KR20220061698A - Low temperature power generation system operation control logic - Google Patents

Abstract

The present invention relates to a low-temperature power generation system operation controlling logic. According to the present invention, the low-temperature power generation system operation controlling logic of the present invention, as a generator controlling system, comprises: a generator; an electrical part; a turbine rotated by flow of a working fluid; a first heat exchange module disposed at a front end of the generator to heat the working fluid and flow the same to the generator; and a second heat exchange module disposed at a rear end of the generator to cool the working fluid passing through the generator. The low-temperature power generation system operation controlling logic includes: a preliminary check step of checking an operation of the turbine before starting the generator by checking a condition of the electrical part and the turbine of the generator before operating the turbine; and a control step of determining whether or not the generator is operated according to a status of the turbine after the preliminary check step is completed. An objective of the present invention is to provide the low-temperature power generation system operation logic for determining whether or not to continue operating the turbine.

Description

Low temperature power generation system operation control logic

The present invention relates to a low-temperature power generation system operation control logic (Logic), and more particularly, to a generator, an electrical component, a turbine rotated by the flow of a working fluid, and disposed at the front end of the generator to heat the working fluid to flow to the generator It includes a first heat exchange module and a second heat exchange module disposed at the rear end of the generator to cool the working fluid passing through the generator. It relates to a low-temperature power generation system operation control logic including a pre-check step of pre-checking whether or not and a control step of determining whether a generator is in operation according to the state of a turbine after the pre-check step is completed.

The content described in this section merely provides background information on the present invention and does not constitute the prior art.

The operation monitoring operator, which is a component of the conventional power plant turbine system control system (Registration Patent No. 10-0575204), is generally composed of a selection switch, a push button, a dial, a recorder, an indicator, and an indicator. However, since they are recorded at different locations or stored in different recording media, they cause inconvenience in monitoring and manipulation, as well as difficulties in storing and managing data. In addition, since the main controller, which is a component of the power plant turbine system control system, is multiplexed by a module composed of analog circuits, and the control variable adjustment by the operator is controlled by resistors, etc., precise control is difficult and new control functions are added The problem that it is difficult to do has been pointed out.

Moreover, the conventional analog power plant turbine system control system has a closed design structure, and it is not easy to procure spare parts due to technical progress and discontinuation of parts due to long-term use. The reality is that we are experiencing a lot of difficulties in maintenance. In particular, the alarm identification and convenience for the modules and parts constituting the main controller are inferior.

In this regard, the turbine system of the power plant is one of the core control facilities of the power plant, and after increasing the speed of the turbine driving the generator from the low-speed rotation state to the rated speed, the generator is operated in parallel to the power system to control the electrical output Therefore, in order to maintain the rated frequency, which is the most important element of electricity quality, the stability and reliability of the turbine system control system are essential.

In addition, the conventional low temperature power generation operation control system has been pointed out a problem in that the turbine is damaged and malfunctions by operating the turbine without performing an inspection for the presence or absence of damaged electrical components in the turbine before operation.

In order to solve the problems of the conventional low-temperature power generation operation control system described above, some domestic and foreign related companies have conducted research on the low-temperature power generation operation control system including the detection stage before turbine operation. Compared to the conventional low-temperature power generation operation control system, the market competitiveness was low, and there was no case of full-scale commercialization.

Therefore, there is a need to develop a device capable of solving the problems of the prior art as described above.

The problem to be solved by the present invention is to supplement the above-mentioned disadvantages of the prior art, and the object of the present invention is as follows.

First, in order to prevent damage to the turbine generator, it is intended to provide a low-temperature power generation system operation logic that determines whether or not the turbine operation continues by identifying the temperature, pressure difference, and flow rate of the working fluid in the heat source, condensate, generator and bearings. do.

Second, it is intended to provide a low-temperature power generation system operation logic in which a generator can stably produce a target amount of electricity by loading a certain amount of load on the turbine and sequentially increasing the flow rate injected into the turbine in response thereto.

Third, the present pressure at the turbine inlet or condenser outlet is compared with the saturation pressure, the upper limit coefficient, and the lower limit coefficient to provide a low-temperature power generation system operation logic that can control the flow rate in the turbine or determine whether the turbine continues to operate.

