CN112257371A - Power grid transmission line analysis system - Google Patents

Abstract

The invention discloses a power grid transmission line analysis system, and relates to the technical field of power system simulation; the system comprises a computer, a controller, a signal source, a rack model based on the reduced power transmission line of a power grid and a measuring instrument for measuring voltage and current, wherein the computer is electrically connected with and communicates with the controller; the method realizes the good working reality and high efficiency of analyzing the power transmission line of the power grid through a computer, a controller, a signal source, a rack model, a measuring instrument and the like.

Description

Power grid transmission line analysis system

Technical Field

The invention relates to the technical field of power system simulation, in particular to a power grid transmission line analysis system.

Background

The system or equipment simulation technology of the power grid mainly comprises three types of RTDS, an alternating current and direct current electromagnetic transient simulation platform, a power grid system moving model and the like at present. The following are described respectively:

the RTDS is called a Real Time Digital Simulator (Real Time Digital Simulator), developed and manufactured by toniba RTDS, canada, and is a device specially designed for studying electromagnetic transient phenomena in power systems. The RTDS has been widely used in power enterprises and research institutions in 28 countries (regions), and the installed number exceeds 140. The grid model, generator, load and controller model of the RTDS are all digital and are simulated by software. The system has current and voltage quantities simulated by software, and the current and voltage quantities are converted into actual current and voltage quantities through digital-to-analog conversion. The current and voltage values of the outputs can be used for driving protection, automatic devices and the like, and are used for testing the reliability of the protection and automatic devices and the reasonability of algorithms.

The RTDS model is simulated by a digital software, only the output end adopts a digital-to-analog conversion technology to output real current and voltage quantities, and the RTDS works at 50 Hz.

The AC/DC electromagnetic transient simulation platform is a digital-analog hybrid simulation and digital hybrid simulation system independently developed by China electric academy, has the simulation capability and technology at the most advanced international level, and is applied to China electric academy and each provincial electric academy. The platform integrates the functions of power grid load flow calculation, steady-state analysis, electromagnetic transient analysis, analog-digital-analog conversion and hardware output current and voltage. The simulation range can cover the whole ultra-large power grid of China, and the simulation time scale is from the steady-state phenomenon of the small level to the electromagnetic transient phenomenon of the microsecond level. The method is mainly characterized in that the method not only has the same real current and voltage output through digital-to-analog conversion as RTDS, but also has effective fusion and connection of various digital-to-analog means, and the simulation scale is greatly expanded on time scale and space scale.

The alternating current and direct current electromagnetic transient simulation platform is basically the same as the RTDS, a model of the alternating current and direct current electromagnetic transient simulation platform is also simulated by a digital software, real current and voltage quantities are output only by adopting a digital-to-analog conversion technology at an output end, the working frequency of a simulation object of the alternating current and direct current electromagnetic transient simulation platform is 50Hz, the alternating current and direct current electromagnetic transient simulation platform needs to obtain the simulation of millisecond time scale which is subdivided from hour time scale in the whole China power grid range, and the investment scale is huge.

The power grid system dynamic model is a classic system for power grid simulation. In the 60's and 70's, where digital computers were not very popular, they were important devices for studying power systems. At that time, equipment was available in the electric power system specialties of the Chinese academy of electric sciences and all universities and colleges. The general simulation scale is two to four generators and corresponding loads, and the electromagnetic and mechanical dynamic research service of the power system is provided. The power system physical simulation model is established according to the similarity principle, each part of the actual power system is designed and built according to the similar conditions to form a relatively small-scale power system, and the model is used for replacing the actual power system to carry out experimental research on various normal and fault states. At present, modern information and electronic technology are introduced into a dynamic simulation system, distributed digital network measurement can be realized, and the dynamic simulation system can be closely combined with systems such as RTDS and the like to complement each other.

The power transmission line is regarded as an integral component by the power grid system moving die, and the power grid system moving die works at 50Hz, so that the influence of parameters such as the internal size and the layout of the power transmission line on the electrical property of the power transmission line cannot be researched.

Problems with the prior art and considerations:

how to solve the relatively poor and lower technical problem of efficiency of authenticity in the analysis electric wire netting transmission line work.

Disclosure of Invention

The invention aims to solve the technical problem of providing a power grid transmission line analysis system which realizes good working reality and high efficiency of analyzing the power grid transmission line through a computer, a controller, a signal source, a rack model, a measuring instrument and the like.

In order to solve the technical problems, the technical scheme adopted by the invention is as follows: the utility model provides a power grid transmission line analytic system includes computer, controller, signal source, based on rack model and the measuring instrument that is used for measuring voltage and electric current after power grid transmission line dwindles, the computer is connected and communicates with the controller electricity, the controller is connected and communicates with the signal source electricity, the output of signal source is connected with measuring instrument's input electricity, measuring instrument's output is connected with rack model's input electricity and obtains rack model's voltage and electric current.

The further technical scheme is as follows: the signal source comprises a signal generator and an amplifying circuit used for forming the signal source, the amplifying circuit used for forming the signal source comprises a voltage amplifier and a current amplifier used for forming the signal source, and the signal generator, the voltage amplifier and the current amplifier used for forming the signal source are sequentially connected; the signal source is a signal source with the frequency range of 0.5 MHz-50 MHz.

The further technical scheme is as follows: the signal source is a three-phase signal source; the signal generator comprises a signal generator, a signal source, a first amplifying circuit, a second amplifying circuit, a third amplifying circuit, a fourth amplifying circuit and a fourth amplifying circuit, wherein the number of the amplifying circuits for forming the signal source is three, the first amplifying circuits to the third amplifying circuits are respectively the same in structure and are used for forming the signal source, and a first output; the voltage of the rack model is three-phase voltage, and the current of the rack model is three-phase current.

The further technical scheme is as follows: the voltage amplifier used for forming the signal source is a differential operational amplifier, and the current amplifier used for forming the signal source is a current buffer; the signal source is a signal source with the frequency of 5 MHz.

The further technical scheme is as follows: the measuring instrument comprises a first measuring unit and a second measuring unit, the first measuring unit is used for measuring current and voltage, the second measuring unit is used for measuring active power and reactive power, an output port of the signal source is connected with an input port of the first measuring unit, a first output port of the first measuring unit is connected with an input port of the bench model, and a second output port of the first measuring unit is connected with an input port of the second measuring unit.

The further technical scheme is as follows: the first measuring unit is a current and voltage measuring unit which comprises a first voltage amplifier, a second voltage amplifier and a current sampling resistor, wherein the first voltage amplifier is used for measuring current and voltage; the second measurement unit is used for measuring an active and reactive measurement unit, and the active and reactive measurement unit comprises an amplifier for measuring active, first to fourth resistors and a multiplier, an amplifier for measuring reactive, first to third resistors, a capacitor and a multiplier; the output end of the signal source is connected with the positive phase input end of a first voltage amplifier for measuring current and voltage, the negative phase input end of the first voltage amplifier for measuring current and voltage is connected with the positive phase input end of a second voltage amplifier for measuring current and voltage, the negative phase input end of the second voltage amplifier for measuring current and voltage is grounded, a current sampling resistor for measuring current and voltage is connected between the positive phase input end and the negative phase input end of the first voltage amplifier for measuring current and voltage, and the connection part of the negative phase input end of the first voltage amplifier for measuring current and voltage and the positive phase input end of the second voltage amplifier for measuring current and voltage is connected with the first input end of the rack model; the positive phase input end of the amplifier for measuring the work is connected to the output end of the second voltage amplifier for measuring the current and the voltage through a third resistor for measuring the work, the positive phase input end of the amplifier for measuring the work is connected to the ground through a fourth resistor for measuring the work, the negative phase input end of the amplifier for measuring the work is connected to the ground through a first resistor for measuring the work, a second resistor for measuring the work is connected between the negative phase input end and the output end of the amplifier for measuring the work, the output end of the first voltage amplifier for measuring the current and the voltage is connected with the first input end of the multiplier for measuring the work, and the output end of the amplifier for measuring the work is connected with the second input end of the multiplier for measuring the work; the positive phase input end of the amplifier for measuring the reactive power is connected to the output end of the second voltage amplifier for measuring the current voltage through a third resistor for measuring the reactive power, the positive phase input end of the amplifier for measuring the reactive power is connected to the ground through a capacitor for measuring the reactive power, the negative phase input end of the amplifier for measuring the reactive power is connected to the ground through a first resistor for measuring the reactive power, a second resistor for measuring the reactive power is connected between the negative phase input end and the output end of the amplifier for measuring the reactive power, the output end of the first voltage amplifier for measuring the current voltage is connected with the first input end of the multiplier for measuring the reactive power, and the output end of the amplifier for measuring the reactive power is connected with the second input end of the multiplier for measuring the reactive power.

