KR102036192B1 - Turbine drive control apparatus and method according to remaining life - Google Patents

Abstract

The present invention relates to a turbine drive control apparatus and method according to the remaining life of determining the remaining life of a specific parameter of the turbine, and controlling the driving of the specific parameter to maximize the remaining life in accordance with the maintenance time based on the determined remaining life. It is about.
Turbine drive control apparatus according to the remaining life according to an embodiment of the present invention is a measurement unit for measuring a specific component occurring in a specific parameter of the turbine, and the remaining life of the specific parameter according to the specific component value of the specific parameter A storage unit configured to determine a residual life of a specific parameter according to the specific component value measured in real time based on the information stored in the storage unit, a storage unit based on the remaining life of the determined specific parameter. And a control unit for controlling the driving of the turbine to maximize consumption of the remaining life in accordance with a set maintenance time point.

Description

Turbine drive control apparatus and method according to remaining life}

The present invention relates to a turbine drive control apparatus and method according to the remaining life, more specifically to determine the remaining life of the specific parameters of the turbine, and to determine the maximum remaining life in accordance with the maintenance time based on the determined remaining life It relates to a turbine drive control apparatus and method according to the remaining life of the control of the drive of the parameter.

When the turbine is driven quickly, the stress value generated in the turbine is greatly increased. The higher the stress value of the turbine, the higher the life span of the turbine, and thus the remaining service life. Furthermore, the combustor, blades, etc. of the turbine are vulnerable parts that are prone to failure when the turbine is driven quickly, and the weaker parts are more prone to failure as the remaining life decreases. However, since the remaining life of each parameter of the turbine is not known at the time of maintenance of the turbine, it is not possible to take measures accordingly, and there is a problem that the failure occurs because the remaining life of the weak part of the turbine is short before the maintenance time is reached. there was. In addition, there is a problem that the maintenance is performed several times even though the remaining life of each parameter of the turbine is large.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-described problems, and an object of the present invention is to provide a turbine driving control apparatus and method according to the remaining service life of checking the remaining service life of a specific parameter of the turbine and adjusting the inspection time.

In addition, the present invention is to solve the above-described problems, turbine drive control device according to the remaining life of the control of the drive of the turbine to check the remaining life of the specific parameters of the turbine to consume all the remaining life in accordance with the preset inspection time And to provide a method.

In addition to the technical task of the present invention mentioned above, other features and advantages of the present invention will be described below, or from such description and description will be clearly understood by those skilled in the art.

Turbine drive control apparatus according to the remaining life according to an embodiment of the present invention for achieving the above object is a measuring unit for measuring a specific component occurring in a specific parameter of the turbine, and a specific parameter of the specific component value of the specific parameter A storage unit for storing the remaining life, a determination unit for determining the remaining life of the specific parameter according to the specific component value measured in real time based on the information stored in the storage unit, and based on the remaining life of the determined specific parameter. It includes a control unit for controlling the drive of the turbine to maximize the remaining life in accordance with the preset maintenance time.

Here, the specific parameter is one configuration of the turbine which is likely to cause a failure according to the remaining life when the turbine is driven, and the specific component is a component that is changed when the specific parameter is driven.

The apparatus may further include an inspecting unit that checks the validity of the specific component value, and the inspecting unit determines that the characteristic component value is not valid when the specific component value is higher or lower than a mean of the specific component value by a certain level or more.

In addition, the average of the specific component values is stored in the storage unit or calculated in real time through the specific component values measured in real time in the measurement unit.

In addition, the determination unit determines a specific component value having the same value as the specific component measured in real time among the specific components stored in the storage unit, and determines the remaining life of the specific parameter based on the determined specific component value.

In addition, if it is determined that the remaining life is not consumed at the time of maintenance when the specific parameter is constantly driven, the control unit increases the lifetime consumption rate of the specific parameter.

In addition, the control unit increases the lifespan rate by controlling the turbine so that the turbine starts driving and quickly reaches a point where normal driving is possible.

In addition, the control unit increases the lifespan rate by controlling the turbine to reach the point where the turbine stops driving and stops driving completely.

In addition, if it is determined that all the remaining life is consumed before the maintenance time when the specific parameter is constantly driven, the control unit reduces the lifetime consumption rate of the specific parameter.

