TWI833188B - Gas turbine unit evaluation and verification system, built-in program and its device - Google Patents

Abstract

A rating and verification system for gas turbine units, including: a cloud server that provides a first manufacturer and a second manufacturer to connect to the cloud server respectively through a client device, and the first manufacturer and the second manufacturer respectively Register the parameters of a plurality of gas turbine units; a memory to store the executed evaluation algorithm and verification algorithm corresponding to each parameter; and a display to display that the first manufacturer and the second manufacturer have passed the evaluation algorithm and the verification The data of the algorithm; according to the parameters of the first manufacturer and the second manufacturer, the evaluation algorithm is calculated respectively, and based on this, the first manufacturer or the second manufacturer is judged to win the bid, and the first manufacturer or the second manufacturer that wins the bid is The second manufacturer's parameters perform the verification algorithm and are displayed on the display.

Description

Gas turbine unit evaluation and verification system, built-in program and its device

The invention relates to a bidding system, and in particular, to a rating and verification system, a built-in program and a device thereof that can analyze the operating efficiency and production capacity of gas turbine units from multiple bidders.

For power plants, steam power plants, chemical plants, incineration plants, etc. that frequently start, stand by, and shut down, starting up often takes time. Not only does it respond slowly to the demand of the power system, but the thermal efficiency during the starting process is much lower than the full load condition, causing serious problems. Energy is wasted, and the unit's continued energy consumption during standby will also reduce the overall thermal efficiency of the unit. Please refer to the first picture. The standby energy consumption and start-up time of production equipment or systems and the impact of resource consumption during start-up will cause production cost differences, especially in the early stages of factory construction plans (public projects or private factory construction), the bid invitation documents During the evaluation mechanism and tender review process, in terms of standby, start-up time and resource consumption during the start-up period, it is generally only required to complete the process to full load within a limited time. In order to achieve the fairness of the tender, the slowest equipment is often used. The startup time is a standard standard, and the resource consumption rate during standby and startup periods is not included in the evaluation benchmark. As a result, high-speed equipment, low standby energy consumption, and low startup resource consumption equipment do not have appropriate evaluation advantages, and the overall operating cost of the equipment It cannot be effectively controlled, causing loss of benefits to production agencies or private enterprises.

As the proportion of green energy in Taiwan increases in the future, generating units will be on standby and restarted more frequently every day. Taking into account the energy consumption of an economic life of 25 years, there is a real need to develop a set of standby and start-up thermal units. Consumption rate and startup time evaluation system.

In view of this, the inventor has accumulated many years of research and practical experience in related fields, and specially invented a standby and start-up heat rate and start-up time evaluation system of a gas turbine compound cycle unit to improve the deficiencies of the above-mentioned conventional technologies.

A computer system for verifying a gas turbine unit of the present invention includes: a cloud server that provides a first manufacturer and a second manufacturer to connect to the cloud server respectively through a client device. The first manufacturer and the second manufacturer The manufacturer separately registers the parameters of a plurality of gas turbine units; a memory that stores the executed evaluation algorithm and verification algorithm corresponding to each parameter; and a display that displays the first manufacturer and the second manufacturer after the evaluation algorithm and The data of the verification algorithm is calculated by the evaluation algorithm according to the parameters of the first manufacturer and the second manufacturer respectively, and based on this, it is judged that the first manufacturer or the second manufacturer wins the bid, and the first manufacturer that wins the bid is The parameters of the manufacturer or the second manufacturer are used to perform the verification algorithm and are displayed on the display.

A built-in program for evaluation and verification of gas turbine units. After the computer executes the program, a evaluation algorithm and a verification algorithm are implemented. The evaluation algorithm includes a first calculation function, a second calculation function, and a third calculation function, a fourth calculation function, a fifth calculation function and a sixth calculation function. The first calculation function is Hsb=8760*Cfsb/100, where Hsb: the annual average standby operation hours of the gas turbine unit, in hours ; Cfsb: The annual standby ratio of the gas turbine unit, a variable set by an owner, in %.

The second calculation function is HRsbev=HRsb*Hsb*(Psb/Pf1), where HRsbev: the standby heat rate evaluation value of the gas turbine unit, in kJ/kWh; HRsb: the gas turbine unit is supplied to the factory and exported to the factory in standby mode. The heat consumption rate of external power is a variable registered by the first manufacturer and the second manufacturer, and the unit is kJ/kWh; Psb: When the gas turbine unit is on standby and generates electricity on its own, it supplies in-plant and out-of-plant electric power (the upper limit of the out-of-plant power output is set by the owner). The variables are registered by the first manufacturer and the second manufacturer. The unit is MW; PfL: Gas turbine The full-load power generation power of the set design point is registered as a variable by the first manufacturer and the second manufacturer, and the unit is MW; the third calculation function is Ha=8760*Cf/100, where Ha: the annual average full-load operation hours of the gas turbine unit , unit is hour; Cf: annual full load ratio of gas turbine unit, variable set by an owner, unit is %.

The fourth calculation function is HRsu=Fc/Eg*1000, where HRsu: the average heat rate during the startup of the gas turbine unit, in kJ/kWh; Fc: the energy consumption of each startup of the gas turbine unit, providing a first The manufacturer and a second manufacturer register variables, the unit is MJ; Eg: the power generation rate of the gas turbine unit each time it is started, the first manufacturer and the second manufacturer register variables, the unit is kWh.

