CN202940735U - Power amplifier used for intelligent transformer substation test system - Google Patents

Abstract

The utility model discloses a power amplifier used for an intelligent transformer substation test system. The power amplifier comprises a power supply input module used for outputting a 220V alternating voltage, a rectifier bridge used for rectifying the 220V alternating voltage into a 300V direct voltage, a DC/DC convertor used for converting the 300V direct voltage into a 1V-150V direct voltage and a DC/AC convertor used for carrying out power amplification output on a reference signal, wherein the power supply input module, the rectifier bridge, the DC/DC convertor and the DC/AC convertor are successively connected with each other. By using the power amplifier used for the intelligent transformer substation test system of the utility model, efficiency of the power amplifier can be increased and a power density of the power amplifier can be increased too. Besides, the power amplifier can be provided with multiple protections, such as an overcurrent protection and an overvoltage protection so as to guarantee stability and security during operation of the system.

Description

A kind of power amplifier for the intelligent substation test macro

Technical field

The utility model relates to a kind of power amplifier, is specifically related to a kind of power amplifier for the intelligent substation test macro.Belong to the intelligent substation technical field of measurement and test.

Background technology

Fast development along with communication network technology, photo-electricity mutual-inductor technology, digital protection technology; a plurality of manufacturing firms, R﹠D institution have done a large amount of innovation research work intelligent grid transformer station is technical, and have obtained experience and the achievement of the research of intelligent grid digital transformer substation.in brief, digital transformer substation is the important component part of building unified strong intelligent grid, digital transformer substation will be changed one of traditional transformer station, secondary device, with transformer station one, secondary device is the digitlization object, take the express network communication platform as the basis, the protection and measurement and control device of corresponding every cover primary equipment all need run on network, the electric current that secondary device is required, voltage and control signal, and protection and measurement and control device all data of being in operation and producing, all exchange with unified communication protocol and network again, by digital information is carried out standardization, realize information sharing and interactive operation, and take network data as the basis, realize that DATA REASONING monitors, control protection, the transformer station of the automation functions such as information management.

In intelligent digitalized transformer station technology development, the research of the means of testing of intelligent grid digital transformer substation is also being deepened continuously.As an aspect of means of testing research, the intelligent substation test macro is the key whether each power equipment of verifying smart transformer station works.

On the other hand, power amplifier is the core of intelligent substation test macro, can complete the power amplification of artificial setting signal by this power amplifier, and drives the analogue type protective relaying device.Usually, the common power output of power amplifier is larger, and the power output of single module can be up to 100 volt-amperes to several kilovolt-amperes.In the prior art, often adopt Switching Power Supply to add the combination of linear power amplifier, utilize switch power module as the power supply of Linear Power Amplifier.But because Linear Power Amplifier efficient is lower, and heating is serious, thereby power density is difficult to promote.In view of this, how designing a kind of new power amplification scheme, improve power amplification efficiency and increase power density with effective, is the problem that those skilled in the relevant art should solve.

Summary of the invention

The purpose of this utility model is for overcoming above-mentioned the deficiencies in the prior art, a kind of power amplifier for the intelligent substation test macro being provided.

For achieving the above object, the utility model adopts following technical proposals:

A kind of power amplifier for the intelligent substation test macro, comprise Power Entry Module for the alternating voltage of output 220V, be used for the 220V ac voltage rectifier be the direct voltage of 300V rectifier bridge, be used for direct voltage with 300V be converted to 1V ~ 150V direct voltage the DC/DC converter and be used for reference signal is carried out the DC/AC converter of power amplification output, four connect in turn.

Preferably, described DC/DC converter is a semi-bridge alternation circuit.

