DE112016004974T5 - Compensation control method and system for abruptly changing a device performance - Google Patents

Abstract

A compensation control method and system for abruptly changing a device performance. The method includes: obtaining device power information including a rated device power, current device power, a set set amount and a measured set amount, and obtaining a device power correction condition (S101); Detecting a correction increase condition or the correction decrease condition (S 102); and increasing a device control command according to the predetermined rate if the correction increase condition is detected, and decreasing the device control command according to the predetermined rate if the correction reduction condition is detected (S 103). The method solves a nonlinear relationship between a device control command and a device performance, and a machine set can quickly achieve a safe and stable new operating condition.

Description

This application claims the priority of Chinese Patent Application No. 2015 10718664.6 entitled "Compensation Control Method and Device Abruptly Altering Device Performance" filed on Oct. 28, 2015 with the Chinese Patent Office, which is incorporated by reference in its entirety in the present application.

area

The disclosure relates to the art of automatic control of cogeneration plants, and more particularly to a balance control method and system for the abrupt change of device performance during a RUNBACK process of cogeneration plants.

background

In the technical field of automatic control of cogeneration plants, a RUNBACK (abbreviated as RB) process indicates that in a case where a large auxiliary power plant of the cogeneration plant fails and shuts off, limiting the actual output of the plant (if the coordination control system in an automatic mode), the control system forcibly reduces the unit load to a load target that can be carried by the traveling auxiliary machine to adjust the device performance. This process is also referred to as a load reduction process in auxiliary machine failure. The RUNBACK process involves the correction of device performance, which includes correction logic that directly performs logic functions such as switching from an automatic state to a manual state, preferably increasing, preferably decreasing, increasing forbidden, decreasing prohibited, according to the cause of the accident, when an abnormal signal such as an accidental alarm, an over-limit deviation signal, and an error signal is received from the system to switch the system to a predetermined safe state.

For example, in most auxiliary machines in large cogeneration plants, two or more auxiliary machines such as fans and water pumps work in parallel. In a case where one or more of these auxiliary machines shuts off, the power of the running auxiliary machine of the same type as the deactivated auxiliary machine must increase rapidly while the control mode of the power plant is switched, and the target load, fuel amount, and The flow of working fluid such as water and air at the plant is rapidly reduced, so that the plant quickly reaches a new balanced operating condition to ensure the safe and stable operation of the plant.

At present, a linear overlay method is generally used to increase the power of a running auxiliary machine after another plant's auxiliary machine has shut down, with the power of the off-machine being superimposed on the line of the running machine according to a certain proportion. The method easily causes dangers such as that the power of the running machine exceeds the maximum allowed value, and other parameters of the factory exceed the limits because of the non-linear relationship between the auxiliary machine control commands and the actual auxiliary machine performance, and the variation relationships below the performance limit of the on-going auxiliary machine, an appropriate system adjustment quantity and other limited quantities are not taken into account in this procedure.

presentation

Against this background, a balance control method and apparatus for abruptly changing a device performance according to the present disclosure is provided, which can avoid the danger due to the nonlinear relationship between the device control commands and the device performance, so that the factory can quickly reach a new operating condition safe and stable.

• Erlangen von Vorrichtungsleistungsinformationen, die eine Nenn-Vorrichtungsleistung, aktuelle Vorrichtungsleistung, eine eingestellte Einstellungsmenge und eine gemessene Einstellungsmenge enthalten, und Erlangen einer Vorrichtungsleistung-Korrektursteuerungsbedingung auf Grundlage der Vorrichtungsleistungsinformationen, wobei die Vorrichtungsleistung-Korrektursteuerungsbedingung eine Korrekturerhöhungs-Bedingung und eine Korrekturverringerungs-Bedingung beinhaltet;
• Erfassen, ob die Korrekturerhöhungs-Bedingung oder die Korrekturverringerungs-Bedingung für die Vorrichtungsleistung erfüllt ist; und
• Erhöhen eines Werts eines Vorrichtungssteuerbefehls in einer vorgegebenen Rate, falls erfasst wird, dass die Korrekturerhöhungs-Bedingung erfüllt ist, und Verringern des Werts des Vorrichtungssteuerbefehls in der vorgegebenen Rate, falls erfasst wird, dass die Korrekturverringerungs-Bedingung erfüllt ist.