The further technical scheme is as follows: the active and reactive power measurement unit comprises six active and reactive power measurement units with the same structure, namely a first line A-C phase current and voltage measurement unit and a second line A-C phase current and voltage measurement unit respectively; the first voltage amplifier and the second voltage amplifier for measuring the current and the voltage are both differential operational amplifiers, and the current sampling resistor for measuring the current and the voltage is a resistor with the resistance value range of 1 ohm to 20 ohms; the amplifier for measuring active and the amplifier for measuring inactive are operational amplifiers, the multiplier for measuring active and the multiplier for measuring inactive are analog multipliers, the first resistor for measuring active is a resistor with a resistance value ranging from 0.5 kilo-ohm to 10 kilo-ohm, the second resistor for measuring active is a resistor with a resistance value ranging from 0.5 kilo-ohm to 10 kilo-ohm, the third resistor for measuring active is a resistor with a resistance value ranging from 1 kilo-ohm to 50 kilo-ohm, the fourth resistor for measuring active is a resistor with a resistance value ranging from 0.1 kilo-ohm to 5 kilo-ohm, the first resistor for measuring inactive is a resistor with a resistance value ranging from 0.5 kilo-ohm to 10 kilo-ohm, the second resistor for measuring inactive is a resistor with a resistance value ranging from 0.5 kilo-ohm to 10 kilo-ohm, and the third resistor for measuring inactive is a resistor with a resistance value ranging from 1 kilo-ohm to 50 kilo-ohm, the capacitance used for measuring the reactive power is a capacitance having a capacitance value in the range of 20 picofarads to 200 picofarads.

The further technical scheme is as follows: the current sampling resistor for measuring current and voltage is a resistor with the resistance value of 5 ohms, the first resistor for measuring active is a resistor with the resistance value of 1 kiloohm, the second resistor for measuring active is a resistor with the resistance value of 1 kiloohm, the third resistor for measuring active is a resistor with the resistance value of 9 kiloohm, the fourth resistor for measuring active is a resistor with the resistance value of 1 kiloohm, the first resistor for measuring reactive is a resistor with the resistance value of 1 kiloohm, the second resistor for measuring reactive is a resistor with the resistance value of 1 kiloohm, the third resistor for measuring reactive is a resistor with the resistance value of 3 kiloohm, and the capacitor for measuring reactive is a capacitor with the capacitance value of 100 picofarads.

The further technical scheme is as follows: the rack model comprises a rack and two groups of three-phase transmission lines arranged on the rack, the six phase lines of the two groups of three-phase transmission lines including the rack model are respectively a first line A-C phase line and a second line A-C phase line of the rack model, and the output end of the measuring instrument is connected with the input ends of the two groups of three-phase transmission lines arranged on the rack.

The further technical scheme is as follows: the measuring instrument is connected with the information conversion device and is communicated with the information conversion device; the controller is a single chip microcomputer; the information conversion device is a low-pass filter, the measuring instrument is connected with the controller through the low-pass filter and is in one-way communication, or the information conversion device is an oscilloscope, and the measuring instrument is connected with the oscilloscope and is in one-way communication.

Adopt the produced beneficial effect of above-mentioned technical scheme to lie in:

the utility model provides a power grid transmission line analytic system includes computer, controller, signal source, based on rack model and the measuring instrument that is used for measuring voltage and electric current after power grid transmission line dwindles, the computer is connected and communicates with the controller electricity, the controller is connected and communicates with the signal source electricity, the output of signal source is connected with measuring instrument's input electricity, measuring instrument's output is connected with rack model's input electricity and obtains rack model's voltage and electric current. The method realizes the good working reality and high efficiency of analyzing the power transmission line of the power grid through a computer, a controller, a signal source, a rack model, a measuring instrument and the like.

See detailed description of the preferred embodiments.

Drawings

FIG. 1 is a schematic block diagram ofembodiment 1 of the present invention;

FIG. 2 is a functional block diagram of a signal source, a meter and a gantry model of the present invention;

FIG. 3 is a circuit schematic of a signal source in the present invention;

FIG. 4 is a schematic circuit diagram of a first line A-phase current voltage measuring unit in accordance with the present invention;

FIG. 5 is a schematic circuit diagram of a first line phase B current voltage measuring unit in accordance with the present invention;

FIG. 6 is a schematic circuit diagram of a first line C-phase current voltage measuring unit according to the present invention;

FIG. 7 is a schematic circuit diagram of a second line A-phase current voltage measuring unit according to the present invention;

FIG. 8 is a schematic circuit diagram of a second line phase B current voltage measuring unit according to the present invention;

FIG. 9 is a schematic circuit diagram of a second line C-phase current voltage measuring unit according to the present invention;

fig. 10 is a schematic circuit diagram of a first line a phase active reactive power measurement unit in the present invention;

FIG. 11 is a schematic circuit diagram of a gantry model of the present invention;

fig. 12 is a schematic block diagram ofembodiment 2 of the present invention.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are only a part of the embodiments of the present application, and not all of the embodiments. The following description of at least one exemplary embodiment is merely illustrative in nature and is in no way intended to limit the application, its application, or uses. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present application, but the present application may be practiced in other ways than those described herein, and it will be apparent to those of ordinary skill in the art that the present application is not limited to the specific embodiments disclosed below.

Example 1:

as shown in fig. 1 to 11, the invention discloses a power grid transmission line analysis system, which comprises a computer, a controller, a signal source, a rack model based on the power grid transmission line after being reduced, a measuring instrument and a low-pass filter for measuring voltage and current, wherein the computer is electrically connected with the controller and is in two-way communication, the controller is electrically connected with the signal source and is in two-way communication, an output port of the signal source is electrically connected with an input port of the measuring instrument, a first output port of the measuring instrument is electrically connected with an input port of the rack model, a second output port of the measuring instrument is electrically connected with a first input port of the low-pass filter, a third output port of the measuring instrument is electrically connected with a second input port of the low-pass filter, an output end of the low-pass filter is connected with an input port of, Current, active and reactive, as detailed below.

A signal source:

as shown in FIG. 3, the signal source comprises a signal generator U1-1, first to fourth voltage amplifiers U2-1 to U5-1 for forming the signal source, first to fourth current amplifiers U6-1 to U9-1 and first to fourth output terminals A _ OUT-1 to C _ OUT-1 and O _ OUT-1, wherein the first to fourth voltage amplifiers U2-1 to U5-1 and the first to fourth current amplifiers U6-1 to U9-1 for forming the signal source form four amplifying circuits with the same structure for forming the signal source.

The first output terminal D0_ OUT of the signal generator U1-1 is connected to the non-inverting input terminal of a first voltage amplifier U2-1 forming a signal source, the inverting input terminal of the first voltage amplifier U2-1 forming the signal source is connected to ground GND, the output of the first voltage amplifier U2-1 forming the signal source is connected to the input of the first current amplifier U6-1 forming the signal source, the output of the first current amplifier U6-1 forming the signal source is connected to a first output terminal a _ OUT-1 forming the signal source, the first output terminal A _ OUT-1 for forming a signal source is an A-phase output, and the first voltage amplifier U2-1 and the first current amplifier U6-1 for forming the signal source form a first amplifying circuit for forming the signal source.

The second output terminal D1_ OUT of the signal generator U1-1 is connected to the non-inverting input terminal of a second voltage amplifier U3-1 forming a signal source, the inverting input terminal of the second voltage amplifier U3-1 forming the signal source is connected to ground GND, the output of the second voltage amplifier U3-1 forming the signal source is connected to the input of a second current amplifier U7-1 forming the signal source, the output of the second current amplifier U7-1 forming the signal source is connected to a second output terminal B _ OUT-1 forming the signal source, the second output terminal B _ OUT-1 for forming a signal source is a B-phase output, and the second voltage amplifier U3-1 and the second current amplifier U7-1 for forming the signal source form a second amplifying circuit for forming the signal source.

The third output terminal D2_ OUT of the signal generator U1-1 is connected to the non-inverting input terminal of a third voltage amplifier U4-1 forming a signal source, the inverting input terminal of the third voltage amplifier U4-1 forming the signal source is connected to ground GND, the output of the third voltage amplifier U4-1 forming the signal source is connected to the input of a third current amplifier U8-1 forming the signal source, the output of the third current amplifier U8-1 forming the signal source is connected to a third output terminal C OUT-1 forming the signal source, the third output terminal C _ OUT-1 for forming a signal source is a C-phase output, and the third voltage amplifier U4-1 and the third current amplifier U8-1 for forming the signal source form a third amplifying circuit for forming the signal source.

The fourth output terminal D3_ OUT of the signal generator U1-1 is connected to the non-inverting input terminal of the fourth voltage amplifier U5-1 forming a signal source, the inverting input terminal of the fourth voltage amplifier U5-1 forming the signal source is connected to ground GND, the output of the fourth voltage amplifier U5-1 forming the signal source is connected to the input of a fourth current amplifier U9-1 forming the signal source, the output of the fourth current amplifier U9-1 forming the signal source is connected to a fourth output terminal O OUT-1 forming the signal source, a reference signal output at a fourth output terminal O OUT-1 forming a signal source, the fourth voltage amplifier U5-1 and the fourth current amplifier U9-1 for forming a signal source form a fourth amplifying circuit for forming a signal source.

As shown in fig. 2 and 3, the first output terminal a _ OUT-1, the second output terminal B _ OUT-1, the third output terminal C _ OUT-1 and the fourth output terminal O _ OUT-1, which form the signal source, form an output port of the signal source.

The signal generator U1-1 is a high-speed DDS chip with the model of AD9959, the first to fourth voltage amplifiers U2-1 to U5-1 for forming a signal source are all high-speed differential operational amplifiers with the model of AD8130, the first to fourth current amplifiers U6-1 to U9-1 are all high-speed buffers with the model of BUF634T, and the signal generator, the voltage amplifiers and the current amplifiers themselves and corresponding communication connection technologies are not described herein in detail for the prior art.