The problems of the present invention are not limited to the problems mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the following description.

According to the present invention, as a generator control system, the generator, the electrical components, the turbine rotated by the flow of the working fluid, the first heat exchange module disposed at the front end of the generator to heat the working fluid to flow to the generator, and the generator disposed at the rear end It includes a second heat exchange module that cools the working fluid passing through the generator, and a pre-check step and a pre-check step that checks whether the turbine can be operated before starting the generator by checking the condition of the electric parts and turbine of the generator before the operation of the turbine After the check step is completed, it provides a low-temperature power generation system operation logic including a control step of determining whether or not the generator is in operation according to the state of the turbine.

In this case, the control step may include a working fluid check step of determining whether the generator operates by measuring the temperature, pressure difference, and flow rate for each location of the working fluid.

Furthermore, the working fluid check step is a heat source check step to check the temperature, pressure difference and flow rate of the heat source, a condensate check step to check the temperature, pressure difference and flow rate of the condensate, check the temperature, pressure difference and flow rate of the working fluid in the generator It may include a bearing check step of checking the generator check step and the temperature, pressure difference and flow rate of the working fluid in the bearing.

According to another feature of the present invention, the low-temperature power generation system operation control logic includes an iterative calculation increment having an arbitrary integer value, TMR (Turbine Max RPM), which is the maximum turbine rotation speed, TMV (Turbine RPM marginal value), which is a rotation speed safety factor, and saturation. The method may further include a setting step of setting the lower pressure limit, the upper saturation pressure limit, the condenser outlet dryness, and the condenser outlet dryness upper limit.

In this case, the setting step may include a load & flow rate setting step of setting an initial load value and an initial flow rate so that the generator can produce a target amount of power.

Furthermore, the low-temperature power generation system operation control logic includes an operation step of operating the generator so that the generator can produce the target amount of electricity, and the operation step is the load of the value obtained by dividing the initial load value set in the load & flow setting step by the iterative calculation increment. It increases sequentially from the 1st to the nth step, and the flow rate of the value obtained by dividing the initial value of the flow rate set in the load step and load & flow setting step in which a load is loaded on the generator by the repeated calculation increase width follows the load step and follows the 1st step It may include an injection step of sequentially increasing in the n-th step and injecting the working fluid into the turbine.

Meanwhile, the low temperature power generation system operation control logic measures the current temperature of the turbine inlet and the current pressure of the turbine inlet, and the first saturation pressure, the first upper limit coefficient, and the first lower limit coefficient, which are the pressures for maintaining the fluid in the gaseous state at the turbine inlet. It may include a diagnostic step of comparing with

At this time, in the diagnosis step, when the current pressure at the turbine inlet exceeds a value obtained by multiplying the first saturation pressure and the first upper limit coefficient, the flow rate injected into the turbine is reduced by the flow rate set in the injection step, and the current at the turbine inlet When the pressure does not exceed the value obtained by multiplying the first saturation pressure and the first lower limit coefficient, the flow rate injected into the turbine is increased by the flow rate set in the injection step, and the current pressure at the turbine inlet is equal to the first saturation pressure and the first lower limit coefficient. When it has a value between the product of the product of , the first saturation pressure and the product of the first upper limit coefficient, the first processing step of maintaining the flow rate injected into the turbine to be the same as the current one may be included.

In addition, the diagnosis step measures the current temperature of the inlet of the second heat exchange module and the current pressure of the inlet of the second heat exchange module, the second saturation pressure value, the second upper limit, which is the pressure for maintaining the fluid in the liquid state at the inlet of the second heat exchange module It may further include a process of comparing the coefficient and the second lower limit coefficient.

At this time, the diagnosis step is performed when the current pressure at the inlet of the second heat exchange module does not exceed the value obtained by multiplying the second saturated pressure value by the second lower limit coefficient or exceeds the value obtained by multiplying the second saturated pressure value by the second upper limit coefficient. Stop the operation of the turbine, and when the current pressure at the inlet of the second heat exchange module has a value between the product of the second saturation pressure and the second lower limit coefficient and the value of the second saturation pressure and the second upper limit coefficient, the turbine is turned off. It may include a second processing step that is continuously operated.