The fifth calculation function includes HRo1=(HRf * Ha*f1+HRsu*Ns*Ts/60+HRsbev)/(Ns*Ts/60+Ha+Hsb*Psb/PfL) and HRo2=(HRf*Ha* f1+HRsu*Ns*Ts/60+HRsbev)/(Ns*Ts/60+Ha+Hsb*Psb/PfL), where HRo1 and HRo2: the guaranteed overall heat rate values of the first manufacturer and the second manufacturer The calculated value, the unit is kJ/kWh; HRf: the heat rate of the gas turbine unit at full load, the variable is registered by the first manufacturer and the second manufacturer, the unit is kJ/kWh; Ha: the annual average full-load operating hours of the gas turbine unit, which is imported from the third calculation function, in hours; f1: the heat rate correction parameter of the gas turbine unit at full load, and its calculation formula is as follows: f1=(PfL *Ha)/(PfL*Ha-Psbc*Hsb)

PfL: The full-load power generation power of the gas turbine unit at the design point, a variable registered by the first manufacturer and the second manufacturer, in MW; Psbc: The external input power of the gas turbine unit during standby, determined by the first manufacturer and the second manufacturer Manufacturer registration variable, unit is MW; Hsb: average annual standby operation hours of the gas turbine unit, imported by the first calculation function, unit is hour; HRsu: average heat rate during the startup period of the gas turbine unit, which is calculated by the first calculation function Four calculation functions are imported, the unit is kJ/kWh; Ns: the average number of starts of the gas turbine unit per year, a variable set by the owner, the unit is times/year; Ts: the time from the ignition of the gas turbine unit to the full load of the gas turbine unit, determined by the The variables registered by the first manufacturer and the second manufacturer, the unit is points; HRsbev: the standby heat rate evaluation value of the gas turbine unit, imported from the second calculation function, the unit is kJ/kWh; Psb: the power supply of the gas turbine unit when it is on standby to generate electricity The in-factory and out-factory power output (the upper limit of the out-factory power output is set by the owner) is registered as a variable by the first manufacturer and the second manufacturer, and the unit is MW.

The sixth calculation function is HRv=(HRo1-HRo2)*Ev, where HRv: The calculated value of the difference in evaluation value of the overall heat rate of the first manufacturer and the second manufacturer, in Taiwan dollars; HRo1: The calculated value of the guaranteed value of the overall heat rate of the first manufacturer, which is calculated by the fifth manufacturer The calculation function is imported, and the unit is kJ/kWh; HRo2: the calculated value of the first manufacturer's overall heat rate guarantee value, which is imported by the fifth calculation function, and the unit is kJ/kWh; Ev: which is calculated by The value of a unit heat rate is a variable set by the owner, and the unit is Taiwan dollars/kJ/kWh; the evaluation is based on the efficiency evaluation value HRv established by a public institution or a consulting company in the bid invitation specifications, thereby judging the first manufacturer Or the second manufacturer wins the bid; the verification algorithm includes a first verification calculation function, a second verification calculation function, a third verification calculation function and a fourth verification calculation function, and the first verification calculation function is HRsbeva= HRsba*Hsb*(Psba/PfLa), where HRsbeva: the measured heat rate verification value of the gas turbine unit in standby mode, in kJ/kWh; HRsba: the measured heat rate of the gas turbine unit in standby mode for supplying in-plant and outgoing power. , is the measured variable of the gas turbine unit of the first manufacturer or the second manufacturer that won the bid, the unit is kJ/kWh; Psba: the measured power power of the gas turbine unit in and out of the factory when it is on standby to generate electricity (output power outside the factory) The upper limit is set by the owner), which is the measured variable of the gas turbine unit of the first manufacturer or the second manufacturer that won the bid, in MW; PfLa: the measured full-load power generation power of the gas turbine unit at the design point, which is the measured variable of the first manufacturer or the second manufacturer that won the bid. Measured variables of the gas turbine unit of the second manufacturer, in MW.

The second verification calculation function is HRsua=Fca/Ega*1000, where HRsua: the measured average heat rate during startup of the gas turbine unit, in kJ/kWh; Fca: the measured startup energy consumption of the gas turbine unit, which is the measured variable of the gas turbine unit of the first or second manufacturer that won the bid, in unit is MJ; Ega: the measured startup power generation degree of the gas turbine unit, which is the measured variable of the gas turbine unit of the first manufacturer or the second manufacturer that won the bid, and the unit is kWh.

The third verification calculation function is HRoA=(HRfa*Ha*f2+HRsua*Ns*Tsa/60+HRsbeva)/(Ns*Tsa/60+Ha+Hsb*Psbca/PfLa), where HRoA: measured overall heat consumption Guaranteed rate value, unit is kJ/kWh; HRfa: the measured heat rate of the gas turbine unit at full load; measured variable, unit is kJ/kWh; Ha: annual average full-load operating hours of the gas turbine unit, calculated by the third calculation function Import, unit is hour; f2: the measured heat rate correction parameter of the gas turbine unit when it is fully loaded, the calculation formula is as follows: f2=(PfLa*Ha)/(PfLa*Ha-Psbca*Hsb); PfLa: gas turbine unit The actual measured full-load power generation power is the measured variable of the gas turbine unit of the first manufacturer or the second manufacturer that won the bid, and the unit is MW; Psbca: the measured external input power of the gas turbine unit during standby, which is the first manufacturer or the second manufacturer that won the bid. The measured variables of the gas turbine unit of the second manufacturer, the unit is MW; Hsb: the annual average standby operation hours of the gas turbine unit, imported from the first calculation function, the unit is hours; HRsua: the measured average heat rate during the start-up period of the gas turbine unit, imported from the second verification calculation function, the unit is kJ/kWh; Ns: the average number of starts of the gas turbine unit per year, a variable set by the owner, the unit is times/ Year; Tsa: measured time from gas turbine unit ignition to gas turbine unit full load; measured variable, unit is minute.

The fourth verification calculation function is HRp=(HRo1 or HRo2-HRoA)*Pv, where HRp: is the calculated penalty value of the first manufacturer or the second manufacturer that wins the bid for failing to meet the guaranteed value of the overall heat rate, in Taiwan dollars; HRo1 or HRo2: The guaranteed value of the overall heat rate of the first or second manufacturer that won the bid imported from the fifth calculation function, in kJ/kWh; HRoA: the measured overall value imported from the third verification calculation function Heat rate, unit is kJ/kWh; Pv: unit heat rate setting penalty value; set by the owner, unit is NT$/kJ/kWh.

A device for evaluation and verification of gas turbine units, which includes: a memory; a display; and a computing module, which is connected to the display. The computing module converts the complex parameters stored in the memory into The evaluation algorithm and verification algorithm are set to calculate the gas turbine unit of the qualified bidder and display it on the display.

The purpose of this invention is to provide an appropriate evaluation, business selection or bidding mechanism for public institutions to avoid the failure of excellent equipment (system) manufacturers to win the bid and cause loss of benefits to production agencies or private enterprises.

The first picture is a schematic diagram of the commonly used bidder heat rate evaluation and comparison mechanism.