A measuring instrument:

as shown in fig. 1, the measuring instrument includes a first measuring unit for measuring current and voltage, which is a current and voltage measuring unit, and a second measuring unit for measuring active and reactive power, which is an active and reactive power measuring unit.

As shown in fig. 4 to 9, the current and voltage measuring unit includes six current and voltage measuring units with the same structure, namely a first line a-phase current and voltage measuring unit, a first line B-phase current and voltage measuring unit and a first line C-phase current and voltage measuring unit, the device comprises a second line A-phase current and voltage measuring unit, a second line B-phase current and voltage measuring unit and a second line C-phase current and voltage measuring unit, wherein six current and voltage measuring units with the same structure form two groups of three-phase current and voltage measuring units, the two groups of three-phase current and voltage measuring units are respectively a first line three-phase current and voltage measuring unit and a second line three-phase current and voltage measuring unit with the same structure, the first line A-C phase current and voltage measuring units form a first line three-phase current and voltage measuring unit, and the second line A-C phase current and voltage measuring units form a second line three-phase current and voltage measuring unit.

As shown IN fig. 4, the first-line a-phase current voltage measuring unit includes a first voltage amplifier U1-2 for measuring the voltage of the first-line a-phase current, a second voltage amplifier U2-2, a signal source terminal 1_ a _ IN-2, a current collection output terminal 1_ a _ i _ OUT-2, a voltage collection output terminal 1_ a _ U _ OUT-2, a driver terminal 1_ a _ OUT-2, and a current sampling resistor R1-2, the signal source terminal 1_ a _ IN-2 for measuring the voltage of the first-line a-phase current is connected to a non-inverting input terminal of the first voltage amplifier U1-2 for measuring the voltage of the first-line a-phase current, an inverting input terminal of the first voltage amplifier U1-2 for measuring the voltage of the first-line a-phase current is connected to a non-inverting input terminal of the second voltage amplifier U2-2 for measuring the voltage of the first-line a-phase current, an inverting input terminal of a second voltage amplifier U2-2 for measuring the voltage of the first line A-phase current is grounded GND, a current sampling resistor R1-2 for measuring the voltage of the first line A-phase current is connected between a non-inverting input terminal and an inverting input terminal of a first voltage amplifier U1-2 for measuring the voltage of the first line A-phase current, an excitation terminal 1_ A _ OUT-2 for measuring the voltage of the first line A-phase current is connected at a connection of an inverting input terminal of the first voltage amplifier U1-2 for measuring the voltage of the first line A-phase current and a non-inverting input terminal of a second voltage amplifier U2-2 for measuring the voltage of the first line A-phase current, a current collection output terminal 1_ A _ i _ OUT-2 for measuring the voltage of the first line A-phase current is connected with an output terminal of the first voltage amplifier U1-2 for measuring the voltage of the first line A-phase current, the voltage acquisition output terminal 1_ A _ U _ OUT-2 for measuring the first line A-phase current voltage is connected to the output of a second voltage amplifier U2-2 for measuring the first line A-phase current voltage. The current sampling resistor R1-2 for measuring the phase a current voltage of the first line is a resistor having a resistance of 5 ohms.

As shown IN FIG. 5, the first line B-phase current voltage measuring unit comprises a first voltage amplifier U3-2, a second voltage amplifier U4-2, a signal source terminal 1_ B _ IN-2, a current collection output terminal 1_ B _ i _ OUT-2, a voltage collection output terminal 1_ B _ U _ OUT-2, a drive terminal 1_ B _ OUT-2 and a current sampling resistor R2-2 for measuring the first line B-phase current voltage.

As shown IN FIG. 6, the first line C-phase current and voltage measuring unit comprises a first voltage amplifier U5-2, a second voltage amplifier U6-2, a signal source terminal 1_ C _ IN-2, a current collection output terminal 1_ C _ i _ OUT-2, a voltage collection output terminal 1_ C _ U _ OUT-2, an excitation terminal 1_ C _ OUT-2 and a current sampling resistor R3-2 for measuring the voltage of the first line C-phase current.

As shown IN fig. 7, the second line a-phase current voltage measuring unit includes a first voltage amplifier U7-2, a second voltage amplifier U8-2, a signal source terminal 2_ a _ IN-2, a current collection output terminal 2_ a _ i _ OUT-2, a voltage collection output terminal 2_ a _ U _ OUT-2, a stimulus terminal 2_ a _ OUT-2, and a current sampling resistor R4-2 for measuring the second line a-phase current voltage.

As shown IN FIG. 8, the second-line B-phase current voltage measuring unit includes a first voltage amplifier U9-2 for measuring the second-line B-phase current voltage, a second voltage amplifier U10-2, a signal source terminal 2_ B _ IN-2, a current collection output terminal 2_ B _ i _ OUT-2, a voltage collection output terminal 2_ B _ U _ OUT-2, a drive terminal 2_ B _ OUT-2, and a current sampling resistor R5-2.

As shown IN fig. 9, the second-line C-phase current voltage measuring unit includes a first voltage amplifier U11-2, a second voltage amplifier U12-2, a signal source terminal 2_ C _ IN-2, a current collection output terminal 2_ C _ i _ OUT-2, a voltage collection output terminal 2_ C _ U _ OUT-2, a drive terminal 2_ C _ OUT-2, and a current sampling resistor R6-2 for measuring the second-line C-phase current voltage.

The first voltage amplifier and the second voltage amplifier of each current-voltage measurement unit are both high-speed differential operational amplifiers, the model is AD8130, the current sampling resistors of each current-voltage measurement unit are resistors with a resistance value of 5 ohms, and the voltage amplifiers themselves and the corresponding communication connection technology are not described in detail in the prior art.

The active and reactive power measurement unit comprises six active and reactive power measurement units with the same structure, namely a first line A-phase active and reactive power measurement unit, a first line B-phase active and reactive power measurement unit, a first line C-phase active and reactive power measurement unit, a second line A-phase active and reactive power measurement unit, a second line B-phase active and reactive power measurement unit and a second line C-phase active and reactive power measurement unit, the active and reactive measurement units with the same structure form two groups of three-phase active and reactive measurement units, the two groups of three-phase active and reactive measurement units are respectively a first line three-phase active and reactive measurement unit and a second line three-phase active and reactive measurement unit with the same structure, the first line A-C phase active and reactive measurement units form a first line three-phase active and reactive measurement unit, and the second line A-C phase active and reactive measurement units form a second line three-phase active and reactive measurement unit.

As shown IN fig. 10, the first line a-phase active and reactive power measuring unit includes an amplifier U1-3 for measuring the first line a-phase active power, first to fourth resistors R1_1-3 to R1_4-3, a multiplier U3-3 and an active output terminal 1_ a _ P _ OUT-3, an amplifier U2-3 for measuring the first line a-phase reactive power, first to third resistors R2_1-3 to R2_3-3, a capacitor C2_1-3, a multiplier U4-3 and a reactive output terminal 1_ a _ Q _ OUT-3, and a voltage input terminal 1_ a _ U _ IN-3 and a current input terminal 1_ a _ i _ IN-3 for measuring the first line a-phase active and reactive power, an input terminal of the amplifier U normal phase 1-3 for measuring the first line a-phase active power being connected to a third resistor R1_3-3 for measuring the first line a-phase active and reactive power for measuring the first line a-phase A voltage input terminal 1_ a _ U _ IN-3 for measuring active and reactive power of the first line a-phase, a non-inverting input terminal of an amplifier U1-3 for measuring active power of the first line a-phase being connected to ground GND via a fourth resistor R1_4-3 for measuring active power of the first line a-phase, an inverting input terminal of an amplifier U1-3 for measuring active power of the first line a-phase being connected to ground GND via a first resistor R1_1-3 for measuring active power of the first line a-phase, a second resistor R1_2-3 for measuring active power of the first line a-phase being connected between an inverting input terminal and an output terminal of an amplifier U1-3 for measuring active power of the first line a-phase, a current input terminal 1_ a _ i _ IN-3 for measuring active and reactive power of the first line a-phase being connected to a first input terminal of a multiplier U3-3 for measuring active power of the first line a-phase, the output of the amplifier U1-3 for measuring the first line a phase activity is connected to the second input of the multiplier U3-3 for measuring the first line a phase activity and the output of the multiplier U3-3 for measuring the first line a phase activity is connected to the active output terminal 1_ a _ P _ OUT-3 for measuring the first line a phase activity.

The non-inverting input of the amplifier U2-3 for measuring reactive power of the first line A phase is connected via a third resistor R2_3-3 for measuring reactive power of the first line A phase to a voltage input terminal 1_ A _ U _ IN-3 for measuring active and reactive power of the first line A phase, the non-inverting input of the amplifier U2-3 for measuring reactive power of the first line A phase is connected via a capacitor C2_1-3 for measuring reactive power of the first line A phase to ground GND, the inverting input of the amplifier U2-3 for measuring reactive power of the first line A phase is connected via a first resistor R2_1-3 for measuring reactive power of the first line A phase to ground GND, a second resistor R2_2-3 for measuring reactive power of the first line A phase is connected between the inverting input and the output of the amplifier U2-3 for measuring reactive power of the first line A phase, the current input terminal 1_ a _ i _ IN-3 for measuring the active and reactive power of the a-phase of the first line is connected to a first input of a multiplier U4-3 for measuring the reactive power of the a-phase of the first line, the output of an amplifier U2-3 for measuring the reactive power of the a-phase of the first line is connected to a second input of a multiplier U4-3 for measuring the reactive power of the a-phase of the first line, and the output of a multiplier U4-3 for measuring the reactive power of the a-phase of the first line is connected to a reactive output terminal 1_ a _ Q _ OUT-3 for measuring the reactive power of the a-phase of the first line.