In addition, the control unit reduces the consumption rate by controlling the turbine so that the turbine starts to drive and arrives slowly to the point where normal operation is possible.

The controller also controls the turbine to slow down to the point where the turbine stops running and the drive is completely stopped, reducing the lifespan rate.

In addition, the controller sets a time point at which it is determined that all remaining life will be consumed when the specific parameter is constantly driven.

In addition, the measurement unit measures a specific component of a specific parameter in a section up to the point where the turbine starts driving and can be operated normally, or measures a specific component of a specific parameter in a section up to the point where the turbine stops driving and the driving is completely stopped. Measure

In addition, the control unit controls the driving of the specific parameter in accordance with the maintenance time, and then re-determines the remaining life according to the specific component value measured in real time.

Turbine drive control method according to the remaining life according to an embodiment of the present invention for achieving the above object is the step of storing the remaining life of the specific parameter according to the specific component value generated in the specific parameter of the turbine, and the specific parameter in real time Determining a specific component occurring in the system, determining a remaining life of the specific parameter according to the specific component value measured in real time based on the stored information, and preset maintenance based on the remaining life of the determined specific parameter. Controlling driving of a specific parameter to maximize consumption of remaining life in time.

Further, in the step of determining the remaining life of a specific parameter, it is determined as a specific component value having the same value as the specific component measured in real time among the stored specific components, and determines the remaining life of the specific parameter based on the determined specific component value do.

In addition, in the step of controlling the driving of the specific parameter, if it is determined that the remaining life is not consumed at the time of maintenance when the specific parameter is constantly driven, the lifetime consumption rate of the specific parameter is increased.

In addition, in the step of controlling the driving of the specific parameter, the turbine is controlled so that the turbine starts driving and arrives quickly to the point where the normal driving is possible, thereby increasing the lifetime consumption rate.

In addition, in the step of controlling the driving of a specific parameter, the turbine is controlled to reach the point where the turbine stops driving and the driving is completely stopped, thereby increasing the lifetime consumption rate.

In addition, in the step of controlling the driving of a specific parameter, when it is determined that all the remaining life is consumed before the maintenance time when the specific parameter is constantly driven, the lifetime consumption rate of the specific parameter is reduced.

In addition, in the step of controlling the driving of a specific parameter, the turbine is controlled so that the turbine starts driving and arrives slowly to the point where normal driving is possible, thereby reducing the life span.

In addition, in the step of controlling the driving of a specific parameter, the turbine is controlled so that the turbine stops driving and arrives slowly to the point where the driving is completely stopped, thereby reducing the lifetime consumption rate.

Further, in the step of controlling the driving of the specific parameter, a time point at which it is determined that all remaining life is consumed when the specific parameter is constantly driven is set as the maintenance point.

In addition, in the step of measuring a specific component, the section to the point where the turbine starts to drive and to the point where the normal drive can be measured, the specific component of the specific parameter, the point to the point where the turbine stops driving and the drive is completely stopped. Measure specific components of specific parameters in

Further, in the step of determining the remaining life of the specific parameter, if the control unit controls the driving of the specific parameter in accordance with the maintenance time point, the remaining life is re-determined according to the specific component value measured in real time.

Turbine drive control apparatus and method according to the remaining life according to an embodiment of the present invention can determine the remaining life of a specific parameter by confirming the lifetime consumption rate of the specific parameter of the turbine.

In addition, the turbine drive control apparatus and method according to the remaining life can confirm the remaining life of a specific parameter of the turbine to consume all of the remaining life in accordance with the inspection time.

In addition, the turbine drive control apparatus and method according to the remaining life can check the inspection time by checking the remaining life of the specific parameters of the turbine.

In addition, other features and advantages of the present invention may be newly understood through the embodiments of the present invention.

1 is a view showing the configuration of a turbine drive control apparatus according to the remaining life according to an embodiment of the present invention.
2 is a view showing an increase in lifespan consumption rate according to an embodiment of the present invention.
3 is a view showing an increase in lifespan consumption rate according to an embodiment of the present invention.
4 is a view showing a reduction in the lifetime consumption rate according to an embodiment of the present invention.
5 is a view showing a reduction in the lifetime consumption rate according to an embodiment of the present invention.
6 is a view showing a turbine drive control method according to the remaining life according to an embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention.