The second figure is a schematic diagram of the time curve from ignition to full load of the gas turbine unit of the first manufacturer of the present invention.

The third figure is a schematic diagram of the time curve from ignition to full load of the gas turbine unit of the second manufacturer of the present invention.

The fourth figure is a schematic diagram of unit efficiency during startup by the first manufacturer of the present invention.

The fifth figure is a schematic diagram of unit efficiency during startup of the second manufacturer of the present invention.

The sixth figure is a schematic diagram of the heat consumption rate evaluation and comparison mechanism of bidders according to the present invention.

The gas turbine unit evaluation and verification system of the present invention includes: a cloud server, which provides a first manufacturer and a second manufacturer to connect to the cloud server respectively through a client device. The first manufacturer and the second manufacturer Manufacturers register the parameters of multiple gas turbine units separately.

A memory that stores the executed evaluation algorithm and verification algorithm corresponding to each parameter.

A display that displays the data of the first manufacturer and the second manufacturer that have passed the evaluation algorithm and the verification algorithm; according to the parameters of the first manufacturer and the second manufacturer, they have been calculated by the evaluation algorithm respectively. According to the evaluation The algorithm calculation result determines whether the first manufacturer or the second manufacturer has won the bid, and the verification algorithm is performed using the parameters of the first manufacturer or the second manufacturer that won the bid, and is displayed on the display.

The ranking algorithm includes a first calculation function, a second calculation function, a third calculation function, a fourth calculation function, a fifth calculation function and a sixth calculation function. The first calculation function is Hsb=8760 *Cfsb/100, among which Hsb: the annual average standby operation hours of the gas turbine unit, in hours; Cfsb: the annual standby ratio of the gas turbine unit, a variable set by an owner, in %.

The second calculation function is HRsbev=HRsb*Hsb*(Psb/Pf1), where HRsbev: the standby heat rate evaluation value of the gas turbine unit, in kJ/kWh; HRsb: the gas turbine unit is supplied to the factory and exported to the factory in standby mode. The heat rate of external power is a variable registered by the first manufacturer and the second manufacturer, and the unit is kJ/kWh; Psb: When the gas turbine unit is on standby to generate electricity by itself, it supplies internal and external power to the factory, and the upper limit of the output of external power. Set by the owner, variables are registered by the first manufacturer and the second manufacturer, the unit is MW; PfL: the full load power generation power of the gas turbine unit design point, variables are registered by the first manufacturer and the second manufacturer, the unit is MW.

The third calculation function is Ha=8760*Cf/100, where Ha: the annual average full-load operating hours of the gas turbine unit, in hours; Cf: the annual full-load ratio of the gas turbine unit, a variable set by the owner, in %.

Please refer to the second and third figures, which are schematic diagrams of the time curves from ignition to full load of the gas turbine units of the first manufacturer and the second manufacturer.

The fourth calculation function is HRsu=Fc/Eg*1000, where HRsu: the average heat rate during the startup of the gas turbine unit, in kJ/kWh; Fc: the energy consumption of each startup of the gas turbine unit, providing at least one first One manufacturer and at least one second manufacturer register variables, the unit is MJ; Eg: the power generation rate of the gas turbine unit each time it is started, the first manufacturer and the second manufacturer register variables, the unit is kWh; Please refer to the fourth and fifth figures, which are schematic diagrams of unit efficiency during startup by the first manufacturer and the second manufacturer.

The fifth calculation function includes HRo1=(HRf*Ha*f1+HRsu*Ns*Ts/60+HRsbev)/(Ns*Ts/60+Ha+Hsb*Psb/PfL) and HRo2=(HRf*Ha* f1+HRsu*Ns*Ts/60+HRsbev))/(Ns*Ts/60+Ha+Hsb*Psb/PfL), where HRo1 and HRo2: the overall heat rate guarantee of the first manufacturer and the second manufacturer The calculated value of the value, the unit is kJ/kWh; HRf: the heat rate of the gas turbine unit at full load, variables registered by the first manufacturer and the second manufacturer, the unit is kJ/kWh; Ha: the annual average full load of the gas turbine unit The number of operating hours is imported from the third calculation function, and the unit is hours; f1: the heat rate correction parameter of the gas turbine unit at full load, the calculation formula is as follows: f1=(PfL*Ha)/(PfL*Ha -Psbc*Hsb); PfL: The full-load power generation power of the gas turbine unit at the design point, a variable registered by the first manufacturer and the second manufacturer, in MW; Psbc: The external input power of the gas turbine unit during standby, determined by the second manufacturer The first manufacturer and the second manufacturer register variables, the unit is MW; Hsb: the annual average standby operation hours of the gas turbine unit, imported by the first calculation function, the unit is hours; HRsu: the average heat rate during the start-up period of the gas turbine unit, which is imported from the fourth calculation function, the unit is kJ/kWh; Ns: the average number of starts of the gas turbine unit per year, a variable set by the owner, the unit is times/ Year; Ts: the time from the ignition of the gas turbine unit (gas turbine) to the full load of the gas turbine unit, the variable is registered by the first manufacturer and the second manufacturer, in minutes; HRsbev: the standby heat rate rating value of the gas turbine unit, determined by the second manufacturer The second calculation function is imported, the unit is kJ/kWh; Psb: When the gas turbine unit is on standby and generates electricity by itself, it supplies in-plant and outputs off-site power (the upper limit of the output off-site power is set by the owner), between the first manufacturer and the second Manufacturer login variable, unit is MW.

The sixth calculation function is HRv=(HRo1-HRo2)*Ev, where HRv: the calculated value difference of the overall heat consumption rate of the first manufacturer and the second manufacturer, in Taiwan dollars; HRo1: the first manufacturer The calculated value of the guaranteed overall heat rate value of the second manufacturer is imported from the fifth calculation function, and the unit is kJ/kWh; HRo2: the calculated value of the guaranteed overall heat rate value of the second manufacturer, which is calculated by the third calculation function. Five calculation functions are imported, the unit is kJ/kWh; Ev: it is the value of one unit of heat rate, a variable set by the owner, the unit is NT$/kJ/kWh.

During the evaluation, the efficiency evaluation value HRv formulated by a public institution or a consulting company in the bid invitation specifications will be included in the bid selection and evaluation mechanism as a bidding judgment.