Meanwhile, in operating the generator, the first processing step or the second processing step may be performed in real time.

Additional solutions of the present invention will be set forth in part in the description that follows, and in part will be readily ascertained from the description, or may be learned by practice of the invention.

Both the foregoing general description and the following detailed description are exemplary and explanatory only and do not limit the invention as set forth in the claims.

The effects of the present invention configured as described above will be described as follows.

First, in order to prevent damage to the turbine generator, it is intended to provide a low-temperature power generation system operation logic that determines whether the turbine operation continues by identifying the temperature, pressure difference, and flow rate of the working fluid in the heat source, condensate, generator and bearings. do.

Second, it is intended to provide a low-temperature power generation system operation logic capable of stably producing a target amount of power by a generator by loading a certain amount of load on the turbine and sequentially increasing the flow rate injected into the turbine in response thereto.

Third, the present pressure at the turbine inlet or condenser outlet is compared with the saturation pressure, the upper limit coefficient, and the lower limit coefficient to provide a low-temperature power generation system operation logic that can control the flow rate in the turbine or determine whether the turbine continues to operate.

Effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the description of the claims.

1 is a schematic diagram of a turbine system according to an embodiment of the present invention;
2 is an overall chart flow of a low-temperature power generation system operation logic according to an embodiment of the present invention.
3 is a chart flow of a working fluid control step according to an embodiment of the present invention.
4 is a chart flow of a setting step according to an embodiment of the present invention.
5 is a chart flow of the load & flow rate setting step according to an embodiment of the present invention.
6 is a chart flow of the loading step and the injection step according to an embodiment of the present invention.
7 is a chart flow of a first diagnosis step according to an embodiment of the present invention.
8 is a graph showing the correlation between RPM and flow rate according to the load applied to the turbine by the low-temperature power generation system operation logic of the present invention.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the accompanying drawings.

However, in describing a specific embodiment of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted.

The above-mentioned objects, features and advantages of the present invention will become more apparent from the following detailed description taken in conjunction with the accompanying drawings. However, since the present invention may include various changes and may include various embodiments, specific embodiments will be exemplified in the drawings and described in detail below.

If it is determined that a detailed description of a known function or configuration related to the present invention may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted. In addition, the number used in the description of the present specification is only an identification symbol for distinguishing one component from other components.

In addition, the suffix "part" for components used in the following description is used or used only to facilitate the preparation of the specification, and does not have a meaning or role distinct from each other by itself.

1 is a schematic diagram of a turbine 200 system according to an embodiment of the present invention.

The generator control system according to the present invention includes a generator, electrical components, turbine 200, a first heat exchange module 300 and a second heat exchange module 400, and performs a pre-check step (S100) and a control step (S200) may include

The first heat exchange module 300 may be disposed at the front end of the generator to heat the working fluid and flow to the generator.

The second heat exchange module 400 may be disposed at the rear end of the generator to cool the working fluid passing through the generator.

In the pre-checking step, it is possible to check in advance whether the turbine 200 is operable before starting the generator by checking the electrical components of the generator and the state of the turbine 200 before the operation of the turbine 200 .

In the control step (S200), it is possible to determine whether or not the generator is in operation according to the state of the turbine 200 after the completion of the pre-checking step.

2 is an overall chart flow of a low-temperature power generation system operation logic according to an embodiment of the present invention.

Figure 3 is a chart flow of the working fluid check step (S210) according to an embodiment of the present invention.

The control step (S200) may include a working fluid check step (S210).

The working fluid check step (S210) may include a heat source check step (S211), a condensate check step (S212), a generator check step (S213) and a bearing check step.

The working fluid check step may determine whether the generator operates by measuring the temperature, pressure difference, and flow rate for each position of the working fluid.

The heat source check step S211 may check the temperature, pressure difference, and flow rate of the heat source.

The condensed water check step (S212) may check the temperature, pressure difference, and flow rate of the condensed water.

The generator check step (S213) may check the temperature, pressure difference, and flow rate of the working fluid in the generator.

The bearing check step (S214) may check the temperature, pressure difference, and flow rate of the working fluid in the bearing.