In order to clearly describe the present invention, parts irrelevant to the description are omitted, and like reference numerals designate like elements throughout the specification.

Throughout the specification, when a part is "connected" to another part, this includes not only "directly connected" but also "electrically connected" with another element in between. . In addition, when a part is said to "include" a certain component, which means that it may further include other components, except to exclude other components unless otherwise stated.

When a portion is referred to as being "above" another portion, it may be just above the other portion or may be accompanied by another portion in between. In contrast, when a part is mentioned as "directly above" another part, no other part is involved between them.

Terms such as first, second, and third are used to describe various parts, components, regions, layers, and / or sections, but are not limited to these. These terms are only used to distinguish one part, component, region, layer or section from another part, component, region, layer or section. Accordingly, the first portion, component, region, layer or section described below may be referred to as the second portion, component, region, layer or section without departing from the scope of the invention.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the singular forms “a,” “an,” and “the” include plural forms as well, unless the phrases clearly indicate the opposite. As used herein, the meaning of "comprising" embodies a particular characteristic, region, integer, step, operation, element and / or component, and the presence of other characteristics, region, integer, step, operation, element and / or component It does not exclude the addition.

Terms indicating relative space such as "below" and "above" may be used to more easily explain the relationship of one part to another part shown in the drawings. These terms are intended to include other meanings or operations of the device in use with the meanings intended in the figures. For example, if the device in the figure is reversed, any parts described as being "below" of the other parts are described as being "above" the other parts. Thus, the exemplary term "below" encompasses both up and down directions. The device can be rotated 90 degrees or at other angles, the terms representing relative space being interpreted accordingly.

Unless defined otherwise, all terms including technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art. Commonly defined terms used are additionally interpreted to have a meaning consistent with the related technical literature and the presently disclosed contents, and are not interpreted in an ideal or very formal sense unless defined.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention.

1 is a view showing the configuration of a turbine drive control apparatus according to the remaining life according to an embodiment of the present invention.

Referring to FIG. 1, the turbine driving control apparatus 100 according to the remaining lifespan according to an embodiment of the present invention includes a measuring unit 110, a storage unit 120, a determination unit 130, an inspection unit 140, and a control unit ( 150).

The measurement unit 110 may measure a specific component generated in a specific parameter of the turbine. Here, the specific parameter may be a configuration of a turbine in which a failure is likely to occur according to the remaining life when the turbine is driven. In addition, the specific component may be a component that changes when the specific parameter is driven. As an example, the particular parameter may be a blade of the compressor, which is one component of the turbine, and the particular component may be vibration. That is, the blade is rotated when the turbine is driven, and thus the blade may vibrate, and the vibration may be a specific component that is changed when the turbine is driven. As another example, the particular parameter may be a boiler, which is one component of the turbine, and the particular component may be a steam temperature. In other words, when the turbine is driven, the boiler heats the water, and thus the temperature of the steam may change.

The measuring unit 110 measures a specific component of a specific parameter in a section up to the point where the turbine starts driving and can be normally driven, or specifies a specific parameter in a section up to the point where the turbine stops driving and stops driving completely. The component can be measured. That is, the measurement unit 110 may measure a specific component in a specific parameter in a start-up period and a shut-down period for driving the turbine. Here, the point at which the normal driving is possible is a point at which the turbine is sufficiently heated and constantly driven, and may be a point capable of sufficiently converting energy of fluid such as water, gas, and steam into mechanical work even if the turbine is driven constantly.

The storage unit 120 may store the remaining life of the specific parameter according to the specific component value of the specific parameter. The storage unit 120 may store in advance a table of the relationship between the specific component value of the specific parameter and the remaining life. The storage unit 120 may store a specific component value of a specific parameter measured by the measuring unit 110 and store a remaining life according to the specific component value.

The determination unit 130 may determine the remaining life of the specific parameter according to the specific component value measured in real time based on the table stored in the storage 120. Specifically, the determination unit 130 matches a specific component value identical to the specific component measured in real time among the characteristic components stored in the storage unit 120 and determines the remaining life of the specific parameter according to the matched specific component value. Can be. As an example, when the steam temperature of the boiler measured in real time by the measuring unit 110 is 380 ° C, the determination unit 130 has a remaining life that is stored to correspond to 380 ° C among the steam temperatures stored in the storage unit 120. It can be determined by the remaining life of a specific parameter according to the specific component value measured in real time.