The first line B-phase active and reactive power measuring unit comprises an amplifier for measuring the B-phase active power of a first line, a first resistor, a second resistor, a third resistor, a first resistor, a second resistor, a fourth resistor, a multiplier and an active output terminal 1_ B _ P _ OUT-3, an amplifier for measuring the B-phase reactive power of the first line, a first resistor, a second resistor, a third resistor, a capacitor, a multiplier and a reactive output terminal 1_ B _ Q _ OUT-3, and a voltage input terminal 1_ B _ u _ IN-3 and a current input terminal 1_ B _ i _ IN-3 for measuring the B-phase active power and the reactive power of the first line, and the first line C-phase active and reactive power measuring unit comprises an amplifier for measuring the C-phase active power of the first line, a first resistor, a second resistor, a fourth resistor, a multiplier and an active output terminal 1_ C _ P _ OUT-3, an amplifier for measuring the C-phase reactive power of the, A multiplier and a reactive output terminal 1_ C _ Q _ OUT-3 and a voltage input terminal 1_ C _ u _ IN-3 and a current input terminal 1_ C _ i _ IN-3 for measuring the active and reactive of the C-phase of the first line, a second line A-phase active and reactive measurement unit comprising an amplifier for measuring the active of the A-phase of the second line, first to fourth resistors, a multiplier and an active output terminal 2_ A _ P _ OUT-3, an amplifier for measuring the reactive of the A-phase of the second line, first to third resistors, a capacitor, a multiplier and a reactive output terminal 2_ A _ Q _ OUT-3 and a voltage input terminal 2_ A _ u _ IN-3 and a current input terminal 2_ A _ i _ IN-3 for measuring the active and reactive of the A-phase of the second line, a second line B-phase active and reactive measurement unit comprising an amplifier for measuring the active and reactive of the B-phase of the second line, First to fourth resistors, a multiplier and an active output terminal 2_ B _ P _ OUT-3, an amplifier for measuring B-phase reactive power of the second line, first to third resistors, a capacitor, a multiplier and a reactive output terminal 2_ B _ Q _ OUT-3, and a voltage input terminal 2_ B _ u _ IN-3 and a current input terminal 2_ B _ i _ IN-3 for measuring B-phase active and reactive power of the second line, and a second-line C-phase active and reactive power measuring unit comprises an amplifier for measuring C-phase active power of the second line, first to fourth resistors, a multiplier and an active output terminal 2_ C _ P _ OUT-3, an amplifier for measuring C-phase reactive power of the second line, first to third resistors, a capacitor, a multiplier and a reactive output terminal 2_ C _ Q _ OUT-3, and a voltage input terminal 2_ C _ u _ IN-3 and a current input terminal 2 u \\ \ OUT-3 for measuring C-phase active and reactive power of the second line C _ i _ IN-3.

Wherein, the amplifier of each active and reactive measurement unit is a high-speed operational amplifier, the model is AD8017, the multiplier of each active and reactive measurement unit is a high-speed analog multiplier, the model is AD835, the first resistance of each active and reactive measurement unit for measuring active is a resistance with the resistance value of 1 kiloohm, the second resistance of each active and reactive measurement unit for measuring active is a resistance with the resistance value of 1 kiloohm, the third resistance of each active and reactive measurement unit for measuring active is a resistance with the resistance value of 9 kiloohm, the fourth resistance of each active and reactive measurement unit for measuring active is a resistance with the resistance value of 1 kiloohm, the first resistance of each active and reactive measurement unit for measuring reactive is a resistance with the resistance value of 1 kiloohm, and the second resistance of each active and reactive measurement unit for measuring reactive is a resistance with the resistance value of 1 kiloohm, the third resistance used for measuring the reactive power of each active and reactive power measurement unit is a resistance with a resistance value of 3 kilo ohms, the capacitance used for measuring the reactive power of each active and reactive power measurement unit is a capacitance with a capacitance value of 100 picofarads, and the amplifier and the corresponding communication connection technology are not repeated in the prior art.

As shown IN FIG. 2, a signal source terminal 1_ A _ IN-2 for measuring a first line A-phase current voltage, a signal source terminal 1_ B _ IN-2 for measuring a first line B-phase current voltage, a signal source terminal 1_ C _ IN-2 for measuring a first line C-phase current voltage, a signal source terminal 2_ A _ IN-2 for measuring a second line A-phase current voltage, a signal source terminal 2_ B _ IN-2 for measuring a second line B-phase current voltage, and a signal source terminal 2_ C _ IN-2 for measuring a second line C-phase current voltage form an input port of a current voltage measuring unit, i.e., an input port of a measuring instrument, an excitation terminal 1_ A _ OUT-2 for measuring a first line A-phase current voltage, an excitation terminal 1_ B _ OUT-2 for measuring a first line B-phase current voltage, a signal source terminal 1_ B _ OUT-2 for measuring a first line B-, An excitation terminal 1_ C _ OUT-2 for measuring the voltage of the first line C phase current, an excitation terminal 2_ A _ OUT-2 for measuring the voltage of the second line A phase current, an excitation terminal 2_ B _ OUT-2 for measuring the voltage of the second line B phase current, and an excitation terminal 2_ C _ OUT-2 for measuring the voltage of the second line C phase current form a first output port of a current-voltage measuring unit, i.e. a first output port of a measuring instrument, a current collection output terminal 1_ A _ i _ OUT-2 and a voltage collection output terminal 1_ A _ u _ OUT-2 for measuring the voltage of the first line A phase current, a current collection output terminal 1_ B _ i _ OUT-2 and a voltage collection output terminal 1_ B _ u _ OUT-2 for measuring the voltage of the first line B phase current, and a current collection output terminal 1_ C _ i _ OUT-2 for measuring the voltage of the first line C phase current And a voltage collecting output terminal 1_ C _ u _ OUT-2, a current collecting output terminal 2_ A _ i _ OUT-2 and a voltage collecting output terminal 2_ A _ u _ OUT-2 for measuring the phase-A current voltage of the second line, a current collecting output terminal 2_ B _ i _ OUT-2 and a voltage collecting output terminal 2_ B _ u _ OUT-2 for measuring the phase-B current voltage of the second line, a current collecting output terminal 2_ C _ i _ OUT-2 and a voltage collecting output terminal 2_ C _ u _ OUT-2 for measuring the phase-C current voltage of the second line form a second output port of a current-voltage measuring unit, namely a second output port of the measuring instrument, a current input terminal 1_ A _ i _ IN-3 and a voltage input terminal 1_ A _ u _ IN-3 for measuring the active and reactive of the phase of the first line, a, Current input terminal 1_ B _ i _ IN-3 and voltage input terminal 1_ B _ u _ IN-3 for measuring the active and reactive power of the B-phase of the first line, current input terminal 1_ C _ i _ IN-3 and voltage input terminal 1_ C _ u _ IN-3 for measuring the active and reactive power of the C-phase of the first line, current input terminal 2_ a _ i _ IN-3 and voltage input terminal 2_ a _ u _ IN-3 for measuring the active and reactive power of the a-phase of the second line, current input terminal 2_ B _ i _ IN-3 and voltage input terminal 2_ B _ u _ IN-3 for measuring the active and reactive power of the B-phase of the second line, current input terminal 2_ C _ i _ IN-3 and voltage input terminal 2_ C _ u _ IN-3 for measuring the active and reactive power of the C-phase of the second line form an input port of an active and reactive power measuring unit, active output terminal 1_ A _ P _ OUT-3 for measuring the active of the A-phase of the first line, reactive output terminal 1_ A _ Q _ OUT-3 for measuring the reactive of the A-phase of the first line, active output terminal 1_ B _ P _ OUT-3 for measuring the active of the B-phase of the first line, reactive output terminal 1_ B _ Q _ OUT-3 for measuring the reactive of the B-phase of the first line, active output terminal 1_ C _ P _ OUT-3 for measuring the active of the C-phase of the first line, reactive output terminal 1_ C _ Q _ OUT-3 for measuring the reactive of the C-phase of the first line, active output terminal 2_ A _ P _ OUT-3 for measuring the active of the A-phase of the second line, reactive output terminal 2_ A _ Q _ OUT-3 for measuring the reactive of the A-phase of the second line, active output terminal 2_ B _ P _ OUT-3 for measuring the active of the B-phase of the second line, The reactive output terminal 2_ B _ Q _ OUT-3 for measuring the reactive power of the B phase of the second line, the active output terminal 2_ C _ P _ OUT-3 for measuring the active power of the C phase of the second line and the reactive output terminal 2_ C _ Q _ OUT-3 for measuring the reactive power of the C phase of the second line form an output port of an active and reactive measuring unit, namely a third output port of the measuring instrument.