As a result, it is possible to prevent damage to the turbine 200 generator by determining whether the turbine 200 continues to operate by determining the state of the temperature, pressure difference, and flow rate of the working fluid in the heat source, condensate, generator and bearings.

4 is a chart flow of the setting step (S300) according to an embodiment of the present invention.

5 is a chart flow of the load & flow rate setting step (S310) according to an embodiment of the present invention.

The low-temperature power generation system operation control logic according to an embodiment of the present invention may further include a setting step (S300).

The setting step (S300) is an iterative calculation increment having an arbitrary integer value, TMR (Turbine Max RPM), which is the maximum rotational speed of the turbine 200, TMV (Turbine RPM marginal value), which is the rotational safety factor, Saturation pressure lower limit, Saturation pressure upper limit , condenser outlet dryness and condenser outlet dryness upper limit can be set.

The setting step (S300) may further include a load & flow rate setting step (S310).

The load & flow rate setting step (S310) may set an initial load value and an initial flow rate so that the generator can produce a target amount of power.

When the set initial load value and the initial flow rate value are applied to the turbine 200 , it is possible to produce a target amount of power.

6 is a chart flow of the loading step (S410) and the injection step (S420) according to an embodiment of the present invention.

The low-temperature power generation system operation control logic may include an operation step (S400).

In the operation step (S400), the generator may be operated so that the generator can produce a target amount of power.

The operation step (S400) may include a loading step (S410) and an injection step (S420).

In the load step (S410), the load of the value obtained by dividing the initial value of the load set in the load & flow setting step (S310) by the iteratively calculated increment is sequentially increased from the 1st to the nth step, and the load can be loaded on the generator. there is.

The injection step (S420) follows the load step (S410) with the flow rate of the value obtained by dividing the initial value of the flow rate set in the load & flow setting step (S310) by the iteratively calculated increment, and sequentially increases from the 1st to the nth step, and the turbine ( 200) can be injected with a working fluid.

In more detail, it can be defined as the first load step (S410) to load the minimum unit load (L1) divided by the load initial value set in the load & flow setting step (S310) by the iteratively calculated increment to the generator. After that, the minimum unit flow rate (M1) obtained by dividing the initial flow rate set in the load & flow setting step (S310) by the iteratively calculated increment is followed by the first load step (S410) and injecting into the turbine 200 is the first injection step ( S420) can be defined. Immediately after the first load step (S410), the RPM of the turbine 200 is reduced, and immediately after the first injection step (S420), the RPM of the turbine 200 may be restored to a preset value.

After the first load step (S410) and the first injection step (S420) are finished, the load value L2 obtained by adding the minimum unit load to L1 to the generator may be defined as the second load step (S410). Injecting the flow rate value M2 obtained by adding the minimum unit flow rate to M1 into the turbine 200 following the second load step S410 may be defined as the second injection step S420 . Immediately after the second load step (S410), the RPM of the turbine 200 is reduced, and immediately after the second injection step (S420), the RPM of the turbine 200 may be restored to a preset value.

After the second load step (S410) and the second injection step (S420) are finished, the load value L3 obtained by adding the minimum unit load to L2 to the generator may be defined as the third load step (S410). Injecting the flow rate value M3 obtained by adding the minimum unit flow rate to M2 into the turbine 200 following the third load step S410 may be defined as the third injection step S420 . Immediately after the third load step (S410), the RPM of the turbine 200 is reduced, and immediately after the third injection step (S420), the RPM of the turbine 200 may be restored to a preset value.

By repeatedly executing the N-th load step (S410) and the N-th injection step (S420) as many times as the number of times corresponding to the iterative calculation increment having an arbitrary integer value, the generator can produce the target amount of power.

As a result, by loading a certain amount of load on the turbine 200 and sequentially increasing the flow rate injected into the turbine 200 in response thereto, the generator can stably produce the target amount of power.

7 is a chart flow of the first diagnosis step (S500) according to an embodiment of the present invention.

8 is a graph showing the correlation between RPM and flow rate according to the load applied to the turbine by the low-temperature power generation system operation logic of the present invention.