The inspection unit 140 may check the validity of the specific component value. The inspection unit 140 may determine that the specific component value is not effective when the specific component value is higher or lower than the average of the specific component value by more than a predetermined value. Here, the average of the specific component values may be stored in the storage 120, or may be calculated in real time through the specific component values measured by the inspection unit 140 in real time. For example, the average of the steam temperature of the boiler is 380 ℃, when the steam temperature of the boiler measured in real time by the measuring unit 140 is 200 ℃ can determine that the inspection unit 140 is not a valid value. Here, the criterion for determining that the specific component value is not valid may be set differently for each specific parameter. In addition, a criterion for determining whether the characteristic component value is valid may be set by determining whether the existing specific component values are measured within a range through the specific component values stored in the storage unit 120. The inspection unit 140 may determine the validity of the specific component value measured in real time by the measuring unit 130, and if the specific component value is valid, the determination unit 130 may determine the remaining life of the specific parameter according to the specific component value. .

The controller 150 may control the driving of the turbine so that the remaining life is maximized in accordance with the preset maintenance time based on the determined remaining life of the specific parameter. For example, if it is determined that the remaining life is not consumed at the time of maintenance when the specific parameter is constantly driven, the controller 150 may increase the lifetime consumption rate of the specific parameter. For example, when it is determined that the remaining life of a specific parameter is 30% or more at a preset maintenance time, the controller 150 may control the driving of the specific parameter so that the remaining life of the specific parameter is 100% consumed at the maintenance time. The controller 150 may increase the lifespan rate by controlling the turbine so that the turbine starts to drive quickly and reaches a point where the normal drive is possible. The controller 150 may control the turbine to be driven faster so that the controller 150 can reach the point where the normal driving is possible. At this time, in order to increase the speed of the turbine to drive quickly, the speed of driving the specific parameter must also increase quickly, the lifetime consumption rate of the specific parameter can be increased. The controller 150 may control the driving of the specific parameter such that the remaining life is reduced by increasing the lifetime consumption rate of the specific parameter.

In addition, the controller 150 may increase the lifespan rate by controlling the turbine to reach the point where the turbine stops driving and reaches a point where the driving is completely stopped. The controller 150 may control the turbine to stop driving while decreasing the speed more quickly to reach the point where the turbine is completely stopped. In this case, in order to quickly reduce the speed of the turbine drive, the speed of driving a specific parameter must also be reduced quickly, so the lifetime consumption rate of a specific parameter can be increased. The controller 150 may control the driving of the specific parameter such that the remaining life is reduced by increasing the lifetime consumption rate of the specific parameter.

As another example, when it is determined that all of the remaining life is consumed before the maintenance time, the controller 150 may reduce the lifespan rate of the specific parameter. For example, when it is determined that the remaining life of a specific parameter is to be consumed when the preset maintenance time is over one month remaining, the controller 150 controls driving of the specific parameter such that the remaining life of the specific parameter is consumed in accordance with the maintenance time. can do. The controller 150 may control the turbine to slowly reach the point where the turbine starts driving and reaches a point where normal driving is possible, thereby reducing the lifespan rate. The controller 150 may control the turbine to drive more slowly to reach the point where the normal driving is possible. In this case, in order to slowly increase the speed at which the turbine is driven, the speed at which the specific parameter is driven must also be increased slowly, and thus, the lifetime consumption rate of the specific parameter can be reduced. The controller 150 may control the driving of the specific parameter such that the remaining life is increased by reducing the lifetime consumption rate of the specific parameter.

In addition, the controller 150 may control the turbine to slowly reach the point where the turbine stops driving and stops driving completely, thereby reducing the lifespan rate. The controller 150 may control the turbine to stop driving while decreasing the speed to reach the point where the turbine is completely stopped. In this case, in order to slowly reduce the speed at which the turbine is driven, the speed at which the specific parameter is driven must also be slowly reduced, and thus, the lifetime consumption rate of the specific parameter can be reduced. The controller 150 may control the driving of the specific parameter such that the remaining life is increased by reducing the lifetime consumption rate of the specific parameter.

In addition, the controller 150 may set a time point at which it is determined that all remaining life will be consumed when the specific parameter is constantly driven. The controller 150 may change the maintenance time without controlling the driving of the specific parameter so that the specific parameter may be maintained according to the time when the remaining life of the specific parameter is consumed.