Described semi-bridge alternation circuit comprises:

The primary side circuit, comprise resistance R 1, resistance R 2, switching tube Q1 and switching tube Q2, wherein, the first end of the first end of described resistance R 1 and described switching tube Q1 is connected to an end of 300V direct voltage, and the second end of described resistance R 2 and the second end of described switching tube Q2 are connected to the other end of 300V direct voltage;

High frequency transformer, have first side winding, the first secondary side winding and the second secondary side winding, common node and the other end that an end of described first side winding is electrically connected to described resistance R 1 and resistance R 2 are connected to the second end of described switching tube Q1 and the first end of described switching tube Q2 via capacitor C 3; And

the secondary side circuit, comprise diode D3, diode D4, flat ripple inductance L 1 and two filter capacitor C4 ~ C5, one end of anodic bonding to the first secondary side winding of diode D3 and negative electrode are connected to the first end of described flat ripple inductance L 1, one end of anodic bonding to the second secondary side winding of diode D4 and negative electrode are connected to the first end of described flat ripple inductance L 1, two filter capacitor C4 ~ C5 are connected in parallel, the other end that the end of filter capacitor C4 ~ C5 is connected to the other end of described flat ripple inductance L 1 and filter capacitor C4 ~ C5 is connected to the common end of the first secondary side winding and the second secondary side winding.

Preferably, described diode D3 and diode D4 are fast recovery rectifier diode.

Preferably, described DC/AC converter is a full-bridge circuit.

Described full-bridge circuit comprises:

The first brachium pontis, have the switching tube Q6 and the switching tube Q7 that are connected in series, the first end of described switching tube Q6 is connected to an end of described input voltage, the second end of described switching tube Q7 is connected to the other end of described input voltage, and the second end of described switching tube Q6 is electrically connected to the first end of described switching tube Q7 and forms first node A;

The second brachium pontis, be connected in parallel with described the first brachium pontis, have the switching tube Q8 and the switching tube Q9 that are connected in series, the first end of described switching tube Q8 is connected to the first end of described switching tube Q6, the second end of described switching tube Q9 is connected to the second end of described switching tube Q7, and the second end of described switching tube Q8 is electrically connected to the first end of described switching tube Q9 and forms Section Point B; And

Second-order low-pass filter, comprise inductance L 6, inductance L 7, capacitor C 6 and capacitor C 7, wherein, the first end of described inductance L 6 is connected to described first node A, the first end of described capacitor C 6 is connected to the second end of described inductance L 6 and the first end of described inductance L 7, the second end of described capacitor C 6 is connected to the second end of described Section Point B and described capacitor C 7, and the first end of described capacitor C 7 is connected with the second end of described inductance L 7.

When switching tube Q6 and switching tube Q9 conducting, described switching tube Q7 and switching tube Q8 cut-off; When described switching tube Q7 and switching tube Q8 conducting, described switching tube Q6 and switching tube Q9 cut-off.

Described power amplifier also comprises overvoltage crowbar and the current foldback circuit that the output voltage of DC/DC converter and output current are detected respectively and protect.

The beneficial effects of the utility model are, adopt the power amplifier for the intelligent substation test macro of the present utility model, can improve the efficient of power amplifier, and increase the power density of power amplifier.In addition, this power amplifier also can arrange the multiple protective design of overcurrent protection and overvoltage protection, stability and fail safe during with the operation of assurance system.

Description of drawings

Fig. 1 is structured flowchart of the present utility model;

Fig. 2 is the circuit diagram of DC/DC converter;

Fig. 3 is the circuit diagram of the primary side of DC/AC converter;

Fig. 4 is the optocoupler structure chart of isolation that the half-bridge output voltage is sampled;

The circuit theory diagrams that Fig. 5 samples and isolates the half-bridge output voltage for the optocoupler that adopts Fig. 4;

Fig. 6 when using the half-bridge output voltage sampling isolation circuit of Fig. 5, take input voltage as abscissa and output voltage be the match linearity of the ordinate line of writing music;

Fig. 7 is for adopting the current transformer method to carry out the circuit diagram that overcurrent detects and protects.

Embodiment

Below in conjunction with drawings and Examples, the utility model is further set forth, should be noted that following explanation is only in order to explain the utility model, its content not to be limited.

Fig. 1 is structured flowchart of the present utility model.As shown in Figure 1, the utility model comprises Power Entry Module 101, rectifier bridge 103, DC/DC converter 105 and DC/AC converter 107.Power Entry Module 101 output 220V alternating voltages, rectifier bridge 103 is connected to Power Entry Module 101, with the direct voltage of 220V alternating voltage conversion into about 300V, DC/DC converter 105 is according to actual operating position, the 300V direct voltage is converted to the direct voltage of 1V ~ 150V, thereby provide power supply for DC/AC converter 107.The reference signal that DC/AC converter 107 provides control system is carried out power amplification output.