The low-temperature power generation system operation control logic may include a first diagnosis step S500 and a second diagnosis step S510.

In the first diagnosis step (S500), the current temperature of the inlet of the turbine 200 and the current pressure of the inlet of the turbine 200 are measured, and the first saturation pressure, which is the pressure for maintaining the fluid in a gaseous state at the inlet of the turbine 200, is It can be compared with the first upper limit coefficient and the first lower limit coefficient.

More specifically, the first diagnosis step S500 may include a first processing step S501 , and the current pressure at the inlet of the first turbine 200 is a value obtained by multiplying the first saturation pressure and the first upper limit coefficient. If it exceeds, the first processing step (S501) may reduce the flow rate injected into the turbine 200 by the flow rate set in the injection step (S420).

On the other hand, when the current pressure at the inlet of the turbine 200 does not exceed the value obtained by multiplying the first saturation pressure and the first lower limit coefficient, the first processing step (S501) is the injection step ( It can be increased by the flow rate set in S420).

On the other hand, when the current pressure at the inlet of the turbine 200 has a value between a value obtained by multiplying the first saturation pressure and the first lower limit coefficient and a value obtained by multiplying the first saturation pressure and the first upper limit coefficient, the first processing step (S501) can keep the flow rate injected into the turbine 200 the same as the current one.

The second diagnosis step (S510) may include a second processing step (S511), and the second diagnosis step (S510) includes the current temperature of the inlet of the second heat exchange module 400 and the temperature of the inlet of the second heat exchange module 400 . The current pressure may be measured and compared with the second saturation pressure value, the second upper limit coefficient, and the second lower limit coefficient, which are pressures for maintaining the fluid in a liquid state at the inlet of the second heat exchange module 400 .

More specifically, the current pressure at the inlet of the second heat exchange module 400 does not exceed a value obtained by multiplying the second saturated pressure value by the second lower limit coefficient or exceeds a value obtained by multiplying the second saturated pressure value by the second upper limit coefficient In the case of the second processing step (S511), the operation of the turbine 200 may be stopped.

On the other hand, if the current pressure at the inlet of the second heat exchange module 400 has a value between the product of the second saturation pressure and the second lower limit coefficient and the value obtained by multiplying the second saturation pressure and the second upper limit coefficient, the second process Step S511 may continuously operate the turbine 200 .

As a result, the turbine 200 can be operated by effectively adjusting the flow rate in the turbine 200 by comparing the current pressure and the saturation pressure, the upper limit coefficient, and the lower limit coefficient at the inlet of the turbine 200, and the current pressure and saturation at the outlet of the condenser By comparing the pressure, the upper limit coefficient, and the lower limit coefficient, it is possible to determine whether the operation of the turbine 200 continues.

Meanwhile, in operating the generator, the first processing step (S501) or the second processing step (S511) may be performed in real time.

This embodiment is merely illustrative of the technical idea of the present invention, and those of ordinary skill in the art to which the present invention pertains may make various modifications and variations of this embodiment without departing from the essential characteristics of the present invention. It will be possible.

This embodiment is intended to explain, not to limit the technical spirit of the present invention, and therefore, the scope of the present invention is not limited by the present embodiment.

The protection scope of the present invention should be construed by the claims, and all technical ideas that are equivalent or equivalent thereto should be construed as being included in the scope of the present invention.

10 - generator
200 - turbine
300 - first heat exchange module
400 - second heat exchange module
500 - tank
S100 - Pre-check step
S200 - control stage
S210 - Working fluid check step
S211 - Heat source check step
S212 - Condensate Check Step
S213 - Generator Check Phase
S214 - bearing check step
S300 - Setting Step
S310 - Load & Flow Setting Step
S400 - Driving stage
S410 - load stage
S420 - Injection step
S500 - First diagnosis stage
S501 - first processing step
S510 - Second diagnosis stage
S511 - Second processing step

Claims (11)

as a generator system,
The generator is
electronic parts;
A turbine rotated by the flow of the working fluid;
a first heat exchange module disposed at the front end of the generator to heat a working fluid and flow to the generator; and
a second heat exchange module disposed at the rear end of the generator to cool the working fluid passing through the generator;
includes,