In addition, when the maintenance time is arbitrarily changed, the controller 150 may control the driving of the turbine according to the changed maintenance time. For example, when a maintenance point is arbitrarily changed by a mechanic who maintains the turbine, a manager who manages the turbine, or the like, the controller 150 may control the driving of the turbine in accordance with the changed maintenance point. For example, when the maintenance time point is changed to one week after the existing maintenance time point, the controller 150 may control the turbine so that the remaining life of a specific parameter is consumed in accordance with the changed maintenance time point.

In addition, the controller 150 controls the turbine so that the remaining life of a specific parameter is maximized in accordance with the maintenance time. If it is determined that the remaining life of a specific parameter is consumed when the maintenance time is changed for a certain time, the maintenance time is adjusted according to the time limit. Can be changed. For example, if the remaining life of a specific parameter is controlled to be maximized in accordance with the maintenance time, 90% of the remaining life of the specific parameter may be consumed at the maintenance time. At this time, if the turbine is further driven for 5 days at the preset maintenance time, the controller 150 may change the maintenance time back 5 days if it is determined that all remaining life of the specific parameter is consumed.

According to an embodiment of the present invention, the turbine drive control apparatus according to the remaining life may determine the remaining life of the specific parameter by checking the life consumption rate of the specific parameter of the turbine. In addition, the turbine drive control apparatus and method according to the remaining life can confirm the remaining life of a specific parameter of the turbine to consume all of the remaining life in accordance with the inspection time. In addition, the turbine drive control apparatus and method according to the remaining life can check the inspection time by checking the remaining life of the specific parameters of the turbine.

2 is a view showing an increase in lifespan consumption rate according to an embodiment of the present invention.

Referring to FIG. 2, the solid line (a) shows the arrival time to the point where the existing turbine can be normally driven when the turbine is driven, and the dotted line (b) is normal when the turbine is controlled to increase the lifetime consumption rate of the specific parameter. It can represent the arrival time to the point where the drive is possible.

Depending on the speed at which the turbine starts to drive and reaches a point where normal operation is possible, the lifetime consumption of a particular parameter may vary, and thus the remaining life of that particular parameter may vary. The measurement unit 110 may measure a specific component of a specific parameter in a section up to the point where the turbine starts driving and can be normally driven. In this case, the time when the turbine reaches the point where the normal driving is possible may be t1. The determination unit 120 may determine the remaining life of the specific parameter based on the specific component measured in real time by the measuring unit 110. The controller 150 may control the driving of the turbine so that the remaining life is maximized at the preset maintenance time based on the determined remaining life. If it is determined that the remaining life is not consumed at the time of maintenance when the specific parameter is constantly driven, the controller 150 may increase the lifetime consumption rate of the specific parameter. The controller 150 may control the turbine so that the speed at which the turbine starts driving and reaches a point where the normal driving is possible is increased. That is, the time at which the turbine reaches the point at which the turbine can be driven normally by the control of the controller 150 may be t2. Turbines must be driven faster in order to reach high speeds to the point where they can be driven normally, and in order to do so, the speed of driving certain parameters can be increased, so the lifetime consumption of certain parameters can be increased. Accordingly, the remaining life of a particular parameter can be reduced.

3 is a view showing an increase in lifespan consumption rate according to an embodiment of the present invention.

Referring to FIG. 3, the solid line (c) shows the arrival time to the point where the existing turbine can be normally driven when the turbine is being driven, and the dotted line (d) shows the turbine when the turbine is controlled to increase the lifetime consumption rate of the specific parameter. The arrival time to this point of complete stop can be represented.