The following technical solutions are implemented in the present disclosure. In one aspect of the present disclosure, there is provided a compensation control method for abruptly changing device performance, comprising:

• Obtaining device power information including a rated device power, current device power, a set set amount and a measured set amount, and obtaining a device power correction control condition based on the device power information, wherein the device power correction control condition includes a correction increase condition and a correction decrease condition;
• Detecting whether the correction increase condition or the device performance decrease correction condition is satisfied; and
• Increasing a value of a device control command at a predetermined rate if it is detected that the correction increase condition is satisfied, and decreasing the value of the device control command in the predetermined rate, if it is detected that the correction reduction condition is satisfied.

• ein Syntheseoperationsmodul, das eingerichtet ist, Vorrichtungsleistungsinformationen zu erlangen, die eine Nenn-Vorrichtungsleistung, eine aktuelle Vorrichtungsleistung, eine eingestellte Einstellungsmenge und eine gemessene Einstellungsmenge enthalten, und eine Vorrichtungsleistung-Korrektursteuerungsbedingung auf Grundlage der Vorrichtungsleistungsinformationen zu erlangen, wobei die Vorrichtungsleistung-Korrektursteuerungsbedingung eine Korrekturerhöhungs-Bedingung und eine Korrekturverringerungs-Bedingung beinhaltet;
• ein Erfassungsmodul, das eingerichtet ist, zu erfassen, ob die Korrekturerhöhungs-Bedingung oder die Korrekturverringerungs-Bedingung für die Vorrichtungsleistung erfüllt ist; und ein Erhöhungs- und Verringerungs-Steuerungsmodul, das eingerichtet ist, einen Wert eines Vorrichtungssteuerbefehls in einer vorgegebenen Rate zu erhöhen, falls erfasst wird, dass die Korrekturerhöhungs-Bedingung erfüllt ist, und den Wert des Vorrichtungssteuerbefehls in der vorgegebenen Rate zu verringern, falls erfasst wird, dass die Korrekturverringerungs-Bedingung erfüllt ist.

In another aspect of the present disclosure, a compensation control system for abruptly changing device performance is disclosed, comprising:

• a synthesis operation module configured to acquire device power information including a rated device power, a current device power, a set set amount and a measured set amount, and a device power correction control condition based on the device power information, wherein the device power correction control condition is a correction increase Condition and a correction reduction condition includes;
• a detection module configured to detect whether the correction increase condition or the device performance decrease correction condition is satisfied; and an increase and decrease control module configured to increase a value of a device control command at a predetermined rate if it is detected that the correction increase condition is satisfied and to decrease the value of the device control command at the predetermined rate, if detected is that the correction reduction condition is satisfied.

The advantageous effect for realizing the above technical solutions of the present disclosure are as follows. The correction increase condition and the correction decrease condition for the control instruction are detected by performing the synthesis operation on a device operation state, the rated device power, the current device power (a device power feedback), the current adjustment amount, the set adjustment amount, and other limiting conditions. The correction increase condition and the device performance decrease correction condition are issued under the condition that the device power does not exceed the limit value, the deviation between the adjustment amount and the adjustment value is small, and other parameters do not exceed the safety allowable ranges in the correction control operation. In a case where the device performance correction increase condition is satisfied, the value of the device control command is increased in a maximum allowed rate of change of device performance. In a case where the device performance correction decreasing condition is satisfied, the value of the device control command is reduced in the maximum allowed rate of change of the device power. In this way, the danger due to the non-linear relationship between the device control command and the device performance can be avoided, so that the factory can quickly reach a new operating condition that is safe and stable.