DC/DC converter using half-bridge converter, its major advantage are that it is Vdc that switching tube bears voltage when turn-offing, rather than is the Vdc of 2 times as push-pull topology or single-ended forward converter (Forward).Under identical situation, be equivalent to reduce the requirement of withstand voltage to switching device, be applicable to the occasion that input voltage is high, power output is large.

Fig. 2 illustrates the circuit diagram of the DC/DC converter in the power amplifier of Fig. 1.Specifically, resistance R 1, resistance R 2 are used for determining midpoint potential, and the voltage on assurance capacitor C 1 and capacitor C 2 is respectively half of Vdc, i.e. 1/2Vdc.Switching tube Q1, switching tube Q2 can be MOSFET or IGBT, and capacitor C 3 is capacitances, are used for preventing transformer T1 magnetic bias.Diode D1, diode D2 inverse parallel be at the DS of switching tube Q1 and switching tube Q2 end, and the leakage inductance peak voltage clamper that switching tube Q1 and switching tube Q2 are born is in Vdc.T1 is high frequency transformer, realizes conversion and the isolation of energy.At the secondary side of high frequency transformer T1, diode D3 and diode D4 are fast recovery rectifier diodes, and inductance L 1 is flat ripple inductance, and capacitor C 4, capacitor C 5 are secondary side filter capacitors.Resistance R 3 is dummy loads, is used for guaranteeing that the electric current of flat ripple inductance L 1 keeps continuous state.

In more detail, the circuit of this DC/DC converter can be described below.This semi-bridge alternation circuit comprises: primary side circuit, high frequency transformer and secondary side circuit.Wherein, the primary side circuit comprises resistance R 1, resistance R 2, switching tube Q1 and switching tube Q2.The first end of the first end of resistance R 1 and switching tube Q1 is connected to an end of 300V direct voltage, and the second end of resistance R 2 and the second end of switching tube Q2 are connected to the other end of 300V direct voltage.Resistance R 1, resistance R 2 are used for determining midpoint potential, and the voltage on assurance capacitor C 1 and capacitor C 2 is respectively half of Vdc, i.e. 1/2Vdc, approximately 150V direct voltage.High frequency transformer T1 has first side winding, the first secondary side winding and the second secondary side winding.Common node and the other end that one end of first side winding is electrically connected to resistance R 1 and resistance R 2 are connected to the second end of switching tube Q1 and the first end of switching tube Q2 via capacitor C 3.The secondary side circuit comprises diode D3, diode D4, flat ripple inductance L 1 and two filter capacitor C4 ~ C5, one end of anodic bonding to the first secondary side winding of diode D3 and negative electrode are connected to the first end of flat ripple inductance L 1, one end of anodic bonding to the second secondary side winding of diode D4 and negative electrode are connected to the first end of flat ripple inductance L 1, two filter capacitor C4 ~ C5 are connected in parallel, and the other end that the end of filter capacitor C4 ~ C5 is connected to the other end of flat ripple inductance L 1 and filter capacitor C4 ~ C5 is connected to the common end of the first secondary side winding and the second secondary side winding.

Fig. 3 illustrates the circuit diagram of the primary side of the DC/AC converter in the power amplifier of Fig. 1.With reference to Fig. 3, at the full-bridge converter duration of work, the two switching tubes conducting simultaneously on the full-bridge diagonal.For example, in front half period, switching tube Q6 and switching tube Q9 conducting simultaneously, this moment, switching tube Q7 and switching tube Q8 all were in cut-off state; In rear half period, switching tube Q7 and switching tube Q8 conducting simultaneously, this moment, switching tube Q6 and switching tube Q9 all were in cut-off state.The conduction period of each switching tube is less than half period, for example, when switching tube Q6 and switching tube Q9 conducting, switching tube Q7 and switching tube Q8 cut-off, input voltage Ui exports after the second-order low-pass filter that inductance L 6, capacitor C 6, inductance L 7, capacitor C 7 consist of.

