat exchanger water pressure differential (x 18) and the vacuum pump-condenser vacuum degree (x 19).

Further, other relevant factors include the multiple regeneration system front / rear differential pressure (x16) and the multiple regeneration system inlet valve position (x17).

A vacuum degree prediction model is generated using the collected data (S402). In order to generate the vacuum degree prediction model, the vacuum degree related factors are required. The values of the respective vacuum degree factors are as follows:

Ο Cooling water related factor = x1 + x2 + x3

Ο Leak related factor = x20 + x21 + x22 + x23 + x24 + (x25 + x26 + x25 · x26)

Ο Cooling water flow rate related factor = (x5 + x6 + x7) * x8 + (x11 * x12)

(Where A * B is A + B + A · B).

Ο Generator load factor = x9 + x4 * x10 + x27

Ο Pollution factor = x13 + x14 + x15 + x28 + x29 + x30 + x31

Ο Vacuum pump related factor = x18 + x19

Ο Other related factors = x16 * x17

A plurality of vacuum degree prediction models are generated using the calculated respective vacuum degree factors as follows:

(Vacuum flow rate related factor) A (Cooling water temperature related factor) + B (Leakage related factor) + C (Cooling water flow rate related factor) + D (Generator load related factor) + E ) + G (Other related factors)

Subsequently, the optimum vacuum degree of the condenser is calculated using the condensation degree prediction model of the condenser (S404).

The value at which the generated degree of vacuum (y) becomes the lowest value is the vacuum degree optimum value (y '). However, the coolant temperature-related factor and the generator load-related factor among the factors used in the prediction model of the degree of vacuum of the condenser are set as fixed factors since they are not adjustable factors. The minimum value of the degree of vacuum (y) according to the change of the factor other than the fixed factor is calculated to calculate the degree of vacuum optimum value (y '). The model of the calculated optimal degree of vacuum (y ') can be calculated as follows:

Y = A (cooling water temperature related factor) + B (leakage related factor) + C (cooling water flow rate related factor) + D (generator load factor) + E (pollution related factor) ') + G (other relevant arguments')

5 is a flowchart of a method for managing performance of a condenser according to an embodiment of the present invention.

The vacuum degree of the condenser is measured in real time (S500).

The difference between the measured real-time vacuum degree and the optimum vacuum degree is calculated (S501). Specifically, a model using the degree of vacuum related factor for the calculated difference value (Df) is generated as follows:

ΟDf = A (Cooling water temperature related factor) + B (Leak related factor - Leak related factor) + C (Cooling water flow related factor - Cooling water flow related factor) + D (Generator load related factor) + E + F (Vacuum pump related factor - Vacuum pump related factor ') + G (Other related factor - Other related factor')

Subsequently, the degree of vacuum degree increase according to the change of the factor of the degree of vacuum related factor of the degree of vacuum difference value is calculated using the model of the difference value (S504).

Here, the related parameter values that can be changed exclude cooling water temperature related factors and generator load related factors. The difference value model is used to calculate the degree of vacuum elevation according to the change of the factor of each degree of vacuum. That is, the control unit 202 can calculate the degree of vacuum increase for each controllable related factor.

The output rise can be realized according to the calculated degree of vacuum degree rise.

The output restoration capacity for each degree of vacuum related factor according to the degree of vacuum rise is as follows.

Power ② = f (Leak Related Factor - Leak Related Factor ')

Power ③ = f (Cooling water flow rate related factor - Cooling water flow rate related factor ')

Power ⑤ = f (pollution related factor - pollution related factor ')

Power ⑥ = f (Vacuum pump related factor - Vacuum pump related factor ')

Power ⑦ = f (other related factors - other related factors')

※ f (x) = vacuum degree ~ complex output relation function (general function for compliance with contract according to contract)

FIG. 6 is a screen showing an example of a possible performance increase of a condenser according to an embodiment of the present invention.

The real time condensate vacuum degree and the optimum vacuum degree according to each unit are displayed, and the degree of vacuum degree increase according to the related factor change is shown. Also, the peripherals related cleaning / maintenance histories according to each unit are displayed together.

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

200 condenser performance management apparatus 202 control unit
204 display section 206 communication section
300 data collection unit 302 The degree of vacuum degree prediction model generation unit
304 Vacuum degree optimum value calculation unit
306 Vacuum degree optimum value - Real time degree of vacuum calculation part
308 Vacuum degree ascendability calculation unit

Claims (11)

A degree of vacuum prediction model generating unit for generating the condensation degree prediction model using the collected factors of the degree of vacuum related factor; And
And a degree of vacuum degree updatability calculation unit for calculating a degree of elevation of vacuum degree using the difference between the optimum degree of vacuum degree calculated based on the degree of vacuum degree prediction model and the real time measurement degree of vacuum.
The method according to claim 1,
A data collecting unit collecting the plurality of vacuum degree related factors and the real time measurement vacuum degree; And
And a vacuum degree optimum value calculation unit for calculating the vacuum degree optimum value.
The method of claim 2,
Wherein the condensation degree related factor is at least one of a cooling water temperature related factor, a leakage related factor, a cooling water flow rate related factor, a pollution related factor, a generator load related factor, and a vacuum pump related factor. The method of claim 3,
Wherein the optimum degree of vacuum degree is a lowest value among degrees of vacuum degree values calculated using the degree of vacuum degree prediction model.
The method of claim 4,
Calculating a degree of vacuum degree increase using the difference between the optimum degree of vacuum degree and the real time measurement degree of vacuum,
Wherein the effective factor is at least one of a leakage related factor, a cooling water flow rate related factor, a pollution related factor, and a vacuum pump related factor.
The method of claim 5,
Further comprising a display unit for displaying a degree of vacuum degree increase according to the change of the effective factor value.
Generating the plurality of vacuum degree prediction models using the collected plurality of vacuum degree related factors; And
And calculating a degree of vacuum degree elevation using the difference between the optimum degree of vacuum degree calculated based on the degree of vacuum degree prediction model and the real time measurement degree of vacuum degree.
The method of claim 7,
Wherein the optimal degree of vacuum degree is a lowest value among degrees of vacuum degree values calculated using the degree of vacuum degree prediction model.
The method of claim 8,
Wherein the condensation degree related factor is at least one of a cooling water temperature related factor, a leakage related factor, a cooling water flow rate related factor, a pollution related factor, a generator load related factor, and a vacuum pump related factor.
The method of claim 9,
Calculating a degree of vacuum degree increase using the difference between the optimum degree of vacuum degree and the real time measurement degree of vacuum,
Wherein the effective factor is at least one of a leakage related factor, a cooling water flow rate related factor, a pollution related factor, and a vacuum pump related factor.
The method of claim 10,
Further comprising the step of displaying a degree of vacuum degree increase according to the change of the effective factor value.

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