list of figures

• 1 Fig. 10 is a schematic structural diagram of a rapid compensation control system for abruptly changing device performance;
• 2 FIG. 10 is a schematic flow diagram of a compensation control method for abruptly changing device performance according to an embodiment of the present disclosure; FIG.
• 3 Fig. 10 is a schematic structural diagram of a compensation control system for abruptly changing a device power for a system in which two devices are in parallel;
• 4 Fig. 10 is a schematic diagram illustrating a principle of a correction raising condition for a moving blade of an induced draft fan;
• 5 Fig. 10 is a schematic diagram illustrating a principle of a correction raising condition for a guide vane of a suction draft blower;
• 6 Fig. 10 is a schematic diagram illustrating a principle of a correction raising condition for a rotational speed of a feedwater pump; and
• 7 FIG. 10 is a schematic structural diagram of a compensation control system for abruptly changing device performance according to an embodiment of the present disclosure. FIG.

DETAILED DESCRIPTION OF THE EMBODIMENTS

In order that the objects, features and advantages of the present disclosure may be better and more easily understood, the technical solution according to the embodiments of the present disclosure will be described clearly and completely hereinafter in conjunction with the drawings. It is noted that the described embodiments are only a few and not all of the embodiments according to the present invention Revelation is. All other embodiments obtained by one skilled in the art based on the embodiments in the present disclosure without inventive step are within the scope of the present disclosure.

The embodiments of the present disclosure include an embodiment of a compensation control method for abruptly changing a device performance, and an embodiment of a corresponding compensation control system for abruptly changing a device performance, which will be described in detail below.

1 FIG. 10 is a schematic diagram of a hardware environment for implementing a compensation control method for abruptly changing device performance in accordance with the present disclosure. FIG. As in 1 1, the hardware environment for implementing the abrupt change in device performance compensation control according to the present disclosure includes: a synthesis operation circuit having a correction enhancement condition / downstream device performance correction decrease condition by performing a synthesis operation on a device performance, a device power feedback, a set system value, a measured one System value and other restrictive conditions obtained in real time, and a main control signal output from an upstream controller; and quickly compensates the performance of downstream devices according to the correction increase condition and the correction decrease condition, respectively, so that the entire unit quickly reaches a new operation condition that is safe and stable.

at 2 Figure 5 is a schematic flow diagram of a compensation control method for abruptly changing device performance according to an embodiment of the present disclosure. As in 2 That is, the compensation control method for abruptly changing a device performance according to this embodiment includes the following steps S101 to S103, which will be described in detail below.

In S101, device power information including a rated device power, a current device power, a set set amount, and a measured set amount is acquired, and a device power correction condition is obtained based on the device power information. The device power correction condition includes a correction increase condition and a correction decrease condition. In S102, it is detected whether the correction decreasing condition or the device performance increasing corrective condition is satisfied.

In S103, a value of a device control command is increased at a predetermined rate if it is detected that the correction increase condition is satisfied, and the value of the device control command is decreased in the predetermined rate if it is detected that the correction reduction condition is satisfied.

It is noted that the value of the device control command is increased in the predetermined rate, if it is detected that the correction increase condition is satisfied, and the value of the device control command is not further increased, if it is detected that a predetermined correction increase target value is reached or the correction increase condition is not met. The value of the device control command is reduced in the predetermined rate if it is detected that the correction-reduction condition is satisfied, and the value of the device control command is not further reduced if it is detected that a predetermined correction-reduction target value is reached or does not satisfy the correction-reduction condition becomes.

Prior to step S103, the compensation control method further comprises obtaining a maximum increase / decrease rate of the value of the device control command based on an actual maximum rate of change of the device performance. Optionally, the default rate is the actual maximum rate of change of device performance. As a preferred embodiment, an observation instruction is sent to an upstream controller if it is detected that the correction increase condition or the correction decrease condition is satisfied. Upon receiving the observation information, the upstream controller observes an average value of values of the device control commands from downstream devices to compensate for upstream power and downstream power. For example, in a system in which two downstream devices are parallel, in a case where an output of the upstream controller is unchanged and a change in the device performance of one of the downstream devices is observed, the device performance of the other downstream device is counteracted in one direction changes a direction of the observed changes to keep constant a sum of the device powers of the two downstream devices.