More specifically, the circuit of this DC/AC converter can be described below.The primary side circuit of this full-bridge circuit comprises the first brachium pontis, the second brachium pontis and second-order low-pass filter.The first brachium pontis has switching tube Q6 and the switching tube Q7 that is connected in series, the first end of switching tube Q6 is connected to the end of input voltage Ui, the second end of switching tube Q7 is connected to the other end of input voltage Ui, and the second end of switching tube Q6 is electrically connected to the first end of switching tube Q7 and forms first node A.The second brachium pontis and the first brachium pontis are connected in parallel, and have the switching tube Q8 and the switching tube Q9 that are connected in series.The first end of switching tube Q8 is connected to the first end of switching tube Q6, and the second end of switching tube Q9 is connected to the second end of switching tube Q7, and the second end of switching tube Q8 is electrically connected to the first end of switching tube Q9 and forms Section Point B.

Second-order low-pass filter comprises inductance L 6, inductance L 7, capacitor C 6 and capacitor C 7.The first end of inductance L 6 is connected to first node A, the first end of capacitor C 1 is connected to the second end of inductance L 6 and the first end of inductance L 7, the second end of capacitor C 1 is connected to the second end of Section Point B and capacitor C 7, and the first end of capacitor C 7 is connected with the second end of inductance L 7.

In addition, also it should be noted that, switching tube Q6 and switching tube Q9 cut-off and switching tube Q7 and switching tube Q8 be not yet during conducting, two diodes afterflows simultaneously of Circuit Fault on Secondary Transformer full-wave rectification, and transformer secondary short circuit in winding, voltage are zero.

In addition, for guaranteeing the fail safe of test signal generation systems, the application also adopts the protective circuit of multiple protective design.This protective circuit mainly is divided into overvoltage crowbar and current foldback circuit.Overcurrent protection is respectively from half bridge portion and full-bridge Subsampling.Overvoltage protection is respectively from half-bridge output and high-voltage output end sampling.

Half-bridge circuit is the core of whole power amplification circuit, the success or failure whether stable relation arrives whole system of half-bridge output voltage.Because control ring adopts the voltage close loop regulative mode, the voltage-regulation of half-bridge circuit is ring in voltage-regulation.The PWM drive waveforms of the certain duty ratio of control circuit given first is to half-bridge circuit, so the corresponding dc voltage value of half-bridge circuit output is sent single-chip microcomputer back to through sample circuit, single-chip microcomputer is adjusted set-point according to measured value, thereby has realized the voltage close loop regulatory function.For avoiding control circuit to be subjected to the impact of power circuit fault, and improve certainty of measurement, but adopt the high-precision linear optocoupler HCNR200 of isolation mode analog signal to isolate in the application's a embodiment.Fig. 4 illustrates in the power amplifier of Fig. 1, to the half-bridge output voltage sample the isolation the optocoupler structure chart.This opto-coupler chip comprises a high performance LED, two photodiode PD1 and photodiode PD2 that made and have strict proportionate relationship by same process.The light that LED sends is received by photodiode PD1 and photodiode PD2, when using this opto-coupler chip, consisted of input circuit and formed negative-feedback circuit by LED and photodiode PD1, photodiode PD2 consists of spacing output circuit.Because input circuit is introduced negative feedback, thereby as long as LED and photodiode PD1 relation are definite, the importation is just stable.Because photodiode PD1 and photodiode PD2 relation are constant, so just can make output signal and input signal proportionate relationship stable again.