A rack model:

as shown IN fig. 11, the rack model includes a rack and two sets of three-phase transmission lines fixed on the rack, the two sets of three-phase transmission lines include six phase lines of the rack model and six signal access terminals, the six phase lines are respectively a first line a phase line 1A-4, a first line B phase line 1B-4, a first lineC phase line 1C-4, a second line aphase line 2A-4, a second lineB phase line 2B-4 and a second lineC phase line 2C-4 of the rack model, and the six signal access terminals are respectively a first line a phase input terminal 1_ a _ IN-4, a first line B phase input terminal 1_ B _ IN-4, a first line C phase input terminal 1_ C _ IN-4, a second line a phase input terminal 2_ a _ IN-4, a second line B phase input terminal 2_ B _ IN-4 and a second line C phase input terminal 2_ C _ IN _4 of the rack model -4.

One end of a first line A phase line 1A-4 of the rack model is connected with a first line A phase input terminal 1_ A _ IN-4 of the rack model to form a first branch line of a rack model A phase, the other end of the first line A phase line 1A-4 of the rack model is grounded GND through an A phase Load impedance A _ Load-4 of the rack model, and the A phase Load impedance A _ Load-4 of the rack model is a Load impedance formed by combining a resistor, a capacitor and an inductor of an actual situation according to analysis requirements. One end of a phase line A2A-4 of the second line of the rack model is connected with a phase input terminal A2 _ A _ IN-4 of the second line of the rack model to form a phase second branch of the rack model, and the other end of the phase line A2A-4 of the second line of the rack model is grounded GND through a phase Load impedance A _ Load-4 of the rack model. The first branch and the second branch of the A phase of the gantry model form an A phase circuit of the gantry model.

One end of a first line B phase line 1B-4 of the rack model is connected with a first line B phase input terminal 1_ B _ IN-4 of the rack model to form a first branch of a rack model B phase, the other end of the first line B phase line 1B-4 of the rack model is grounded GND through a B phase Load impedance B _ Load-4 of the rack model, and the B phase Load impedance B _ Load-4 of the rack model is a Load impedance formed by combining a resistor, a capacitor and an inductor of an actual situation according to analysis requirements. One end of a second linephase B line 2B-4 of the rack model is connected with a second line phase B input terminal 2_ B _ IN-4 of the rack model to form a second branch of the phase B of the rack model, and the other end of the second linephase B line 2B-4 of the rack model is grounded GND through a phase B Load impedance B _ Load-4 of the rack model. The first branch and the second branch of the B phase of the gantry model form a B phase circuit of the gantry model.

One end of a first lineC phase line 1C-4 of the rack model is connected with a first line C phase input terminal 1_ C _ IN-4 of the rack model to form a first branch of a rack model C phase, the other end of the first lineC phase line 1C-4 of the rack model is grounded GND through a C phase Load impedance C _ Load-4 of the rack model, and the C phase Load impedance C _ Load-4 of the rack model is a Load impedance formed by combining a resistor, a capacitor and an inductor of an actual situation according to analysis requirements. One end of a second lineC phase line 2C-4 of the rack model is connected with a second line C phase input terminal 2_ C _ IN-4 of the rack model to form a second branch of the rack model C phase, and the other end of the second lineC phase line 2C-4 of the rack model is grounded GND through a C phase Load impedance C _ Load-4 of the rack model. The first branch and the second branch of the C phase of the gantry model form a C phase circuit of the gantry model.

The first branch of the A phase of the rack model, the first branch of the B phase of the rack model and the first branch of the C phase of the rack model form a first circuit of the A phase to the C phase of the rack model, namely a first circuit of the A phase to the C phase of the rack model, and the second branch of the A phase of the rack model, the second branch of the B phase of the rack model and the second branch of the C phase of the rack model form a second circuit of the A phase to the C phase of the rack model, namely a second circuit of the A phase to the C phase of the rack model.

As shown IN fig. 2 and 11, the first line a-phase input terminal 1_ a _ IN-4, the first line B-phase input terminal 1_ B _ IN-4, the first line C-phase input terminal 1_ C _ IN-4, the second line a-phase input terminal 2_ a _ IN-4, the second line B-phase input terminal 2_ B _ IN-4, and the second line C-phase input terminal 2_ C _ IN-4 of the stage model form input ports of the stage model, i.e., input terminals of two groups of three-phase power transmission lines, and the first line a-phase input terminal 1_ a _ IN-4 of the stage model is a first input terminal of the stage model.

The low-pass filter is a built resistance-capacitance filter, the resistance is selected to be 1 kiloohm, and the capacitance is selected to be 100 nano-method.

Description of the wiring:

as shown in fig. 1 and fig. 2, the computer is electrically connected with the controller and is in bidirectional communication with the controller, the controller is electrically connected with the signal source and is in bidirectional communication with the signal source, the output port of the signal source is electrically connected with the input port of the current-voltage measuring unit, the first output port of the current-voltage measuring unit is connected with the input port of the gantry model, the second output port of the current-voltage measuring unit is connected with the input port of the active-reactive measuring unit, the second output port of the current-voltage measuring unit is electrically connected with the first input port of the low-pass filter, the output port of the active-reactive measuring unit is electrically connected with the second input port of the low-pass filter, and the output port of the.

Example 2:

example 2 differs from example 1 in that the output of the measuring instrument was connected to an oscilloscope, and data was manually read and analyzed.

As shown in fig. 12, the invention discloses a power grid transmission line analysis system, which comprises a computer, a controller, a signal source, a rack model based on the reduced power grid transmission line, a measuring instrument and an oscilloscope for measuring voltage and current, wherein the computer is electrically connected with the controller and is in two-way communication, the controller is electrically connected with the signal source and is in two-way communication, an output port of the signal source is electrically connected with an input port of the measuring instrument, a first output port of the measuring instrument is electrically connected with an input port of the rack model, a second output port of the measuring instrument is electrically connected with a first group of input ports of the oscilloscope, a third output port of the measuring instrument is electrically connected with a second group of input ports of the oscilloscope, and the voltage, the current, the active power and the reactive power of the rack model.

With respect to the above embodiment, the resistance value of the first active and reactive power measuring unit for measuring active resistance ranges from 0.5 kohm to 10 kohm, the resistance value of the second active and reactive power measuring unit for measuring active resistance ranges from 0.5 kohm to 10 kohm, the resistance value of the third active and reactive power measuring unit for measuring active resistance ranges from 1 kohm to 50 kohm, the resistance value of the fourth active and reactive power measuring unit for measuring active resistance ranges from 0.1 kohm to 5 kohm, the resistance value of the first active and reactive power measuring unit for measuring reactive power ranges from 0.5 kohm to 10 kohm, the resistance value of the second active and reactive power measuring unit for measuring reactive power ranges from 0.5 kohm to 10 kohm, and the resistance value of the third active and reactive power measuring unit for measuring reactive power ranges from 1 kohm to 50 kohm, the capacitance value of the capacitance used for measuring the reactive power of each active reactive power measuring unit ranges from 20 picofarads to 200 picofarads.

The invention concept of the application is as follows:

1. the working characteristic rule of the power transmission line is researched by improving the frequency. The invention preliminarily determines the working characteristic rule of the transmission line under the frequency of 50Hz by adopting the frequency of 5MHz through practice, but the claim is not limited to the frequency of 5MHz, the inventor thinks that the effect of the invention can be achieved by adopting the frequency in the range of 0.5MHz to 50MHz, and various advantages shown by the invention can be changed along with the adjustment of the frequency.

2. The invention measures the current using a differential operational amplifier. Many methods of measuring current have been tested in the practice of the present invention and the results of screening used in the present invention to measure current.

3. The invention adopts an analog multiplier to measure the active power. The invention adopts the analog multiplier to directly multiply the current and the voltage to measure the active power, and has the characteristics of low cost, simple structure and measurement precision meeting the requirement.

4. The invention adopts an analog multiplier to measure the reactive power. The invention firstly shifts the phase of the voltage forward by 90 degrees, and then multiplies the voltage by the current through the analog multiplier to measure the reactive power, and has the characteristics of low cost, simple structure and measurement precision meeting the requirement.

Technical contribution of the present application:

1. the present invention differs from the RTDS in that: the RTDS model is simulated by digital software, only the output end adopts digital-to-analog conversion technology to output real current and voltage quantity, the model of the invention simulates the actual electromagnetic law, but not software simulation, and the current and voltage quantity in the invention are all real quantity. Another difference is that RTDS operates at 50Hz and the present invention operates at 5 MHz.

2. The difference between the simulation platform and the AC/DC electromagnetic transient simulation platform is basically the same as that of the RTDS, the model of the AC/DC electromagnetic transient simulation platform is also simulated by digital software, only the digital-to-analog conversion technology is adopted at the output end to output real current and voltage quantities, the model of the invention is generated by simulating the actual electromagnetic law rather than software simulation, the working frequency of a simulation object of the AC/DC electromagnetic transient simulation platform is 50Hz, and the simulation platform works at 5 MHz. In addition, the aim of the invention is low-cost local simulation, the alternating current and direct current electromagnetic transient simulation platform needs to obtain the simulation of millisecond time scale which is subdivided from the small time scale in the whole Chinese power grid range, the investment scale is large, and the manufacturing cost difference is obvious.