The correction increase condition and the correction decrease condition for the Device performance is generated by performing the synthesis operation on data such as the nominal device power, the device power feedback, the adjusted system value, the measured system value, and other constraining conditions. In a case where the device power correction increase instruction exists, the value of the device control command is increased in the maximum allowable change rate of the device performance, the target value being the predetermined correction increase target value. In a case where the device power correction decrease instruction exists, the value of the device control command is reduced in the maximum allowed rate of change of the device power, the target value being the predetermined correction reduction target value. In this way, the correction control on the basis of the device power which does not exceed the threshold value, small deviations of the adjustment amount parameters and other related parameters which are within the safety margin are ensured, and hence the danger due to the non-linear relationship between the device control command and the device performance with the correction is avoided can be.

In this embodiment, the upstream controller acquires a system main control signal based on a set device power value and a measured device power value, and sends the system main control signal to a downstream control circuit as a main control signal of downstream device power at which an offset operation is performed to obtain a device control command. During the correction control operation, the value of the device control command is increased or decreased in the predetermined rate, and the system adjusts the device power according to the device control command. In other words, the compensation control method for abruptly changing a device power further comprises receiving a main control signal of downstream device power sent from the upstream controller, the main control signal of downstream device power being obtained from the upstream controller based on a set device power value and a measured device power value ; and obtaining the device control command by performing an offset operation on the main control signal of a downstream device power.

On the basis of the abrupt change of device performance described above, the abrupt change in device performance compensation control method according to the present disclosure will be described below in specific application scenarios.

A first deployment scenario involves a compensation control system for abruptly changing device performance for a system in which two devices are running in parallel.

3 Fig. 10 is a schematic structural diagram of a compensation control system for abruptly changing a device performance for a system in which two devices are in parallel. As in 3 As shown, an implementation process of the compensation control method for abruptly changing a device power may include the following steps S11 to S13.

In step S11, a system main control signal is obtained by PID based on a set system value SP, a measured value PV, power feedback from two devices, and the like, and output to a downstream device control circuit by MASTER, which performs distribution and compensation, to obtain a main control signal COOL a downstream device to form.

In step S12, the normal state control commands CO02A and CO02B are generated by an offset operation module and a manual operation module based on the device main control signal CO01.

In step S13, final device control commands COA and COB are generated based on the normal state control commands CO02A and CO02B by a correction increasing process, a correction decreasing process, and a rate control process. The device performance of the system is adjusted according to a device A control command and a device B control command.

Specifically, in a case where the correction increase condition (ORD_U_A or URD_U_B_) is satisfied, the value of the device control command is increased in the predetermined rate to a power increase target value (UA or UB) until the correction increase condition is not satisfied or Value of the device control command reaches the increase target value; and in a case where the correction decreasing condition (ORD_D_A or ORD_D_B) is satisfied, the value of the device control command is reduced in the predetermined rate to a power reduction target value (DA or DB) until the correction decreasing condition is not satisfied or Value of the device control command reaches the reduction target value.

The correction increase condition and the correction decrease condition are obtained by performing the PID synthesis operation on the device operation state, the rated device power, the device power feedback, the adjustment amount, the set adjustment amount, and other restrictive conditions, so that the correction increase condition or the correction decrease condition. Condition for the device performance is given on the assumption that the device power does not exceed the limit value, the deviation between the setting amount and the set value is small, and other parameters do not exceed the allowable safety ranges in the correction operation.

The limit rate for the value of the device control command is determined based on the actual maximum rate of change of the device itself.

In order to prevent an abrupt change in the device control command performance during the correction control operation and a correction release operation, in a case where the correction increase condition or the device performance decrease correction condition is satisfied, an instruction is sent to the upstream controller to supply the upstream controller cause to observe and output an average value of values of device control commands of the downstream devices.