Depending on the speed at which the turbine stops driving and reaches the point where the drive is completely stopped, the lifetime consumption of a particular parameter may vary and thus the remaining life of that particular parameter may vary. The measuring unit 110 may measure a specific component of a specific parameter in a section up to the point where the turbine stops driving and the driving is completely stopped. In this case, the time when the turbine reaches the point where the normal driving is possible may be t1. The determination unit 120 may determine the remaining life of the specific parameter based on the specific component measured in real time by the measuring unit 110. The controller 150 may control the driving of a specific parameter such that the remaining life is maximized according to a preset maintenance time based on the determined remaining life. If it is determined that the remaining life is not consumed at the time of maintenance when the specific parameter is constantly driven, the controller 150 may increase the lifetime consumption rate of the specific parameter. The controller 150 may control the turbine so that the speed at which the turbine stops driving and reaches a point where the driving is completely stopped is increased. That is, the time that reaches the point where the turbine is completely stopped by the control of the controller 150 may be t2. The turbine must stop running faster in order to reach the point of complete stop at a faster rate, and in order to do so, the speed of stopping the drive of a specific parameter must be increased, so the lifetime consumption rate of a particular parameter can be increased. Accordingly, the remaining life of a particular parameter can be reduced.

4 is a view showing a reduction in the lifetime consumption rate according to an embodiment of the present invention.

Referring to FIG. 4, the solid line e represents the arrival time to the point where normal driving is possible when the existing turbine is driven, and the dotted line f is normal when the turbine is controlled to reduce the lifetime consumption rate of a specific parameter. It can represent the arrival time to the point where the drive is possible.

Depending on the speed at which the turbine starts to drive and reaches a point where normal operation is possible, the lifetime consumption of a particular parameter may vary, and thus the remaining life of that particular parameter may vary. The measurement unit 110 may measure a specific component of a specific parameter in the section 10 up to the point where the turbine starts driving and can be normally driven. In this case, the time when the turbine reaches the point where the normal driving is possible may be t1. The determination unit 120 may determine the remaining life of the specific parameter based on the specific component measured in real time by the measuring unit 110. The controller 150 may control the driving of a specific parameter such that the remaining life is maximized according to a preset maintenance time based on the determined remaining life. The controller 150 may reduce the lifetime consumption rate of the specific parameter when it is determined that all of the remaining life is consumed before the maintenance time when the specific parameter is constantly driven. The controller 150 may control the turbine so that the speed at which the turbine starts driving and reaches a point where the normal driving is possible is slowed. That is, the time at which the turbine reaches the point at which the turbine can be driven normally by the control of the controller 150 may be t2. The turbine must be driven slower to reach a slower speed to the point where it can be driven normally, and in order to do so, the drive speed of a specific parameter must be slowed down, so the lifetime consumption rate of a specific parameter can be reduced. Accordingly, the remaining life of a particular parameter can be increased.

5 is a view showing an increase in lifespan consumption rate according to an embodiment of the present invention.

Referring to FIG. 5, the solid line g represents the arrival time to the point where the existing turbine can be normally driven when the turbine is driven, and the dotted line h represents the turbine when the turbine is controlled to reduce the lifetime consumption rate of a specific parameter. The arrival time to this point of complete stop can be represented.

Depending on the speed at which the turbine stops driving and reaches the point where the drive is completely stopped, the lifetime consumption of a particular parameter may vary and thus the remaining life of that particular parameter may vary. The measurement unit 110 may measure a specific component of a specific parameter in the section 10 to the point where the turbine stops driving and the driving is completely stopped. In this case, the time when the turbine reaches the point where the normal driving is possible may be t1. The determination unit 120 may determine the remaining life of the specific parameter based on the specific component measured in real time by the measuring unit 110. The controller 150 may control the driving of a specific parameter such that the remaining life is maximized according to a preset maintenance time based on the determined remaining life. The controller 150 may increase the lifetime consumption rate of the specific parameter when it is determined that all of the remaining service life is consumed before the maintenance time when the specific parameter is constantly driven. The controller 150 may control the turbine to slow down the speed at which the turbine stops driving and reaches a point at which the driving is completely stopped. That is, the time that reaches the point where the turbine is completely stopped by the control of the controller 150 may be t2. The turbine must be stopped slowly in order to reach a slow speed up to the point where it is completely stopped, and in order to do so, the drive stop speed of a particular parameter must also be slowed down, so the lifetime consumption rate of a particular parameter can be reduced. Accordingly, the remaining life of a particular parameter can be increased.

6 is a view showing a turbine drive control method according to the remaining life according to an embodiment of the present invention.

1 and 6, the remaining life of a specific parameter according to a specific component value occurring in the specific parameter of the turbine is stored (S10). In detail, the measurement unit 110 may measure a specific component generated in a specific parameter of the turbine. The storage unit 120 may store the remaining life of the specific parameter according to the specific component value of the specific parameter measured by the measuring unit 110.