The verification algorithm includes a first verification calculation function, a second verification calculation function, a third verification calculation function and a fourth verification calculation function.

The first verification calculation function is HRsbeva=HRsba*Hsb*(Psba/PfLa), where HRsbeva: the measured heat rate verification value of the gas turbine unit in standby, in kJ/kWh; HRsba: the measured heat rate verification value of the gas turbine unit in standby supplied to the factory and The heat rate of power output outside the factory is the measured variable of the gas turbine unit of the first manufacturer or the second manufacturer that won the bid, and the unit is kJ/kWh; Psba: the actual measured variable of the gas turbine unit when it is on standby to generate electricity on its own and supplied to the factory and the output factory External power power, the upper limit of the output off-site power is set by the owner, and is the measured variable of the gas turbine unit of the first manufacturer or the second manufacturer that won the bid, in MW; PfLa: the measured full-load power generation power of the gas turbine unit design point, is The measured variables of the gas turbine unit of the first manufacturer or the second manufacturer that won the bid, in MW; the second verification calculation function is HRsua=Fca/Ega*1000, where HRsua: the measured average heat consumption of the gas turbine unit during startup Rate, unit is kJ/kWh; Fca: measured startup energy consumption of the gas turbine unit, which is the measured variable of the gas turbine unit of the first or second manufacturer that won the bid, unit is MJ; Ega: measured startup power generation of the gas turbine unit , are the measured variables of the gas turbine unit of the first manufacturer or the second manufacturer that won the bid, and the unit is kWh.

The third verification calculation function is HRoA=(HRfa*Ha*f2+HRsua*Ns*Tsa/60+HRsbeva)/(Ns*Tsa/60+Ha+Hsb*Psbca/PfLa), where HRoA: measured overall heat consumption Rate guaranteed value, unit is kJ/kWh; HRfa: the measured heat rate of the gas turbine unit at full load; the measured variable, in kJ/kWh; Ha: the annual average full-load operating hours of the gas turbine unit, imported by the third calculation function, in hours; f2: gas The measured heat rate correction parameter when the turbine unit is fully loaded is calculated as follows: f2=(PfLa*Ha)/(PfLa*Ha-Psbca*Hsb)

PfLa: the measured full-load power generation power of the gas turbine unit, which is the measured variable of the gas turbine unit of the first or second manufacturer that won the bid, in MW; Psbca: the measured external power input of the gas turbine unit during standby, which is the measured variable of the gas turbine unit that won the bid. The measured variables of the gas turbine unit of the first manufacturer or the second manufacturer, the unit is MW; Hsb: the annual average standby operation hours of the gas turbine unit, imported by the first calculation function, the unit is hours; HRsua: the start-up of the gas turbine unit The measured average heat rate during the period is imported from the second verification calculation function, the unit is kJ/kWh; Ns: the average number of starts of the gas turbine unit per year, a variable set by the owner, the unit is times/year; Tsa: the gas turbine unit The measured time from the ignition of the group (gas turbine) to the full load of the gas turbine unit; the measured variable, the unit is minutes.

The fourth verification calculation function is HRp=(HRo1 or HRo2-HRoA)*Pv, where HRp: is the calculated penalty value of the first manufacturer or the second manufacturer that wins the bid for failing to meet the guaranteed value of the overall heat rate, in Taiwan dollars; HRo1 or HRo2: The overall heat rate guarantee value of the first or second manufacturer that wins the bid is imported from the fifth calculation function, kJ/kWh; in other words, if the successful bidder is the first manufacturer, log in the third The HRo1 value of one manufacturer. If the winning bidder is a second manufacturer, the HRo2 value of the second manufacturer will be recorded.

HRoA: The measured overall heat rate imported from the third verification calculation function, the unit is kJ/kWh; Pv: The unit heat rate setting penalty value; set by the owner, the unit is NT$/kJ/kWh.

At the time of acceptance, the penalty value Pv set by the business unit or the consulting company in the bid invitation specifications will be included in the acceptance mechanism.

Calculate the penalty amount when the overall heat rate of the contract manufacturer (i.e., the first or second manufacturer that wins the bid) does not reach the guaranteed value, and this HRp is included in the verification mechanism as the penalty standard.

The gas turbine unit mentioned above is a compound cycle generator unit, which is a power generation method that combines a gas turbine unit and a steam power unit. After the gas turbine unit drives the generator to generate electricity, the hot gas discharged by the gas turbine at high temperature is then used to pass through the heat. After the recovery boiler recovers part of the heat, the waste gas is discharged again, and the steam generated by the heat recovery boiler is sent to the steam turbine to drive the generator to generate electricity again.

Based on the evaluation algorithm, the present invention compares the first manufacturer and the second manufacturer respectively to determine whether the first manufacturer or the second manufacturer wins the bid; the verification algorithm provides verification of the first manufacturer or the second manufacturer that wins the bid. Whether the actual measured results of the manufacturer's gas turbine unit are consistent with the relevant data registered in the second, third, fourth, fifth and sixth calculation functions. The overall heat rate of the first or second manufacturer that won the bid did not meet the guaranteed The penalty amount is based on HRp as the penalty standard.

The present invention can also be a built-in program for evaluation and verification of gas turbine units. After the computer executes the program, a evaluation algorithm and a verification algorithm are implemented. The evaluation algorithm and the verification algorithm are the same as those mentioned above, so they are no longer necessary. Repeat.

The present invention can also be a device for evaluation and verification of gas turbine units, which includes: a memory; a display; and a computing module, which is connected to the display, and the computing module converts the data stored in the memory. The plural parameters are calculated according to the set evaluation algorithm and verification algorithm to calculate the gas turbine unit of the qualified bidder, and are displayed on the display. The evaluation algorithm and the verification algorithm are the same as the above, so they will not be described again.

Please refer to Figure 6. In the evaluation algorithm of the present invention, multiple parameters of the first manufacturer and the second manufacturer that need to participate in the bidding can be more in line with the actual needs of the bidding manufacturers, and the resource consumption rate during the startup period is included in the evaluation benchmark. This enables high-speed devices and devices with low startup resource consumption to gain appropriate evaluation advantages, thereby overcoming the shortcomings of previous technologies.

However, the above are only preferred embodiments of the present invention and cannot be used to limit the scope of the present invention. All changes and modifications that are obvious to those skilled in the art should be deemed not to depart from the scope of the present invention. The essence of the present invention.