In order to avoid the danger due to the non-linear relationship between the issued instructions and the actual performance of the device A and the device B running in parallel as the power of the device A or the device B changes, the performance of the other device is increased changed in the opposite direction and at the same rate on condition that the upstream control command (the command issued by MASTER) is unchanged, thereby improving the speed and stability of the system. Further, in a case where both devices are switched to the automatic state and the correction increase condition and the correction decrease condition are not satisfied, a device control power offset may be manually set on the premise that the power of the upstream controller remains unchanged; so that the value of the device control command for one device is increased, and the value of the device control command for the other device is reduced to avoid the danger due to the non-linear nature of the device. In a case where the correction-increase condition or the correction-reduction condition is satisfied, or at least one device is in the manual state, the offset power is one-half of a difference between the device control command for the device A and the device control command for the device B. such that when a correction operation is performed on the device control command for one device, the value of the device control command of the other device is changed by the same amount in the opposite direction to keep the overall performance of the two devices unchanged.

A second deployment scenario involves a forced draft fan correction control system in a 600 MW cogeneration plant.

One 600 MW CHP includes two induced draft blowers, ie, one induced draft fan A and one induced draft fan B. After one induced draft fan fails, the opening of the suction fan blade is reduced to a correction reduction target, and the opening of the blade of the other induced draft fan which continues to run is in one predetermined rate to a correction increase target value. A case where the induced draft fan B fails is taken as an example and the correction control operation for the induced draft blowers includes steps of correcting a decrease in the draft fan B, correcting an increase in the induced draft fan A, and observing by a firebox pressure controller, comprising the following steps S21 to S25.

In step S21, the system detects that the induced draft fan B has failed.

In step S22, the bucket of the induced draft fan B is closed to a predetermined target value of 0%.

In step S23, a correction raising instruction for induced draft blower A is issued (the principle is shown in FIG 4 illustrated) by a synthesis operation in a case where a correction raising condition for the induced draft blower A is satisfied.

For example, in a case where all the conditions including that the current of the induced draft fan A is less than 470 A, the value of the instruction for induced draft fan A is less than 75%, the combustion chamber pressure is higher than -200 Pa, and the Load of the unit is less than 300 MW, to be satisfied within 60 seconds after the induced draft fan B has failed, the correction increase instruction for the induced draft fan A is outputted.

In step S24, the maximum rate of change of the position feedback of the moving blade of the induced draft fan is determined to be 2.5% / sec, and the maximum correction increasing rate and the maximum correction decreasing rate of the moving blade of the induced draft fan is set to 2.5% / sec.

In step S25, in the correction operation of the moving blade of the induced draft fan A, the combustion chamber pressure controller (corresponding to the upstream controller of the induced draft fan A and the induced draft fan B) is switched to the observation mode to ensure that the system performance does not abruptly change during the correction operation before and after the correction process has been released.

A third deployment scenario involves a correction control system for induction fan dryer vanes in a 600 MW cogeneration plant.

One 600 MW cogeneration plant includes two induced draft dryers, ie, one induced draft dryer A and one induced draft dryer B. After one induced draft dryer blows out, the opening of the draft fan dryer fan is reduced to a correction reduction target value, and the opening of the nozzle of the other draft dryer fan, which continues to run, becomes within a predetermined one Rate increased to a correction increase target value. A case where the induced draft blower B fails is taken as an example, and the correction control operation for the induced draft blower includes steps for correcting a decrease in the induced draft blower B, correcting an increase in the induced draft blower A, and observing by a total air quantity controller comprising the following steps S31 to S35.

In step S31, the system detects that the induced draft blower B has failed.

In step S32, the opening of the guide vane of the induced draft fan B is decreased to a predetermined correction reduction target value 0%.

In step S33, a correction raising instruction for induced draft blower A is issued (principle is in FIG 5 shown) by a synthesis operation in a case where a correction raising condition for the induced draft blower A is satisfied.

For example, in a case where all the conditions including that the induced draft blower A current is less than 148 A, the value of the instruction for induced draft blower A is less than 93%, the combustion chamber pressure is higher than 200 Pa, and the load If the unit is smaller than 300 MW, to be satisfied within 60 seconds after the induced draft blower B has failed, the suction draft drying blower correction correction instruction A is outputted.