3. The invention is different from a power grid system moving die in that: the power transmission line is regarded as an integral component by the power grid system moving die, the key point of the invention is to research the influence of parameters such as the internal size and the layout of the power transmission line on the electrical property of the power transmission line, and the research directions are different. And the power grid system moving die works at 50Hz, and the power grid system moving die works at 5 MHz.

Description of the technical solution:

the invention consists of five parts, namely a signal source, a measuring instrument, a rack model, a controller and a computer.

The signal source generates three-phase high-frequency signals, the signals act on the bench model, the signals are called excitation, and the reaction of the bench model is called response. The signal source outputs a fourth path of reference signal for the functions of phase-locked amplification, accurate phase measurement and the like of the measuring instrument. In the scope of this application, the fourth reference signal is not used. The measuring instrument is used for collecting the excitation of the signal source and the current and voltage of the response of the rack model, and calculating and analyzing useful information such as active power, reactive power, resistance, reactance and the like.

The bench model is according to the electromagnetism law, according to the principle that frequency rising wavelength shortens, with 1: the 100000 proportion is made, and the operation rule of the power transmission line of the power grid is simulated.

The controller controls the frequency, amplitude and phase of the signal, controls the working mode of the measuring instrument, and collects information such as the phase and amplitude of the current and the voltage obtained by the instrument.

The computer is a control center of the invention, and exchanges information with the controller through a serial port, a network cable and the like, thereby realizing integral data acquisition and control.

A signal source:

the three-phase high-frequency signal source is added with one path of reference signal and outputs four paths. The invention simulates three-phase alternating current of a power grid, designs and manufactures a three-phase high-frequency signal source, and simulates 50Hz alternating current of the power grid by using 5MHz three-phase high-frequency signals. The signal source has four paths of outputs, namely an A-phase output, a B-phase output, a C-phase output and a reference signal output. The A phase output, the B phase output and the C phase output are main outputs of a signal source, sinusoidal signals with equal amplitudes and 120-degree phase difference are generated, the amplitude and the phase can be independently adjusted through the reference signal output to serve as standby outputs to be used for assisting in subsequent measurement, and the signals are not used in the range of application of the invention.

The three-phase high-frequency signal source consists of a signal generating chip U1-1, a voltage amplifying chip U2-1-U5-1 and a current amplifying chip U6-1-U9-1. Chip U1-1 employs AD 9959. The AD9959 is composed of four direct digital frequency synthesizers (DDS), and a digital description of a waveform is written in a memory, and the description is sequentially read, converted into a voltage through digital-to-analog conversion, and output. The invention can synthesize four paths of arbitrary waveforms with associated frequency, amplitude and phase, and is used for synthesizing three paths of 5MHz sinusoidal three-phase voltages and adding one path of reference signal. The chip output terminals are respectively D0_ OUT, D1_ OUT, D2_ OUT and D3_ OUT, and under a 50-ohm load, the maximum output peak-to-peak value of the sine wave signal is 300 mV.

The voltage and current amplitudes of the signals required by the invention are larger than the values which can be provided by the U1-1 chip, so that a voltage and current amplification link is designed. The voltage amplification is provided by the chips U2-1-U5-1, the amplification factor is 60, the maximum peak value reaches 18V, the current amplification is provided by the chips U6-1-U9-1, and the maximum output current can reach 300 mA.

The use process comprises the following steps: sending a control signal to a U1-1 chip, setting the frequency of a signal of D0_ OUT to be a sine wave of 5MHz, outputting a peak-to-peak value of 300mV in amplitude and a phase of 0 degree, and obtaining an A-phase alternating current sine signal with the peak-to-peak value of 18V and the phase of 0 degree at an A-phase output terminal; setting the frequency of a signal of D1_ OUT to be a 5MHz sine wave, outputting a peak-to-peak value of 300mV in amplitude and 120 degrees in phase, and obtaining a B-phase alternating current sine signal with the peak-to-peak value of 18V and the phase of 120 degrees at a B-phase output terminal; setting the frequency of a signal D2_ OUT to be 5MH, outputting a C-phase alternating current sinusoidal signal with the amplitude of 300mV peak-to-peak value and the phase of 240 degrees, and obtaining the peak-to-peak value of 18V and the phase of 240 degrees at a C-phase output terminal; the frequency of the signal D3_ OUT is set to be 5MH, the signal is in a sine wave, the output amplitude is 50mV peak-to-peak value, the phase is 90 degrees, and a sine reference signal with the peak-to-peak value of 3V and the phase of 90 degrees is obtained at the output end of the reference signal.

A measuring instrument:

the measuring instrument comprises a current and voltage measuring unit and an active and reactive measuring unit.

1. Current and voltage measuring unit

In order to accurately measure the current and voltage of each phase, the present invention employs a specially designed current-voltage measuring unit. The experiment has two groups of circuits to be measured, namely a first circuit and a second circuit, each group of circuits needs to measure ABC three phases, and six phases are required, and six groups of current and voltage measuring units with the same structure are required.

Taking a set of current and voltage measuring units, i.e. a first line a-phase current and voltage measuring unit as an example, the working principle is described as follows:

a three-phase high-frequency signal source A phase is connected to a first line A phase current voltage measuring unit through a distributor, a signal source terminal 1_ A _ IN-2 of a first line A phase current voltage measuring unit is connected to the A phase signal source terminal 1_ A _ IN-2 of the first line A phase, current of the A phase signal source A phase current voltage measuring unit flows OUT of a first line A phase excitation terminal 1_ A _ OUT-2 of the first line A phase current voltage measuring unit after passing through a first line A phase current sampling resistor R1-2 of the first line A phase current voltage measuring unit, the current generates voltage on a first line A phase current sampling resistor R1-2 with the resistance value of 5 ohms, the voltage is amplified through a differential operational amplifier U1-2 to obtain output voltage corresponding to the amplitude value and the phase value, and the output voltage is output through a first line A phase current collecting output terminal 1_ A.

The differential operational amplifier U2-2 of the first line a-phase current voltage measuring unit collects the voltage of the first line a-phase terminal 1_ a _ IN-4 of the gantry model through the first line a-phase excitation terminal 1_ a _ OUT-2 of the first line a-phase current voltage measuring unit and forms an output voltage corresponding to the magnitude and phase of the voltage, which is output through the first line a-phase voltage collection output terminal 1_ a _ U _ OUT-2 of the first line a-phase current voltage measuring unit.

Under the condition that the amplification factors of the differential operational amplifier U1-2 and the differential operational amplifier U2-2 of the first line A-phase current and voltage measuring unit are set to be 1, 5mV voltage is output on the differential operational amplifier U1-2 by 1mA current, namely 5mV voltage is output by the first line A-phase current collecting and outputting terminal 1_ A _ i _ OUT-2 of the first line A-phase current and voltage measuring unit. The 1mV voltage at the first line A phase excitation terminal 1_ A _ OUT-2 of the first line A phase current voltage measurement unit will output a 1mV voltage at the differential operational amplifier U2-2, i.e., the first line A phase voltage acquisition output terminal 1_ A _ U _ OUT-2 of the first line A phase current voltage measurement unit outputs a 1mV voltage.

The working process is as follows:

an input end connection method: a three-phase high-frequency signal source generates a three-phase signal, an A-phase output of the three-phase high-frequency signal source is simultaneously connected to a first line A-phase signal source terminal 1_ A _ IN-2 of a first line A-phase current voltage measuring unit and a second line A-phase signal source terminal 2_ A _ IN-2 of a second line A-phase measuring unit through a distributor, a B-phase output of the three-phase high-frequency signal source is simultaneously connected to a first line B-phase signal source terminal 1_ B _ IN-2 of the first line B-phase measuring unit and a second line B-phase signal source terminal 2_ B _ IN-2 of the second line B-phase measuring unit through a distributor, the C-phase output of the three-phase high-frequency signal source is simultaneously connected to a first line C-phase signal source terminal 1_ C _ IN-2 of the first line C-phase measuring unit and a second line C-phase signal source terminal 2_ C _ IN-2 of the second line C-phase measuring unit via a distributor.

An output end connection method: the first line A phase excitation terminal 1_ A _ OUT-2 of the first line A phase current voltage measuring unit is connected to the first line A phase terminal 1_ A _ IN-4 of the gantry model, and the second line A phase excitation terminal 2_ A _ OUT-2 of the second line A phase current voltage measuring unit is connected to the second line A phase terminal 2_ A _ IN-4 of the gantry model. The first line B-phase excitation terminal 1_ B _ OUT-2 of the first line B-phase current-voltage measuring unit is connected to the first line B-phase terminal 1_ B _ IN-4 of the gantry model, and the second line B-phase excitation terminal 2_ B _ OUT-2 of the second line B-phase current-voltage measuring unit is connected to the second line B-phase terminal 2_ B _ IN-4 of the gantry model. The first line C-phase excitation terminal 1_ C _ OUT-2 of the first line C-phase current-voltage measuring unit is connected to the first line C-phase terminal 1_ C _ IN-4 of the gantry model, and the second line C-phase excitation terminal 2_ C _ OUT-2 of the second line C-phase current-voltage measuring unit is connected to the second line C-phase terminal 2_ C _ IN-4 of the gantry model. The first line A phase current acquisition output terminal 1_ A _ i _ OUT-2 of the first line A phase current voltage measurement unit and the first line A phase voltage acquisition output terminal 1_ A _ u _ OUT-2 of the first line A phase current voltage measurement unit are respectively connected to an oscilloscope and the amplitude and the phase of a signal are observed, if the output of the first line A phase current acquisition output terminal 1_ A _ i _ OUT-2 of the first line A phase current voltage measurement unit is 750mV, the corresponding current is 150mA, and if the output of the first line A phase current acquisition output terminal 1_ A _ u _ OUT-2 of the first line A phase current voltage measurement unit is 4V, the corresponding voltage is 4V. The rest five phases are analogized. The outputs of the first line A phase current acquisition output terminal 1_ A _ i _ OUT-2 of the first line A phase current voltage measurement unit and the first line A phase voltage acquisition output terminal 1_ A _ u _ OUT-2 of the first line A phase current voltage measurement unit are also used as inputs of the active and reactive measurement unit.