Use the half-bridge output voltage sampling isolation circuit of optocoupler HCNR200 design as shown in Figure 5.The half-bridge output dc voltage is 0V ~ 150V, and after divider resistance, input feedback circuit voltage Vi is 0 ~ 2V.When the Vi input voltage is 0, the inverting input of amplifier A1 is moved to earth potential by resistance R 1, when input voltage Vi increases gradually, the output of amplifier A1 will increase sharply, thereby the electric current that flows through LED will increase, and flow through the also corresponding increase of electric current of photodiode PD1, so the anti-phase input terminal potential of amplifier A1 will be lifted to almost and equate with Vi, two inputs are equivalent to imaginary short, and the voltage perseverance is 0, have realized the negative feedback regulatory function.And the transmission gain of optocoupler is almost 1, so the in-phase input end voltage of amplifier A2 almost equates with the anti-phase input terminal voltage of amplifier A1.The effect of amplifier A2 is mainly voltage follow, and 2 of resistance R 4 and capacitor C consist of high pass filter, thereby input voltage Vi almost is transferred to single-chip microcomputer linearly.Table 1 is experimental data.

Table 1

?	Vi	The LED anode voltage	The PD1 anode voltage	The PD2 anode voltage	Vo(V)
						1	0.0949	1.356	0.0996	0.0955	0.0982
2	0.297	1.392	0.2955	0.2932	0.2926
						3	0.509	1.410	0.506	0.493	0.502
4	0.706	1.421	0.704	0.686	0.698
						5	0.908	1.429	0.905	0.882	0.896
6	1.17	1.438	1.166	1.136	1.156
						7	1.352	1.443	1.349	1.315	1.338
8	1.515	1.447	1.511	1.473	1.499
						9	1.782	1.454	1.779	1.733	1.763
10	2.008	1.458	2.005	1.953	1.987

Take input voltage Vi as abscissa, output voltage V o is ordinate, uses the linearity curve of Matlab match as shown in Figure 6.As can be seen from Figure 6, the slope of straight line is almost 1, is also that output voltage has almost transmitted input voltage without distortion.Experimental result shows, this partial circuit reliable operation, and the linearity is good, meets designing requirement.Should note some in application, the one, input side and outlet side should be with two optocouplers, and should not use twin-channel optocoupler.The 2nd, equate in order to make output valve and input value, the value of resistance R 1 and resistance R 2 should equate and can not be too little.The 3rd, input voltage value can not surpass the difference of supply power voltage and light-emitting diode tube voltage drop.

The main method that detects electric current has direct series connection sample resistance method, current transformer method, Hall element method etc.In this application, low-pressure side partly comprises the overcurrent protection of half-bridge circuit output current and full-bridge circuit output current, all adopts the current transformer method to detect, as shown in Figure 7.

Current transformer is selected Switching Power Supply current mutual inductor special TAK12, and its no-load voltage ratio is 200:1, and input current 20A, output current 100mA, nonlinearity be less than or equal to 2%, 6000 volts of dielectric strengths, and operating frequency is up to 200kHz.The operation principle of circuit is, the AC signal that sampling resistor R1 by 25 Ω records instrument transformer is converted to the alternating voltage signal, the d. c. voltage signal that obtains pulsing through full bridge rectifier, more just obtained metastable d. c. voltage signal through flat wave capacitor device C1.Amplifier A1 is voltage follower, and resistance R 3 consists of high pass filter with 2 of capacitor C, so that issuable spike in circuit is suppressed.Amplifier A2 plays voltage ratio and acts on.When circuit generation overcurrent; the in-phase input end voltage of amplifier A2 will be over the reference voltage base Vref of inverting input; so amplifier output switching activity; this guard signal divides makes two-way; one the tunnel is sent to CPLD(Complex Programmable Logic Device; CPLD) block immediately all output pwm control signals, another road is sent to single-chip microcomputer and is done the processing such as fault alarm.Because half-bridge circuit is different with the full-bridge circuit output current, so the reference voltage of two-way protective circuit is different.

Adopt the power amplifier for the intelligent substation test macro of the present utility model, can improve the efficient of power amplifier, and increase the power density of power amplifier.In addition, this power amplifier also can arrange the multiple protective design of overcurrent protection and overvoltage protection, stability and fail safe during with the operation of assurance system.

Although above-mentionedly by reference to the accompanying drawings embodiment of the present utility model is described; but be not the restriction to the utility model protection range; on the basis of the technical solution of the utility model, those skilled in the art do not need to pay various modifications that creative work can make or distortion still in protection range of the present utility model.