In step S34, the maximum rate of change of the position feedback of the suction draft fan guide blade is determined to be 2.5% / s, and the maximum correction rate and the maximum correction rate of the suction draft fan blade are set to 2.5% / s.

In step S35, in the correction raising operation of the suction draft dryer fan A, the total air volume controller (corresponding to the upstream controller of the suction draft fan A and the suction draft fan B) is switched to the observation mode to ensure that the system performance does not abruptly change during the correction operation before and after the correction process has been released.

A fourth deployment scenario involves a correction control system for a turbine-driven feedwater pump in a 600 MW power plant.

One 600 MW CHP includes two feedwater pumps, ie, a feedwater pump A and a feedwater pump B. After one feedwater pump fails, the speed of the feedwater pump is reduced to a correction reduction target value and the speed of the other feedwater pump, which continues to run, is set to a predetermined rate Correction increase target value increased. A case where the feedwater pump B fails is taken as an example, and the feedwater pump correction control operation includes steps of correcting a decrease in the rotational speed of the feedwater pump B, correcting an increase in the rotational speed of the feedwater pump A, and monitoring by a supply water flow rate controller comprising the following steps S41 to S45.

In step S41, the system detects that the feedwater pump B has failed.

In step S42, a value of a speed command of the feed water pump B is switched to 0 rpm.

In step S43, a correction increase instruction for feedwater pump A is issued (principle is in FIG 6 illustrated) by a synthesis operation in a case where a correction raising condition for the feedwater pump A is satisfied. For example, in a case where all the conditions including that the speed of the feed water pump A is lower than 5400 rpm, that the total supply water flow rate is less than a steam flow rate of 50 t / h, the drum water level becomes less than 30 mm , and the load of the unit is less than 300 MW, to be satisfied within 60 seconds after the feedwater pump B has failed, the correction increase instruction for feedwater pump A is issued.

In step S44, the maximum rate of change of the speed of the feed water pump that can actually be reached by the feed water pump is obtained as 1000 revolutions per minute ² , and the maximum correction rate and the maximum correction rate of the speed of the feed water pump are set to 1000 revolutions per minute ² .

In step S45, in the correction increasing operation of the rotational speed of the feed water pump A, the drum water level controller and the supply water flow rate controller are switched to the observation mode to ensure that the system performance does not abruptly change during the correction operation of the feed water pump and before and after the correction process has been released.

It is noted that each of the above-described embodiments of methods is described as a combination of a series of simplified representation operations. One skilled in the art, however, will understand that the present disclosure is not limited to the described sequence of operations, as some of the steps may be performed in other orders or concurrently in accordance with the present disclosure. In addition, one skilled in the art will understand that the embodiments described in the specification are preferred embodiments and that not all of the processes and modules that occur in these embodiments are necessary to the present disclosure.

A compensation control system for abruptly changing a device performance according to an embodiment of the present disclosure that can be used to perform the above-described compensation control method for abruptly changing a device performance will be explained below. 7 FIG. 10 is a schematic structural diagram of a compensation control system for abruptly changing device performance according to an embodiment of the present disclosure. FIG. For better understanding, only parts relating to the embodiments of the present disclosure will be incorporated herein by reference 7 shown. As one skilled in the art will understand, the in 7 shown system structure or the system structure does not limit the system, and more or fewer components than shown, combinations of components or different component arrangements may be included.

7 FIG. 10 is a schematic structural diagram of a compensation control system for abruptly changing device performance according to an embodiment of the present disclosure. FIG. As in 6 As shown, the abrupt changeover device performance compensation control system according to this embodiment includes a synthesis operation module 610 , a detection module 620 , and an increase and decrease control module 630 ,

The synthesis operation module 610 is configured to obtain device power information including a rated device power, a current device power, a set adjustment amount and a measured adjustment amount, and a device power correction control condition based on the device power information. The device power correction control condition includes a correction increase condition and a correction decrease condition.

The acquisition module 620 is configured to detect whether the correction increase condition or the device performance decrease correction condition is satisfied.