A pre-checking step of pre-checking whether the turbine is operable before starting the generator by checking the state of the electrical components of the generator and the turbine before the operation of the turbine;
a control step of determining whether the generator is in operation according to the state of the turbine after completion of the pre-checking step;
Low-temperature power generation system operation control logic comprising a.
According to claim 1,
The control step is
Working fluid check step of measuring the temperature, pressure difference, and flow rate for each location of the working fluid and determining whether the generator is operating based on the information
Low-temperature power generation system operation control logic comprising a.
3. The method of claim 2,
The working fluid check step is
a heat source check step of checking the temperature, pressure difference and flow rate of the heat source;
Condensate check step of checking the temperature, pressure difference and flow rate of the condensate;
Generator check step of checking the temperature, pressure difference and flow rate of the working fluid in the generator; and
A bearing check step to check the temperature, pressure difference and flow rate of the working fluid in the bearing
Low-temperature power generation system operation control logic comprising a.
According to claim 1,
Iterative calculation increase with arbitrary integer value, TMR (Turbine Max RPM), which is the maximum turbine rotation speed, TMV (Turbine RPM marginal value), which is the rotation speed safety factor, Saturation pressure lower limit, Saturation pressure upper limit, Condenser outlet dryness and Condenser outlet dryness upper limit setting steps to set
Low-temperature power generation system operation control logic comprising a.
5. The method of claim 4,
The setting step is
A load & flow rate setting step of setting an initial load value and an initial flow rate so that the generator can produce a target amount of power
Low-temperature power generation system operation control logic comprising a.
6. The method of claim 5,
an operation step of operating the generator to produce a target amount of electricity
includes

The driving step is
a load step of sequentially increasing a load of a value obtained by dividing the initial value of the load set in the load & flow setting step by the increase in the iterative calculation from the first to the n-th step, and loading a load on the generator; and
An injection step of injecting a working fluid into the turbine by sequentially increasing the flow rate of the value obtained by dividing the initial flow rate set in the load & flow setting step by the iterative calculation increase width after the load step and sequentially increasing from the 1st to the nth step
Low-temperature power generation system operation control logic comprising a.
7. The method of claim 6,
A first diagnosis of measuring the current temperature of the turbine inlet and the current pressure of the turbine inlet and comparing them with a first saturation pressure, a first upper limit coefficient, and a first lower limit coefficient, which are pressures for maintaining the fluid in a gaseous state at the turbine inlet step
Low-temperature power generation system operation control logic comprising a.
8. The method of claim 7,
The first diagnosis step is
When the current pressure at the turbine inlet exceeds a value obtained by multiplying the first saturation pressure and the first upper limit coefficient, the flow rate injected into the turbine is reduced by the flow rate set in the injection step, and the current pressure at the turbine inlet is the second If it does not exceed the value obtained by multiplying the first saturation pressure and the first lower limit coefficient, the flow rate injected into the turbine is increased by the flow rate set in the injection step, and the current pressure at the turbine inlet is the first saturation pressure and the first lower limit coefficient A first processing step of maintaining the flow rate injected into the turbine equal to the current when it has a value between the product of the product of
Low-temperature power generation system operation control logic comprising a.
9. The method of claim 8,
A second saturation pressure value, a second upper limit coefficient and Low-temperature power generation system operation control logic, characterized in that it further comprises a second diagnosis step of comparing with the second lower limit coefficient.
10. The method of claim 9,
The second diagnosis step is
When the current pressure at the inlet of the second heat exchange module does not exceed the value obtained by multiplying the second saturated pressure value by the second lower limit coefficient or exceeds the value obtained by multiplying the second saturated pressure value by the second upper limit coefficient, the turbine is stopped When the current pressure at the inlet of the second heat exchange module has a value between the product of the second saturation pressure and the second lower limit coefficient and the value of the second saturation pressure and the second upper limit coefficient, the turbine is continuously operated 2nd processing step in operation
Low-temperature power generation system operation control logic comprising a. 11. The method of claim 8 or 10,
In operating the generator, the low-temperature power generation system operation control logic, characterized in that the first processing step or the second processing step is performed in real time while the turbine is operating.

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