Claims (8)

1. power amplifier that is used for the intelligent substation test macro, it is characterized in that, comprise Power Entry Module for the alternating voltage of output 220V, be used for the 220V ac voltage rectifier be the direct voltage of 300V rectifier bridge, be used for direct voltage with 300V be converted to 1V ~ 150V direct voltage the DC/DC converter and be used for reference signal is carried out the DC/AC converter of power amplification output, four connect in turn.

2. a kind of power amplifier for the intelligent substation test macro according to claim 1, is characterized in that, described DC/DC converter is a semi-bridge alternation circuit.

3. a kind of power amplifier for the intelligent substation test macro according to claim 2, is characterized in that, described semi-bridge alternation circuit comprises:

The primary side circuit, comprise resistance R 1, resistance R 2, switching tube Q1 and switching tube Q2, wherein, the first end of the first end of described resistance R 1 and described switching tube Q1 is connected to an end of 300V direct voltage, and the second end of described resistance R 2 and the second end of described switching tube Q2 are connected to the other end of 300V direct voltage;

High frequency transformer, have first side winding, the first secondary side winding and the second secondary side winding, common node and the other end that an end of described first side winding is electrically connected to described resistance R 1 and resistance R 2 are connected to the second end of described switching tube Q1 and the first end of described switching tube Q2 via capacitor C 3; And

the secondary side circuit, comprise diode D3, diode D4, flat ripple inductance L 1 and two filter capacitor C4, C5, one end of anodic bonding to the first secondary side winding of diode D3 and negative electrode are connected to the first end of described flat ripple inductance L 1, one end of anodic bonding to the second secondary side winding of diode D4 and negative electrode are connected to the first end of described flat ripple inductance L 1, two filter capacitor C4 ~ C5 are connected in parallel, the other end that the end of filter capacitor C4 ~ C5 is connected to the other end of described flat ripple inductance L 1 and filter capacitor C4 ~ C5 is connected to the common end of the first secondary side winding and the second secondary side winding.

4. a kind of power amplifier for the intelligent substation test macro according to claim 3, is characterized in that, described diode D3 and diode D4 are fast recovery rectifier diode.

5. a kind of power amplifier for the intelligent substation test macro according to claim 1, is characterized in that, described DC/AC converter is a full-bridge circuit.

6. a kind of power amplifier for the intelligent substation test macro according to claim 5, is characterized in that, described full-bridge circuit comprises:

The first brachium pontis, have the switching tube Q6 and the switching tube Q7 that are connected in series, the first end of described switching tube Q6 is connected to an end of described input voltage, the second end of described switching tube Q7 is connected to the other end of described input voltage, and the second end of described switching tube Q6 is electrically connected to the first end of described switching tube Q7 and forms first node A;

The second brachium pontis, be connected in parallel with described the first brachium pontis, have the switching tube Q8 and the switching tube Q9 that are connected in series, the first end of described switching tube Q8 is connected to the first end of described switching tube Q6, the second end of described switching tube Q9 is connected to the second end of described switching tube Q7, and the second end of described switching tube Q8 is electrically connected to the first end of described switching tube Q9 and forms Section Point B; And

Second-order low-pass filter, comprise inductance L 6, inductance L 7, capacitor C 6 and capacitor C 7, wherein, the first end of described inductance L 6 is connected to described first node A, the first end of described capacitor C 6 is connected to the second end of described inductance L 6 and the first end of described inductance L 7, the second end of described capacitor C 6 is connected to the second end of described Section Point B and described capacitor C 7, and the first end of described capacitor C 7 is connected with the second end of described inductance L 7.

7. a kind of power amplifier for the intelligent substation test macro according to claim 6, is characterized in that, when switching tube Q6 and switching tube Q9 conducting, and described switching tube Q7 and switching tube Q8 cut-off; When described switching tube Q7 and switching tube Q8 conducting, described switching tube Q6 and switching tube Q9 cut-off.

8. a kind of power amplifier for the intelligent substation test macro according to claim 1; it is characterized in that, described power amplifier also comprises overvoltage crowbar and the current foldback circuit that the output voltage of DC/DC converter and output current are detected respectively and protect.

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