2. Active and reactive power measuring unit

The invention provides a method for measuring active and reactive power. The active power is obtained by multiplying the voltage and the current, and the reactive power is obtained by multiplying the voltage, the phase of which is advanced and shifted by 90 degrees, and the current.

As shown in fig. 10, the working principle of the active and reactive power measuring unit adopted by the present invention is described.

The first operational amplifier U1-3 and the second operational amplifier U2-3 of the first line A phase active and reactive power measurement unit are high-speed operational amplifiers and are used for arranging, phase shifting and amplifying voltage signals. The first multiplier U3-3 and the second multiplier U4-3 of the first line A phase active and reactive power measurement unit are high-speed analog multiplier chips and are used for multiplying signals to obtain active and reactive signals.

And acquiring an active signal, wherein the active signal is obtained by multiplying a specially prepared voltage signal and a current signal through an analog multiplier. The voltage signal preparation process of the active signal is that firstly, a resistor R1_3-3 and a resistor R1_4-3 beside a first operational amplifier U1-3 of the first line A-phase active and reactive power measurement unit attenuate the voltage signal by 10 times, the amplitude is reduced to 1/10 of the original voltage signal and the phase is kept unchanged, the resistor R1_1-3 and a resistor R1_2-3 control the amplification factor of the first operational amplifier U1-3 of the first line A-phase active and reactive power measurement unit, the invention adopts the double amplification factor, and the output end of the first operational amplifier U1-3 of the first line A-phase active and reactive power measurement unit obtains the voltage signal which has the amplitude and keeps the phase unchanged with theoriginal voltage signal 1/5. The prepared voltage signal and the current signal are multiplied through a first multiplier U3-3 of the first line A-phase active and reactive power measuring unit to obtain an active signal, and the active signal is output through an active output terminal 1_ A _ P _ OUT-3 of the first line A-phase active and reactive power measuring unit.

And obtaining a reactive signal, wherein the reactive signal is obtained by multiplying a specially prepared reactive voltage signal and a current signal through an analog multiplier. The voltage signal of the reactive signal is prepared by firstly attenuating the voltage signal by 10 times through a resistor R2_3-3 and a capacitor C2_1-3 beside a second operational amplifier U2-3 of the first line A-phase active and reactive measurement unit, and enabling the phase of the signal to move forward by 90 degrees, wherein the resistor R2_1-3 and the resistor R2_2-3 control the amplification factor of the second operational amplifier U2-3 of the first line A-phase active and reactive measurement unit, and the invention adopts the amplification factor of two times, and the output end of the second operational amplifier U2-3 of the first line A-phase active and reactive measurement unit obtains the voltage signal which has the amplitude value which is 90 degrees ahead of theoriginal voltage signal 1/5 and has the phase which is the reactive voltage signal. And multiplying the prepared reactive voltage signal and the current signal by a second multiplier U4-3 of the A-phase active and reactive measurement unit of the first line to obtain a reactive signal, and outputting the reactive signal through a reactive output terminal 1_ A _ Q _ OUT-3 of the A-phase active and reactive measurement unit of the first line.

The active measurement value of the first line a phase will be obtained at the active output terminal 1_ a _ P _ OUT-3 of the first line a phase active and reactive measurement value of the first line a phase will be obtained at the reactive output terminal 1_ a _ Q _ OUT-3 of the first line a phase active and reactive measurement unit.

A rack model:

the bench model is according to the electromagnetism law, according to the principle that frequency rising wavelength shortens, with 1: the 100000 proportion is made, and the operation rule of the power transmission line of the power grid is simulated. The method is characterized in that a 5MHz three-phase high-frequency signal generated by a signal source is loaded on a rack model through a measuring instrument, the electromagnetic law of the rack model is reflected by the amplitude and the phase of current and voltage, and the characteristics are finally captured by the measuring instrument to complete the simulation research on the operation law of the power transmission line of the power grid.

A controller:

the controller is an STM32 singlechip, controls the frequency, amplitude and phase of signals, controls the working mode of the measuring instrument, and collects information such as the phase and amplitude of current and voltage obtained by the instrument. The controller obtains the frequency, amplitude and phase commands of the signals sent to the signal source by the instructions from the computer, and respectively controls the A-phase output, the B-phase output and the C-phase output of the signal source to enable the signal source to generate 5MHz three-phase high-frequency sinusoidal signals. The following information is collected from the measuring instrument: the current and the phase of the voltage of the first line A phase are active and reactive, the current and the phase of the voltage of the first line B phase are active and reactive, the current and the phase of the voltage of the first line C phase are active and reactive, the current and the phase of the voltage of the second line A phase are active and reactive, the current and the phase of the second line B phase are active and reactive, and the current and the phase of the second line C phase are active and reactive. And transmits the information to the computer.

A computer:

the computer is a control center of the invention, and exchanges information with the controller through a serial port, a network cable and the like, thereby realizing integral data acquisition and control. The computer sends frequency, amplitude and phase commands of the signals to the controller, and the commands are translated into signal source commands through the controller to control the signal source commands to generate 5MHz three-phase high-frequency sinusoidal signals. The computer receives the current, voltage amplitude and phase signals and active and reactive signals sent by the controller, and comprehensively analyzes the signals to complete all simulation functions.

After the application runs secretly for a period of time, the technical staff feed back is as follows:

a signal source:

1. according to the signal source, voltage amplification and current amplification links are added after the four DDS (direct digital synthesizer) of AD9959, so that the voltage amplitude and the power of an output signal are improved, and the loss of a rack model is offset.

2. The signal source of the invention is composed of three main signals and one reference signal.

3. The frequency, amplitude and phase of the three main signals are independently adjustable.

4. The three main signals of the invention are generally set into sine wave signals with the same frequency and the same amplitude according to the mode of three-phase sine alternating current, and the A, B, C phases are respectively lagged by 120 degrees.

5. The three main signals can also be set to a three-phase sine alternating current mode with a negative sequence, and the specific method is to set the three main signals to be sine signals with the same frequency and the same amplitude, wherein the A, C, B phases are respectively lagged by 120 degrees.

6. The three main signals can also be set to be a zero-sequence three-phase sine alternating current mode, and the specific method is to set the three main signals to be sine signals with the same frequency and the same amplitude, wherein A, B, C phases are completely the same.

7. The three-way main signal of the present invention can also be set to a three-phase sinusoidal ac power mode having a positive sequence, a negative sequence and a zero sequence, and in this mode, the three-phase sinusoidal ac power mode is set to the same frequency, but the A, B, C phases are no longer the same in amplitude and the phases are no longer 120 degrees in phase.

8. The reference signal of the invention is used by setting the frequency to be the same as the main signal, the amplitude is 0.01 to 0.5 times of the main signal, and the phase is scanned from 0 degree to 360 degrees according to a certain rule.

Means for measuring current:

1. in order to reduce the influence of inductance in a sampling resistor loop as much as possible, the sampling resistor is close to the input end of the differential operational amplifier as much as possible during circuit wiring, so that the area enclosed by the sampling resistor, the resistor lead, the circuit board lead and the differential amplifier lead is as small as possible, and the sampling resistor and the differential operational amplifier sample elements packaged by small patches.

2. The invention selects the resistance value of the sampling resistor, and comprehensively considers two factors of sampling sensitivity and insertion error of simulation experiment as small as possible. If the resistance value is large, the sampling sensitivity is high, but the insertion error is large, so that the reliability of a simulation result is influenced. The sampling sensitivity is low when the resistance value is small, although the insertion error is small, the sensitivity is too low, the clutter interference is increased, and a credible result cannot be obtained easily.

3. The invention selects a high-speed differential operational amplifier to be matched with a sampling resistor to obtain current measurement, the amplification factor of the high-speed differential operational amplifier is too high, which affects the amplification precision of amplitude and phase, the amplification factor of the invention is 1 to 10 times, and the typical value is 1 time.

4. The performance of the high-speed differential operational amplifier used by the invention is closely related to the voltage of a power supply, and the high-speed differential operational amplifier adopts positive and negative 12V power supply, which is the highest working voltage allowed by the high-speed differential operational amplifier. Supply voltages below this value tend to distort the waveform of the current measurement.

5. In order to reduce external noise interference as much as possible, the invention adopts a copper coating strategy on the circuit board, but in order to avoid the influence of capacitance introduced by copper coating on the measurement precision, copper is not coated in the area enclosed among the sampling resistor, the resistor lead, the circuit board lead and the differential amplifier lead.