Claims (5)

A system for evaluation and verification of gas turbine units, which includes: a cloud server that provides a first manufacturer and a second manufacturer to connect to the cloud server respectively through a client device. The first manufacturer and the second manufacturer The manufacturer separately registers the parameters of a plurality of gas turbine units; a memory that stores the executed evaluation algorithm and verification algorithm corresponding to each parameter; and a display that displays the first manufacturer and the second manufacturer after the evaluation algorithm and The data of the verification algorithm is calculated by the evaluation algorithm according to the parameters of the first manufacturer and the second manufacturer respectively, and based on this, it is judged that the first manufacturer or the second manufacturer wins the bid, and the first manufacturer that wins the bid is The parameters of the manufacturer or the second manufacturer are used to perform the verification algorithm and are displayed on the display. The gas turbine unit evaluation and verification system as claimed in claim 1, wherein the evaluation algorithm includes a first calculation function, a second calculation function, a third calculation function, a fourth calculation function, and a fifth calculation function. And a sixth calculation function, the first calculation function is Hsb=8760*Cfsb/100, where Hsb: the annual average standby operation hours of the gas turbine unit, in hours; Cfsb: the annual standby ratio of the gas turbine unit, determined by an owner Set the variables, the unit is %; the second calculation function is HRsbev=HRsb*Hsb*(Psb/PfL), where HRsbev: the standby heat rate rating value of the gas turbine unit, the unit is kJ/kWh; HRsb: the standby gas turbine unit The heat rate of power supplied to the factory and exported to outside the factory during the period is registered as a variable by the first manufacturer and the second manufacturer, and the unit is kJ/kWh; Psb: When the gas turbine unit is on standby to generate electricity on its own, it supplies power to the factory and outputs outside the factory. Power (the upper limit of the output power outside the factory is set by the owner), the variable is registered by the first manufacturer and the second manufacturer, and the unit is MW; PfL: full-load power generation of the gas turbine unit at the design point, a variable registered by the first manufacturer and the second manufacturer, in MW; the third calculation function is Ha=8760*Cf/100, where Ha: annual average of the gas turbine unit Full load operating hours, unit is hour; Cf: Annual full load ratio of gas turbine unit, variable set by an owner, unit is %; The fourth calculation function is HRsu=Fc/Eg*1000, where HRsu: gas turbine unit startup period The average heat rate, in kJ/kWh; Fc: the energy consumption of each start of the gas turbine unit, variables registered by the first manufacturer and the second manufacturer, in MJ; Eg: the energy consumption of each start of the gas turbine unit The degree of power generation is registered as a variable by the first manufacturer and the second manufacturer, and the unit is kWh; the fifth calculation function includes HRo1=(HRf* Ha*f1+HRsu*Ns*Ts/60+HRsbev)/(Ns* Ts/60+Ha+Hsb*Psb/PfL) and HRo2=(HRf*Ha*f1+HRsu*Ns*Ts/60+HRsbev)/(Ns*Ts/60+Ha+Hsb*Psb/PfL), where HRo1 and HRo2: the calculated values of the guaranteed overall heat rate of the first manufacturer and the second manufacturer, in kJ/kWh; HRf: the heat rate of the gas turbine unit at full load, calculated between the first manufacturer and the second manufacturer. 2. Manufacturer registration variables, unit is kJ/kWh; Ha: average annual full-load operating hours of the gas turbine unit, which is imported by the third calculation function, unit is hour; f1: heat rate correction of the gas turbine unit at full load Parameter, f1=(PfL*Ha)/(PfL*Ha-Psbc*Hsb); PfL: The full-load power generation power of the gas turbine unit at the design point, a variable registered by the first manufacturer and the second manufacturer, in MW; Psbc: The external input power of the gas turbine unit during standby, determined by the first manufacturer and the second manufacturer Manufacturer registration variable, unit is MW; Hsb: average annual standby operation hours of the gas turbine unit, imported by the first calculation function, unit is hour; HRsu: average heat rate during startup of the gas turbine unit, which is calculated by the The fourth calculation function is imported, kJ/kWh; Ns: the average number of starts of the gas turbine unit per year, a variable set by the owner, the unit is times/year; Ts: the time from the ignition of the gas turbine unit to the full load of the gas turbine unit, determined by the first The manufacturer and the second manufacturer register variables, the unit is points; HRsbev: the standby heat rate rating value of the gas turbine unit, imported from the second calculation function, the unit is kJ/kWh; Psb: the gas turbine unit supplies the factory when it is on standby to generate electricity by itself. Internal and external power output, the upper limit of the output external power is set by the owner, and the first manufacturer and the second manufacturer register variables in MW; the sixth calculation function is HRv=(HRo1-HRo2)*Ev , where HRv: the calculated value of the difference in evaluation value of the overall heat rate of the first manufacturer and the second manufacturer, in Taiwan dollars; HRo1: the calculated value of the guaranteed value of the first manufacturer's overall heat rate, which is calculated by the The fifth calculation function is imported, the unit is kJ/kWh; HRo2: the calculated value of the first manufacturer's overall heat rate guarantee value, which is imported from the fifth calculation function, the unit is kJ/kWh; Ev: It is the value of a unit heat rate, a variable set by the owner, and the unit is Taiwan dollars/kJ/kWh; the evaluation is based on the efficiency evaluation value HRv established by a public institution or a consulting company in the bid invitation specifications. Determine whether the first manufacturer or the second manufacturer wins the bid. The rating and verification system for a gas turbine unit as claimed in claim 1, wherein the verification algorithm includes a first verification calculation function, a second verification calculation function, a third verification calculation function and a fourth verification calculation function, the The first verification calculation function is HRsbeva=HRsba*Hsb*(Psba/PfLa), where HRsbeva: the measured heat rate verification value of the gas turbine unit in standby, in kJ/kWh; HRsba: the measured heat rate verification value of the gas turbine unit in standby supplied to the factory and The heat rate of power output outside the factory is the measured variable of the gas turbine unit of the first manufacturer or the second manufacturer that won the bid, and the unit is kJ/kWh; Psba: the actual measured variable of the gas turbine unit when it is on standby to