In operation S20, a specific component generated in a specific parameter is measured. The measurement unit 110 may measure a specific component generated in a specific parameter of the turbine. Here, the measuring unit 110 measures a specific component of a specific parameter in a section up to the point where the turbine starts driving and can be normally driven, and measures a specific parameter in a section up to the point where the turbine stops driving and the driving is completely stopped. Specific components of can be measured.

The remaining life of the specific parameter is determined according to the specific component value measured in real time (S30). In detail, the determination unit 130 may determine a specific component value identical to the specific component measured in real time among the characteristic components stored in the storage 120, and determine the remaining life according to the determined specific component value.

It is determined whether the remaining life of the determined specific parameter will be consumed before the preset maintenance time (S40).

If it is determined that the remaining life of the specific parameter is to be consumed before the preset maintenance time, the control unit 150 may reduce the lifetime consumption rate of the specific parameter (S50). In detail, the controller 150 may control the turbine to slowly reach the point where the turbine starts driving and reaches a point where normal driving is possible, thereby reducing the lifetime consumption rate. In addition, the controller 150 may control the turbine to slowly reach the point where the turbine stops driving and stops driving completely, thereby reducing the lifespan rate.

If it is determined that the remaining life of the specific parameter is not consumed before the preset maintenance time and is consumed later, the controller 150 may increase the lifetime consumption rate of the specific parameter (S60). In detail, the controller 150 may increase the lifespan rate by controlling the turbine so as to quickly reach the point at which the turbine starts driving and can be driven normally. In addition, the controller 150 may increase the lifespan rate by controlling the turbine to reach the point where the turbine stops driving and reaches a point where the driving is completely stopped. After reducing or increasing the lifetime consumption rate of certain parameters, the remaining life can be re-determined according to the specific component values measured in real time so that the drive of the turbine can be controlled again.

Turbine drive control apparatus and method according to the remaining life of determining the remaining life of a specific parameter of the turbine, and controlling the driving of the specific parameter to maximize the remaining life in accordance with the maintenance time based on the determined remaining life as described above Can be realized.

As those skilled in the art to which the present invention pertains may implement the present invention in other specific forms without changing the technical spirit or essential features, the embodiments described above are intended to be illustrative in all respects and should not be considered as limiting. Should be. The scope of the present invention is shown by the following claims rather than the detailed description, and all changes or modifications derived from the meaning and scope of the claims and their equivalents should be construed as being included in the scope of the present invention. .

100: turbine drive control device according to the remaining life
110: measuring unit
120: storage unit
130: decision
140: inspection unit
150: control unit

Claims (25)