Device for measuring active and reactive:

1. the active attenuator is used for conditioning the voltage signal, and the active attenuator can isolate the signal, so that the input resistance of the measuring device is increased, and the interference of the measuring device on the rack model is reduced.

2. The attenuation times of the active attenuator of the measuring device are 10 times of attenuation at first, 2 times of amplification of the high-speed operational amplifier and 5 times of total attenuation.

3. The reactive power measuring active attenuator consists of a resistor and a capacitor, and can form amplitude attenuation of 5 times and a phase shift phase leading by 90 degrees.

4. The invention adopts a high-speed analog multiplier to multiply the current measurement and the voltage measurement output by the active attenuator to obtain the active or reactive measurement, and has the characteristics of small volume, less input devices, low cost and meeting the requirement on precision. Compared with the conventional scheme adopting high-speed AD sampling, the volume is reduced by about 80%, the number of devices is reduced by about 70%, and the cost is reduced by about 90%.

5. The device for measuring active power and reactive power is two independent components and can work independently. Because micro simulation experiments generally need to measure active power and reactive power at the same time, in order to reduce complexity, the invention integrates two devices together for design.

6. The resistance network sampling 9 of the active attenuator for measuring work is designed to be more than 1, the resistance value of the resistor is moderate, noise in the resistor is too large, inductance factors are increased, interference is introduced, and the active attenuator for measuring work cannot play a role in isolating a signal source when the resistance value is too small.

7. The invention relates to a resistance-capacitance attenuation phase-shifting network sampling 10-to-1 design before reactive active attenuation is measured.

Claims (10)

1. The utility model provides a power grid transmission line analytic system which characterized in that: the power grid power transmission line reduction-based rack model comprises a computer, a controller, a signal source, a rack model and a measuring instrument, wherein the rack model is based on a reduced power grid power transmission line, the measuring instrument is used for measuring voltage and current, the computer is electrically connected with and communicates with the controller, the controller is electrically connected with and communicates with the signal source, the output end of the signal source is electrically connected with the input end of the measuring instrument, and the output end of the measuring instrument is electrically connected with the input end of the rack model to obtain the voltage and the current of the rack.

2. The power grid transmission line analysis system of claim 1, wherein: the signal source comprises a signal generator and an amplifying circuit used for forming the signal source, the amplifying circuit used for forming the signal source comprises a voltage amplifier and a current amplifier used for forming the signal source, and the signal generator, the voltage amplifier and the current amplifier used for forming the signal source are sequentially connected; the signal source is a signal source with the frequency range of 0.5 MHz-50 MHz.

3. The power grid transmission line analysis system of claim 2, wherein: the signal source is a three-phase signal source; the signal generator comprises a signal generator, a signal source, a first amplifying circuit, a second amplifying circuit, a third amplifying circuit, a fourth amplifying circuit and a fourth amplifying circuit, wherein the number of the amplifying circuits for forming the signal source is three, the first amplifying circuits to the third amplifying circuits are respectively the same in structure and are used for forming the signal source, and a first output; the voltage of the rack model is three-phase voltage, and the current of the rack model is three-phase current.

4. The power grid transmission line analysis system of claim 2, wherein: the voltage amplifier used for forming the signal source is a differential operational amplifier, and the current amplifier used for forming the signal source is a current buffer; the signal source is a signal source with the frequency of 5 MHz.

5. The power grid transmission line analysis system of claim 1, wherein: the measuring instrument comprises a first measuring unit and a second measuring unit, the first measuring unit is used for measuring current and voltage, the second measuring unit is used for measuring active power and reactive power, an output port of the signal source is connected with an input port of the first measuring unit, a first output port of the first measuring unit is connected with an input port of the bench model, and a second output port of the first measuring unit is connected with an input port of the second measuring unit.

6. The power grid transmission line analysis system of claim 5, wherein: the first measuring unit is a current and voltage measuring unit which comprises a first voltage amplifier, a second voltage amplifier and a current sampling resistor, wherein the first voltage amplifier is used for measuring current and voltage; the second measurement unit is used for measuring an active and reactive measurement unit, and the active and reactive measurement unit comprises an amplifier for measuring active, first to fourth resistors and a multiplier, an amplifier for measuring reactive, first to third resistors, a capacitor and a multiplier; the output end of the signal source is connected with the positive phase input end of a first voltage amplifier for measuring current and voltage, the negative phase input end of the first voltage amplifier for measuring current and voltage is connected with the positive phase input end of a second voltage amplifier for measuring current and voltage, the negative phase input end of the second voltage amplifier for measuring current and voltage is grounded, a current sampling resistor for measuring current and voltage is connected between the positive phase input end and the negative phase input end of the first voltage amplifier for measuring current and voltage, and the connection part of the negative phase input end of the first voltage amplifier for measuring current and voltage and the positive phase input end of the second voltage amplifier for measuring current and voltage is connected with the first input end of the rack model; the positive phase input end of the amplifier for measuring the work is connected to the output end of the second voltage amplifier for measuring the current and the voltage through a third resistor for measuring the work, the positive phase input end of the amplifier for measuring the work is connected to the ground through a fourth resistor for measuring the work, the negative phase input end of the amplifier for measuring the work is connected to the ground through a first resistor for measuring the work, a second resistor for measuring the work is connected between the negative phase input end and the output end of the amplifier for measuring the work, the output end of the first voltage amplifier for measuring the current and the voltage is connected with the first input end of the multiplier for measuring the work, and the output end of the amplifier for measuring the work is connected with the second input end of the multiplier for measuring the work; the positive phase input end of the amplifier for measuring the reactive power is connected to the output end of the second voltage amplifier for measuring the current voltage through a third resistor for measuring the reactive power, the positive phase input end of the amplifier for measuring the reactive power is connected to the ground through a capacitor for measuring the reactive power, the negative phase input end of the amplifier for measuring the reactive power is connected to the ground through a first resistor for measuring the reactive power, a second resistor for measuring the reactive power is connected between the negative phase input end and the output end of the amplifier for measuring the reactive power, the output end of the first voltage amplifier for measuring the current voltage is connected with the first input end of the multiplier for measuring the reactive power, and the output end of the amplifier for measuring the reactive power is connected with the second input end of the multiplier for measuring the reactive power.

7. The power grid transmission line analysis system of claim 6, wherein: the active and reactive power measurement unit comprises six active and reactive power measurement units with the same structure, namely a first line A-C phase current and voltage measurement unit and a second line A-C phase current and voltage measurement unit respectively; the first voltage amplifier and the second voltage amplifier for measuring the current and the voltage are both differential operational amplifiers, and the current sampling resistor for measuring the current and the voltage is a resistor with the resistance value range of 1 ohm to 20 ohms; the amplifier for measuring active and the amplifier for measuring inactive are operational amplifiers, the multiplier for measuring active and the multiplier for measuring inactive are analog multipliers, the first resistor for measuring active is a resistor with a resistance value ranging from 0.5 kilo-ohm to 10 kilo-ohm, the second resistor for measuring active is a resistor with a resistance value ranging from 0.5 kilo-ohm to 10 kilo-ohm, the third resistor for measuring active is a resistor with a resistance value ranging from 1 kilo-ohm to 50 kilo-ohm, the fourth resistor for measuring active is a resistor with a resistance value ranging from 0.1 kilo-ohm to 5 kilo-ohm, the first resistor for measuring inactive is a resistor with a resistance value ranging from 0.5 kilo-ohm to 10 kilo-ohm, the second resistor for measuring inactive is a resistor with a resistance value ranging from 0.5 kilo-ohm to 10 kilo-ohm, and the third resistor for measuring inactive is a resistor with a resistance value ranging from 1 kilo-ohm to 50 kilo-ohm, the capacitance used for measuring the reactive power is a capacitance having a capacitance value in the range of 20 picofarads to 200 picofarads.

8. The power grid transmission line analysis system of claim 6, wherein: the current sampling resistor for measuring current and voltage is a resistor with the resistance value of 5 ohms, the first resistor for measuring active is a resistor with the resistance value of 1 kiloohm, the second resistor for measuring active is a resistor with the resistance value of 1 kiloohm, the third resistor for measuring active is a resistor with the resistance value of 9 kiloohm, the fourth resistor for measuring active is a resistor with the resistance value of 1 kiloohm, the first resistor for measuring reactive is a resistor with the resistance value of 1 kiloohm, the second resistor for measuring reactive is a resistor with the resistance value of 1 kiloohm, the third resistor for measuring reactive is a resistor with the resistance value of 3 kiloohm, and the capacitor for measuring reactive is a capacitor with the capacitance value of 100 picofarads.

9. The power grid transmission line analysis system of claim 1, wherein: the rack model comprises a rack and two groups of three-phase transmission lines arranged on the rack, the six phase lines of the two groups of three-phase transmission lines including the rack model are respectively a first line A-C phase line and a second line A-C phase line of the rack model, and the output end of the measuring instrument is connected with the input ends of the two groups of three-phase transmission lines arranged on the rack.

10. The power grid transmission line analysis system according to any one of claims 1 to 9, characterized in that: the measuring instrument is connected with the information conversion device and is communicated with the information conversion device; the controller is a single chip microcomputer; the information conversion device is a low-pass filter, the measuring instrument is connected with the controller through the low-pass filter and is in one-way communication, or the information conversion device is an oscilloscope, and the measuring instrument is connected with the oscilloscope and is in one-way communication.

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