The increase and decrease control module 630 is arranged to increase a value of a device control command at a predetermined rate, if it is detected that the correction increase condition is satisfied, and to decrease the value of the device control command in the predetermined rate, if it is detected that the correction reduction condition is satisfied.

Optionally, to change an abrupt change in the device control command output during the correction operation and the correction release operation, the compensation control system for abruptly changing a device performance may further include an observation module 640 which is arranged to send an observation instruction to an upstream controller if it is detected that the correction increase condition or the correction decrease condition is satisfied. The upstream controller observes an average value of values of device control commands from downstream devices to provide an upstream power and a downstream power upon reception to balance the observation statement. For example, in a system in which two downstream devices run in parallel, in a case where the performance of the upstream controller is unchanged and a change in device performance is observed by one of the downstream devices, the device performance of the other downstream device becomes one Changed direction against a direction of the observed change in order to keep constant a sum of the device power of the two downstream devices.

It is noted that the synthesis operation module 610 is further set to obtain a maximum increase / decrease rate of the value of the device control command based on an actual maximum rate of change of the device performance.

The increase and decrease control module 630 is further configured not to further increase the value of the device control command if it is detected that a predetermined correction increase target value is reached or the correction increase condition is not satisfied, and not further decrease the value of the device control command if it is detected that a predetermined correction -Reduction target value is reached or the correction-reduction condition is not satisfied.

Optionally, the abrupt change in device power compensation control system further comprises an offset control module configured to receive a main control signal of downstream device power transmitted from the upstream controller, the main control signal of downstream device power being set by the upstream controller based on a set of control values Device power value and a measured device power value is obtained; and obtain the device control command by performing an offset operation on the main control signal of a downstream device power. The increase and decrease module 630 is further configured to adjust the device power in accordance with the device control command. According to the above-described embodiment of the abrupt change in device power compensation control system, correction control based on the device power which does not exceed the threshold value, with small deviations of the adjustment amount parameters and other related parameters, are within a safety margin. With the correction control, the danger due to the non-linear relationship between the device control commands and the device performance can be avoided, so that the performance of the current device can be increased as fast as possible to cause the device to reach a new operating condition that is safe and stable is, which significantly improves the success rate of RB and FCB of the unit.

It is noted that the information exchange, the execution process, and the like between the modules / units in the above-described embodiments are based on the same concept as that of the embodiment of the method of the present disclosure whose technical effect is the same as that of the above-described embodiment the method of the present disclosure. Therefore, one can refer to the embodiments of the method for detailed description, which is not repeated here.

In addition, in one of the above-described embodiments of the abrupt change in device performance, the logical subdivision of functional modules is merely exemplary, and in actual use, for example, to meet a hardware configuration requirement or consideration to facilitate software implementation, the above functions are mapped to different functional modules , In other words, the internal structure of the compensation control system for abruptly changing device performance is divided into different functional modules to perform all or part of the functions described above.

The above embodiments have different focuses, and a part that has not been described in detail in one embodiment can be found in the related description of another embodiment.

In addition, in the above embodiments of the present disclosure, the functional modules may be integrated into a processing module, or they may be separate physical modules. Alternatively, two or more modules may be integrated in one module. The above-mentioned integrated module may be implemented in the form of hardware or in the form of a software function module.

In the above, a balance control method and a compensation control system for abruptly changing a device performance according to the present disclosure will be described. One skilled in the art will recognize that changes may be made to the embodiments and a range of use based on a concept of the embodiments of the present disclosure. Against this background Content in the description should not be construed as limiting the present disclosure.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• CN 201510718664 [0001]

Claims (10)