generate electricity on its own and supplied to the factory and the output factory External power power, the upper limit of the output off-site power is set by the owner, and is the measured variable of the gas turbine unit of the first manufacturer or the second manufacturer that won the bid, in MW; PfLa: the measured full-load power generation power of the gas turbine unit design point, is The measured variables of the gas turbine unit of the first manufacturer or the second manufacturer that won the bid, in MW; the second verification calculation function is HRsua=Fca/Ega*1000, where HRsua: the measured average heat consumption of the gas turbine unit during startup Rate, unit is kJ/kWh; Fca: measured startup energy consumption of the gas turbine unit, which is the measured variable of the gas turbine unit of the first or second manufacturer that won the bid, unit is MJ; Ega: measured startup power generation of the gas turbine unit , are the measured variables of the gas turbine unit of the first manufacturer or the second manufacturer that won the bid, in kWh; The third verification calculation function is HRoA=(HRfa*Ha*f2+HRsua*Ns*Tsa/60+HRsbeva)/(Ns*Tsa/60+Ha+Hsb*Psbca/PfLa), where HRoA: measured overall heat consumption Guaranteed rate value, unit is kJ/kWh; HRfa: the measured heat rate of the gas turbine unit at full load; measured variable, unit is kJ/kWh; Ha: annual average full-load operating hours of the gas turbine unit, calculated by the third calculation function Import, hour; f2: The measured heat rate correction parameter of the gas turbine unit at full load, the calculation formula is as follows: f2=(PfLa*Ha)/(PfLa*Ha-Psbca*Hsb)PfLa: The measured full-load power generation of the gas turbine unit Power is the measured variable of the gas turbine unit of the first manufacturer or the second manufacturer that won the bid, and the unit is MW; Psbca: the measured external power input of the gas turbine unit during standby, which is the first manufacturer or the second manufacturer that won the bid. The manufacturer's measured variables of the gas turbine unit, in MW; Hsb: the annual average standby operation hours of the gas turbine unit, imported from the first calculation function, in hours; HRsua: the measured average heat rate during the start-up period of the gas turbine unit, Imported by the second verification calculation function, the unit is kJ/kWh; Ns: the average number of starts of the gas turbine unit per year, a variable set by the owner, the unit is times/year; Tsa: the actual measurement from the ignition of the gas turbine unit to the full load of the gas turbine unit Time; measured variable, unit is minute; the fourth verification calculation function is HRp=(HRo1 or HRo2-HRoA)*Pv, where HRp: is the first manufacturer that won the bid or the second manufacturer did not reach the overall heat rate guarantee value The penalty calculation value, the unit is Taiwan dollars; HRo1 or HRo2: The overall heat rate guarantee value of the first manufacturer or the second manufacturer that wins the bid is imported from the fifth calculation function, the unit is kJ/kWh; HRoA: The measured overall heat rate imported from the third verification calculation function, the unit is kJ/kWh; Pv: The unit heat rate setting penalty value; set by the owner, the unit is NT$/kJ/kWh. A built-in program for evaluation and verification of gas turbine units. After the computer executes the program, a evaluation algorithm and a verification algorithm are implemented. The evaluation algorithm includes a first calculation function, a second calculation function, and a third calculation function, a fourth calculation function, a fifth calculation function and a sixth calculation function. The first calculation function is Hsb=8760*Cfsb/100, where Hsb: the annual average standby operation hours of the gas turbine unit, in hours ; Cfsb: the annual standby ratio of the gas turbine unit, a variable set by an owner, the unit is %; the second calculation function is HRsbev=HRsb*Hsb*(Psb/PfL), where HRsbev: the standby heat rate evaluation value of the gas turbine unit , the unit is kJ/kWh; HRsb: the heat rate of the gas turbine unit supplying power to the factory and outputting power outside the factory when it is in standby mode, a variable registered by a first manufacturer and a second manufacturer, the unit is kJ/kWh; Psb: gas turbine When the unit is on standby and generates electricity by itself, it supplies internal and external power to the factory (the upper limit of the output external power is set by the owner). The first manufacturer and the second manufacturer register variables in MW; PfL: gas turbine unit design point full load The generated power is a variable registered by the first manufacturer and the second manufacturer, in MW; the third calculation function is Ha=8760*Cf/100, where Ha: the annual average full-load operating hours of the gas turbine unit, in hours ;Cf: The annual full load ratio of the gas turbine unit, a variable set by an owner, the unit is %; The fourth calculation function is HRsu=Fc/Eg*1000, where HRsu: The average heat rate during the startup period of the gas turbine unit, the unit is kJ/kWh; Fc: The energy consumption of each start-up of the gas turbine unit, provided as a registered variable by a first manufacturer and a second manufacturer, in MJ; Eg: The power generation rate of each start-up of the gas turbine unit, determined by the first manufacturer and the second manufacturer Manufacturer registration variable, unit is kWh; the fifth calculation function includes HRo1=(HRf * Ha*f1+HRsu*Ns*Ts/60+HRsbev)/(Ns*Ts/60+Ha+Hsb*Psb/PfL) and HRo2=(HRf*Ha*f1+HRsu*Ns*Ts/60+HRsbev)/(Ns*Ts/60+Ha+Hsb*Psb/PfL), where HRo1 and HRo2: the first manufacturer and the second manufacturer The calculated value of the manufacturer's guaranteed overall heat rate, in kJ/kWh; HRf: the heat rate of the gas turbine unit at full load, variables registered by the first manufacturer and the second manufacturer, in kJ/kWh; Ha : The annual average full-load operating hours of the gas turbine unit, which is imported from the third calculation function, in hours; f1: The heat rate correction parameter of the gas turbine unit at full load, f1=(PfL*Ha)/(PfL *Ha-Psbc*Hsb); PfL: The full-load power generation power of the gas turbine unit at the design point, a variable registered by the first manufacturer and the second manufacturer, in MW; Psbc: The external input power of the gas turbine unit during standby, expressed by The first manufacturer and the second manufacturer registered variables, the unit is MW; Hsb: the annual average standby operation hours of the gas turbine unit, imported by the first calculation function, the unit is hours; HRsu: the average heat rate during the startup period of the gas turbine unit, which is imported from the fourth calculation function, and the unit is kJ/kWh; Ns: the average number of startups of the gas turbine unit per year, a variable set by the owner, times/year; Ts: the time from the ignition of the gas turbine unit to the full load of the gas turbine unit, variables registered by the