A measuring unit measuring a specific component generated in a specific parameter of the turbine;
A storage unit for storing the remaining life of the specific parameter according to the specific component value of the specific parameter;
A determination unit for determining a residual life of a specific parameter according to the specific component value measured in real time based on the information stored in the storage unit; And
And a controller configured to control driving of the turbine to maximize consumption of the remaining life based on a predetermined maintenance time based on the remaining life of the specific parameter.
The storage unit stores in advance a table of the relationship between the specific component value of the specific parameter and the remaining life,
The determination unit determines a specific component value matching the specific component value measured in real time among the specific component values stored in the table, reads the remaining life corresponding to the determined specific component value from the table, and reads the remaining residual life. And a turbine drive control device according to the remaining service life determined as the remaining service life of the specific parameter. The method of claim 1,
The specific parameter is a configuration of the turbine, the failure is likely to occur in accordance with the remaining life when the turbine is driven,
The specific component is a turbine drive control device according to the remaining life is a component that is changed when the specific parameter is driven. The method of claim 1,
Further comprising a inspection unit for validating the specific component value,
And the inspection unit determines that the specific component value is not valid when the specific component value is higher or lower than a mean of the specific component value by a predetermined or more. The method of claim 3,
The average of the specific component values is stored in the storage, or
Turbine drive control device according to the remaining life is calculated in real time through a specific component value measured in real time in the measuring unit. delete The method of claim 1,
And the control unit increases the lifespan consumption rate of the specific parameter when it is determined that the remaining life is not consumed at the time of maintenance when the specific parameter is constantly driven. The method of claim 6,
The control unit is a turbine drive control device according to the remaining life of increasing the lifespan rate by controlling the turbine so that the turbine starts to drive and reach a point where the normal drive can be reached quickly. The method of claim 6,
And the control unit controls the turbine to reach the point where the turbine stops driving and reaches the point at which the driving is completely stopped, thereby increasing the life span. The method of claim 1,
The control unit is a turbine drive control apparatus according to the remaining life of reducing the life consumption rate of the specific parameter if it is determined that all the remaining life before the maintenance time when the specific parameter is constantly driven. The method of claim 9,
The control unit is a turbine drive control device according to the remaining life of reducing the life cycle rate by controlling the turbine so that the turbine starts to drive slowly to reach the point where the normal drive is possible. The method of claim 9,
The control unit is a turbine drive control device according to the remaining life of reducing the lifetime consumption rate by controlling the turbine so that the turbine slowly reaches to the point where the drive stops driving and is completely stopped. The method of claim 1,
The control unit is a turbine drive control device according to the remaining life of setting the time when it is determined that all the remaining life will be consumed when the specific parameter is constantly driven. The method of claim 1,
The measuring unit,
Measuring a specific component of the specific parameter in a section up to the point where the turbine starts driving and can be operated normally;
Measuring a specific component of the specific parameter in a section up to the point where the turbine stops driving and the drive is completely stopped;
Turbine drive control device according to remaining life. The method of claim 1,
And the determining unit controls the driving of the specific parameter in accordance with the maintenance time point, and then re-determines the remaining life according to the specific component value measured in real time. Storing the remaining life of the specific parameter according to the specific component value occurring in the specific parameter of the turbine;
Measuring a specific component occurring in the specific parameter in real time;
Determining a remaining life of a specific parameter according to the specific component value measured in real time based on the stored information; And
And controlling the driving of the specific parameter to maximize consumption of the remaining life according to a preset maintenance time based on the determined remaining life of the specific parameter.
In the step of storing the remaining life,
A table of the relationship between the specific component value of the specific parameter and the remaining life is stored in advance,
In determining the remaining life of the specific parameter,
Determine a specific component value matching the specific component value measured in real time among the specific component values stored in the table, read the remaining life corresponding to the determined specific component value from the table, and read the remaining life of the specific parameter. Turbine drive control method according to the remaining life to determine as the remaining life of the. delete The method of claim 15,
In controlling the driving of the specific parameter,
The method of controlling the turbine drive according to the remaining service life of increasing the lifetime consumption rate of the specific parameter when it is determined that not all of the remaining service life is consumed at the maintenance time when the specific parameter is constantly driven. The method of claim 17,
In controlling the driving of the specific parameter,
And controlling the turbine so that the turbine starts driving and quickly reaches a point where normal driving is possible, thereby increasing the lifespan rate. The method of claim 17,
In controlling the driving of the specific parameter,
And controlling the turbine to reach the point where the turbine stops driving and reaches a point at which the driving is completely stopped, thereby increasing the lifespan rate. The method of claim 15,
In controlling the driving of the specific parameter,
The method of controlling the turbine drive according to the remaining service life of reducing the lifetime consumption rate of the specific parameter when it is determined that all of the remaining life before the maintenance time when the specific parameter is constantly driven. The method of claim 20,
In controlling the driving of the specific parameter,
The method of controlling the turbine drive according to the remaining life of reducing the lifespan consumption by controlling the turbine so that the turbine starts to drive and arrives slowly to a point where normal driving is possible. The method of claim 20,
In controlling the driving of the specific parameter,
And controlling the turbine to slow down to the point where the turbine stops driving and stops driving completely. The method of claim 15,
In controlling the driving of the specific parameter,
Turbine drive control method according to the remaining life of setting the time point that is determined that all the remaining life will be consumed when the specific parameter is constantly driven. The method of claim 15,
In the step of measuring the specific component,
Measuring a specific component of the specific parameter in a section up to the point where the turbine starts driving and can be operated normally;
The turbine drive control method according to the remaining life of measuring the specific component of the specific parameter in the section to the point where the turbine stops driving and the drive is completely stopped. The method of claim 15,
In determining the remaining life of the specific parameter,
And controlling the driving of the specific parameter in accordance with the maintenance time point. The turbine driving control method according to the remaining life of re-determining the remaining life according to the specific component value measured in real time.

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