A compensation control method for abruptly changing a device performance, comprising: Obtaining device power information including a rated device power, current device power, a set set amount and a measured set amount, and obtaining a device power correction condition based on the device power information, wherein the device power correction condition includes a correction increase condition and a correction decrease condition; Detecting whether the correction increase condition or the device performance decrease correction condition is satisfied; and Increasing a value of a device control command at a predetermined rate if it is detected that the correction increase condition is satisfied, and decreasing the value of the device control command in the predetermined rate if it is detected that the correction reduction condition is satisfied. Compensating control method for abrupt change of a device performance after Claim 1 wherein, upon detecting whether the correction increase condition or the device performance decrease correction condition is satisfied, the compensation control method further comprises: transmitting an observation instruction to an upstream controller if it is detected that the correction increase condition or the correction decrease Condition is met; and observing, by the upstream controller upon receipt of the watch command, an average value of values of the device control commands from downstream devices to compensate for upstream power and downstream power. A balance control method for abruptly changing a device power according to Claim 2 wherein observing the average value of the values of the device control commands of the downstream upstream power and downstream power compensating devices comprises: in a system in which two downstream devices run in parallel, in a case where power of the upstream controller is unchanged and a change in the device performance of one of the downstream devices is observed, the device performance of the other downstream device in a direction opposite to a direction of the observed change to keep a sum of the device powers of the two downstream devices constant. Compensating control method for abrupt change of a device performance after Claim 1 wherein, prior to increasing the value of the device control command in the predetermined rate and increasing the value of the device control command in the predetermined rate, the compensation control method further comprises: obtaining a maximum increase / decrease rate of the value of the device control command based on an actual maximum rate of change of the device power; after increasing the value of the device control command in the predetermined rate, the compensation control method further comprises: stopping increasing the value of the device control command if it is detected that a predetermined correction increase target value is reached or the correction increase condition is not satisfied; and after decreasing the value of the device control command in the predetermined rate, the compensation control method further comprises: stopping lowering the value of the device control command if it is detected that a predetermined correction reduction target value is reached or the correction reduction condition is not satisfied. Compensating control method for abrupt change of a device performance after Claim 1 , further comprising: receiving a main control signal of a downstream device power sent from the upstream controller, the main control signal of a downstream device power being obtained by the upstream controller based on a set device power value and a measured device power output value; and obtaining the device control command by performing an offset operation on the main control signal of a downstream device power. A compensation control system for abruptly changing a device performance, comprising: a synthesis operation module configured to acquire device performance information including a rated device power, a current device power, a set set amount and a measured set amount, and a device power correction control condition based on the device performance information wherein the device power correction control condition includes a correction increase condition and a correction decrease condition; a detection module configured to detect whether the correction increase condition or the device performance drop correction condition is satisfied; and an increase and decrease control module configured to increase a value of a device control command at a predetermined rate if it is detected that the correction increase condition is satisfied and to decrease the value of the device control command at the predetermined rate, if detected is that the correction reduction condition is satisfied. Compensating control system for abrupt change of a device power after Claim 6 , further comprising an observation module configured to send an observation instruction to an upstream controller if it is detected that the correction increase condition or the correction decrease condition is satisfied, wherein the upstream controller obtains an average value upon receipt of the observation instruction values of device control commands from downstream devices to compensate for upstream power and downstream power. Compensating control system for abrupt change of a device power after Claim 7 wherein the monitoring of the upstream controller of an average value of the values of the device control commands of the downstream upstream power and downstream power compensating devices comprises: in a system in which two downstream devices are in parallel, in a case where the power of the upstream controller is unchanged and the change in the device performance is observed by one of the downstream devices, the device performance of the other downstream device is changed in a direction opposite to a direction of the observed change to keep a sum of the device powers of the two downstream devices constant. Compensating control system for abrupt change of a device power after Claim 6 wherein the synthesis operation module is further configured to obtain a maximum increase / decrease rate of the value of the device control command based on an actual maximum rate of change of device performance; and the increase and decrease control module is further configured to stop increasing the value of the device control command if it is detected that a predetermined correction increase target value is reached or the correction increase condition is not satisfied, and increasing the value of the device control command stop if it is detected that a predetermined correction-reduction target value is reached or the correction-reduction condition is not satisfied. Compensating control system for abrupt change of a device power after Claim 6 , further comprising: an offset control module configured to receive a main control signal of a downstream device power sent from the upstream controller, the main control signal of downstream device power by the upstream controller based on a set device power value and a measured device power value is obtained; and obtain the device control command by performing an offset operation on the main control signal of a downstream device power.

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