first manufacturer and the second manufacturer, in minutes; HRsbev: the standby heat rate rating value of the gas turbine unit, imported by the second calculation function, The unit is kJ/kWh; Psb: When the gas turbine unit is on standby and generates electricity by itself, it supplies power to the factory and outputs power outside the factory. The upper limit of the power output outside the factory is set by the owner, and the first manufacturer and the second manufacturer register the variables. The unit is MW; the sixth calculation function is HRv=(HRo1-HRo2)*Ev, where HRv: the calculated value difference of the overall heat rate of the first manufacturer and the second manufacturer, in Taiwan dollars; HRo1: the calculated value of the first manufacturer and the second manufacturer. The calculated value of the guaranteed overall heat rate value of a manufacturer is imported from the fifth calculation function, and the unit is kJ/kWh; HRo2: the calculated value of the guaranteed overall heat rate value of the first manufacturer, which is calculated by The fifth calculation function is imported, the unit is kJ/kWh; Ev: it is the value of a unit heat rate, a variable set by the owner, the unit is NT$/kJ/kWh; the evaluation is based on a public institution or a consulting company The efficiency rating value HRv set in the bid invitation specifications is used to determine whether the first manufacturer or the second manufacturer wins the bid; the verification algorithm includes a first verification calculation function, a second verification calculation function, and a third verification Calculation function and a fourth verification calculation function. The first verification calculation function is HRsbeva=HRsba*Hsb*(Psba/PfLa), where HRsbeva: Verification value of the gas turbine unit's measured heat rate in standby, in kJ/kWh; HRsba: The measured heat rate of the gas turbine unit's power supply in the factory and output outside the factory when it is in standby, for the first manufacturer or the third company that wins the bid. The actual measured variables of the gas turbine units of the two manufacturers, the unit is kJ/kWh; Psba: the actual measured electric power supplied to the factory and output outside the factory when the gas turbine unit is on standby to generate electricity by itself. The upper limit of the output power outside the factory is set by the owner, which is the first one that wins the bid. The measured variables of the gas turbine unit of the manufacturer or the second manufacturer, in MW; PfLa: the measured full-load power generation power of the gas turbine unit design point, which is the measured variable of the gas turbine unit of the first manufacturer or the second manufacturer that won the bid, in units of MW; the second verification calculation function is HRsua=Fca/Ega*1000, where HRsua: the measured average heat rate during the startup of the gas turbine unit, in kJ/kWh; Fca: the measured startup energy consumption of the gas turbine unit, is obtained The measured variables of the gas turbine unit of the first manufacturer or the second manufacturer of the subject, in MJ; Ega: the measured startup power generation degree of the gas turbine unit, which is the measured variable of the gas turbine unit of the first manufacturer or the second manufacturer that won the bid, The unit is kWh; the third verification calculation function is HRoA=(HRfa*Ha*f2+HRsua*Ns*Tsa/60+HRsbeva)/(Ns*Tsa/60+Ha+Hsb*Psbca/PfLa), where HRoA: The guaranteed value of the overall measured heat rate, in kJ/kWh; HRfa: the measured heat rate of the gas turbine unit at full load; the measured variable, in kJ/kWh; Ha: the annual average full-load operating hours of the gas turbine unit, calculated by The third calculation function is imported, the unit is hours; f2: The measured heat rate correction parameter of the gas turbine unit at full load, f2=(PfLa*Ha)/(PfLa*Ha-Psbca*Hsb); PfLa: The measured full-load power generation power of the gas turbine unit, which is the first manufacturer to win the bid Or the measured variable of the gas turbine unit of the second manufacturer, the unit is MW; Psbca: the measured external power input of the gas turbine unit during standby, which is the measured variable of the gas turbine unit of the first manufacturer or the second manufacturer that won the bid, unit is MW; Hsb: the annual average standby operation hours of the gas turbine unit, imported from the first calculation function, in hours; HRsua: the measured average heat rate during the startup period of the gas turbine unit, imported from the second verification calculation function , the unit is kJ/kWh; Ns: the average number of starts of the gas turbine unit per year, the variable is set by the owner, the unit is times/year; Tsa: the measured time from the ignition of the gas turbine unit to the full load of the gas turbine unit; the measured variable, the unit is minutes; The fourth verification calculation function is HRp=(HRo1 or HRo2-HRoA)*Pv, where HRp: is the calculated penalty value of the first manufacturer or the second manufacturer that wins the bid for failing to meet the guaranteed value of the overall heat rate, in Taiwan dollars; HRo1 or HRo2: The guaranteed value of the overall heat rate of the first or second manufacturer that won the bid imported from the fifth calculation function, in kJ/kWh; HRoA: the measured overall value imported from the third verification calculation function Heat rate, unit is kJ/kWh; Pv: unit heat rate setting penalty value; set by the owner, unit is NT$/kJ/kWh. A device for evaluation and verification of gas turbine units, which includes: a memory that stores a plurality of parameters, each of which includes: Hsb: the annual average standby operation hours of the gas turbine unit, in hours; Cfsb: the annual average standby operation hours of the gas turbine unit; The standby ratio is a variable set by an owner, and the unit is %; HRsbev: The standby heat rate evaluation value of the gas turbine unit, in kJ/kWh; HRsb: The heat rate of the gas turbine unit supplying in-factory and outputting external power when in standby, variables registered by a first manufacturer and a second manufacturer , the unit is kJ/kWh; Psb: when the gas turbine unit is on standby and generates electricity on its own, it supplies power to the factory and outputs power outside the factory (the upper limit of the power output outside the factory is set by the owner), and the variables are registered by the first manufacturer and the second manufacturer, The unit is MW; PfL: The full-load power generation power of the gas turbine unit at the design point, a variable registered by the first manufacturer and the second manufacturer, the unit is MW; Ha: The annual average full-load operating hours of the gas turbine unit, the unit is hours; Cf: The annual full load ratio of the gas turbine unit is a variable set by the owner, in %; HRsu: the average heat rate during the startup of the gas turbine unit, in kJ/kWh; Fc: the energy consumption of each startup of the gas turbine unit, determined by the The first manufacturer and the second manufacturer register variables, the unit is MJ; Eg: the power generation degree of the gas turbine unit each time it is started, the first manufacturer and the second manufacturer register variables, the unit is kWh; HRo1 and HRo2: The first manufacturer The calculated value of the overall heat rate guarantee value of the first manufacturer and the second manufacturer, in kJ/kWh; HRf: the heat rate of the gas turbine unit at full load, variables registered by the first manufacturer and the second manufacturer, in unit is kJ/kWh; Ha: the annual average full-load operating hours of the gas turbine unit, which is imported by the third calculation function, in hours; HRsu: the average heat rate during the startup period of the gas turbine unit, which is imported by the third calculation function. Four calculation functions are imported, the unit is kJ/kWh; Ns: the average number of starts of the gas turbine unit per year, a variable set by the owner, in units of times/year; Ts: the time from ignition of the gas turbine unit to full load of the gas turbine unit, variables registered by the first manufacturer and the second manufacturer, in units of points; HRv: the calculated value of the difference in evaluation value of the overall heat rate of the first manufacturer and the second manufacturer, in Taiwan dollars; HRo1: the calculated value of the guaranteed value of the first manufacturer's overall heat rate, which is calculated by the The fifth calculation function is imported, the unit is kJ/kWh; HRo2: the calculated value of the first manufacturer's overall heat rate guarantee value, which is imported by the fifth calculation function, the unit is kJ/kWh; Ev: its calculated value It consists of a unit heat rate value, a variable set by the owner, and the unit is NT$/kJ/kWh; a display; and a computing module connected to the display, and the computing module stores the data stored in the memory. The complex parameters are used to calculate the gas turbine unit of the qualified bidder according to the set evaluation algorithm and verification algorithm, and display it on the display. The evaluation algorithm includes a first calculation function and a second calculation function. , a third calculation function, a fourth calculation function, a fifth calculation function and a sixth calculation function, the first calculation function is Hsb=8760*Cfsb/100; the second calculation function is HRsbev=HRsb*Hsb *(Psb/PfL); the third calculation function is Ha=8760*Cf/100; the fourth calculation function is HRsu=Fc/Eg*1000; the fifth calculation function includes HRo1=(HRf*Ha*f1 +HRsu*Ns*Ts/60+HRsbev)/(Ns*Ts/60+Ha+Hsb*Psb/PfL) and HRo2=(HRf*Ha*f1+HRsu*Ns*Ts/60+HRsbev))/( Ns*Ts/60+Ha+Hsb*Psb/PfL); The sixth calculation function is HRv=(HRo1-HRo2)*Ev; during the evaluation, the first manufacturer or the second manufacturer is judged based on the efficiency evaluation value HRv established by a public institution or a consulting company in the bid invitation specifications. The bid is won and displayed on the display; the verification algorithm includes a second verification calculation function, a third verification calculation function and a fourth verification calculation function. The first verification calculation function is HRsbeva=HRsba*Hsb*(Psba /PfLa), where HRsbeva: the measured heat rate verification value of the gas turbine unit in standby, in kJ/kWh; HRsba: the measured heat rate of the gas turbine unit in standby for supplying in-plant and outputting power outside the plant, which is the winning bidder. The actual measured variables of the gas turbine unit of the first manufacturer or the second manufacturer, in kJ/kWh; Psba: the actual measured electric power supplied to the factory and output to the outside of the factory when the gas turbine unit is on standby to generate electricity on its own. The upper limit of the output of external power is set by the owner. It is the measured variable of the gas turbine unit of the first manufacturer or the second manufacturer that won the bid, in MW; PfLa: the measured full-load power generation power of the gas turbine unit design point, which is the gas turbine of the first manufacturer or the second manufacturer that won the bid. A set of measured variables, in MW; the second verification calculation function is HRsua=Fca/Ega*1000, where HRsua: the measured average heat rate during the startup of the gas turbine unit, in kJ/kWh; Fca: the measured average heat rate of the gas turbine unit Start-up energy consumption is the measured variable of the gas turbine unit of the first or second manufacturer that won the bid, in MJ; Ega: the measured start-up power generation of the gas turbine unit, which is the measured variable of the first or second manufacturer that won the bid. Measured variables of the gas turbine unit, in kWh; The third verification calculation function is HRoA=(HRfa*Ha*f2+HRsua*Ns*Tsa/60+HRsbeva)/(Ns*Tsa/60+Ha+Hsb*Psbca/PfLa), where HRoA: measured overall heat consumption Guaranteed rate value, unit is kJ/kWh; HRfa: the measured heat rate of the gas turbine unit at full load; measured variable, unit is kJ/kWh; Ha: annual average full-load operating hours of the gas turbine unit, calculated by the third calculation function Import, unit is hour; f2: the measured heat rate correction parameter of the gas turbine unit at full load, f2=(PfLa*Ha)/(PfLa*Ha-Psbca*Hsb); PfLa: the measured full-load power generation power of the gas turbine unit, It is the measured variable of the gas turbine unit of the first manufacturer or the second manufacturer that won the bid, in MW; Psbca: the measured external power input of the gas turbine unit during standby, which is the variable of the first manufacturer or the second manufacturer that won the bid. The measured variables of the gas turbine unit, in MW; Hsb: the annual average standby operation hours of the gas turbine unit, imported by the first calculation function, in hours; HRsua: the measured average heat rate during the startup period of the gas turbine unit, calculated by the The second verification calculation function is imported, the unit is kJ/kWh; Ns: the average number of starts of the gas turbine unit per year, a variable set by the owner, the unit is times/year; Tsa: the measured time from the ignition of the gas turbine unit to the full load of the gas turbine unit; Actual measured variables, the unit is points; the fourth verification calculation function is HRp=(HRo1 or HRo2-HRoA)*Pv, where HRp: is the penalty for the first manufacturer or the second manufacturer that wins the bid for not reaching the guaranteed value of the overall heat rate Calculated value, unit is Taiwan dollar; HRo1 or HRo2: The guaranteed value of the overall heat rate of the first or second manufacturer that won the bid imported from the fifth calculation function, in kJ/kWh; HRoA: the measured overall value imported from the third verification calculation function Heat rate, unit is kJ/kWh; Pv: unit heat rate setting penalty value; set by the owner, unit is NT$/kJ/kWh.

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