CN101154895A - Five-power level non-harmonic switching network topological circuit of variable reference stacking technology - Google Patents

Abstract

The present invention relates to a five-level perfect no-harmonic switching network topological circuit in the reference-variable stacking technique, which belongs to the main body part of the frequency-converting pressure-regulating equipment that is used for the high-power and high-pressure AC motor. The invention mainly settles the technical difficulties of hugeous system, high fabricating cost and low economic benefit in the existing multiplex technique. The technical scheme adapted by the invention for settling the problems is as follows: the five-level perfect no-harmonic switching network topological circuit in the reference-variable stacking technique, is composed of three single-phase switching network topological circuits, and each phase switching network topological circuit is composed of 18 diodes D1 to 18, 10 insulated gate double pole triodes IGBT1 to 10, the resistors of R1 and R2, and the capacitances of C1 and C2. The invention has the advantages of simple structure, low fabricating cost and convenient controlling.

Description

Five level perfect harmony switching network topological circuits of variable reference superimposing technique

Technical field

The present invention relates to a kind of five level perfect harmony switching network topological circuits of variable reference superimposing technique, it belongs to a kind of main part that is mainly used in the frequency conversion voltage adjusting device of high-power, high voltage alternating current machine.

Background technology

Development along with power electric component and control system structure, but silicon controlled rectifier (GTO) as shutoff door, insulated gate bipolar triode (IGBT), reinforced insulated gate bipolar triode (IGET), but the exploitation of the silicon controlled rectifier of reinforced shutoff door (IGCT) and the development of converter technique version and control technology make the high voltage large capcity frequency conversion voltage adjusting device be applied in rapidly in the middle of electric power system and the industrial system.

What frequency conversion equipment at first experienced is the control unit of original two level output.As shown in Figure 1.But because which kind of control mode no matter the output of two level adopt, even pulse width modulation (PWM) control mode of optimizing all is difficult to make output waveform approaching sinusoidal wave to reach perfect harmony.Then the output waveform distortion is remarkable when frequency converter operates in low frequency.So the connection in series-parallel quantity that the people that are engaged in this area research expect increasing by two level modules naturally is in the hope of reaching many level outputs, thereby make output waveform near sinusoidal wave, such technology is called as multiple technology.As shown in Figure 2.From the exportable waveform ((a) A1-A5 among Fig. 3) of Fig. 2 A each module mutually by pulse width modulation (PWM) control.The waveform stack of (a) A1-A5 among Fig. 3 can be obtained the waveform (among Fig. 3 (b)) of the final multiple technology output of A phase.

Multiple technology is on the basis of original two level control technologys, and a plurality of components and parts of connection in series-parallel form.When components and parts were connected in parallel, output voltage will satisfy the requirement that components and parts bear voltage, and the caused problem of this connected mode combines with the current equalizer of complexity, and the complexity of circuit usually easily causes the damage of element.For the connected mode of series connection components and parts, output current will satisfy the ability to bear requirement of components and parts equally, will guarantee that more it is distributed in voltage on the components and parts and under any circumstance all wants balanced, so the also fault of easy generation systems usually.Therefore, from the angle of system reliability, they all are difficult to the reliability service of assurance system.Owing to the control system complexity, output waveform is also relatively poor, usually causes more serious each harmonic simultaneously.In addition, the dynamic electric resistor of connection in series-parallel device is different with electrode capacitance also can to make the control circuit complexity, and loss increases.The series connection of device simultaneously also improves greatly to the requirement of circuits for triggering.The device of will as far as possible accomplishing to connect conducting simultaneously or disconnection, otherwise, because each device switch off time differs, bear the voltage inequality, can cause device failure, even the collapse of whole device.

In addition, the high-power high voltage frequency conversion voltage adjusting device that manufactures and designs based on multipleization method is difficult for solving the problem that current-sharing is all pressed, so can produce significant each harmonic in equipment and system.Harmonic wave can pollute electrical network, brings disaster to other power consumption equipment on the same electrical network, even influences the normal operation of electric power system.Harmonic wave also can interference communications and control system, can make communicating interrupt, systemic breakdown when serious.Harmonic current also can make generator loss increase, thereby heating increases efficient and power factor decline.

At last, because the every analogue unit of multiple technology needs 4 switch elements at least, and every analogue unit needs independently phase shifting transformer power supply, so if pursue many level output waveform, naturally need to increase the quantity of number of switches and analogue unit, and then make the control system software and hardware complicated more, thereby cause whole system huge, the cost height, economic benefit is low.

Summary of the invention

The objective of the invention is to solve above-mentioned technological difficulties and provide a kind of simple in structure, insulated gate bipolar triode quantity is few, five level perfect harmony switching network topological circuits of the variable reference superimposing technique that is easy to control.

The present invention addresses the above problem the technical scheme that adopts to be: five level perfect harmony switching network topological circuits of variable reference superimposing technique, it is made up of three single-phase switching network topological circuits at least, and every phase switching network topological circuit is made of insulated gate bipolar triode IGBT1～10,18 diode D1～18,10, resistance R 1, R2 and capacitor C 1, C2; Insulated gate bipolar triode IGBT1,2,3 and 4 are connected in series, insulated gate bipolar triode IGBT5,6,7 and 8 are connected in series, the collector electrode of insulated gate bipolar triode IGBT1 in above-mentioned two series circuits is connected in parallel with the collector electrode of insulated gate bipolar triode IGBT5 and then is connected with the emitter of insulated gate bipolar triode IGBT9, the emitter of insulated gate bipolar triode IGBT4 is connected in parallel with the emitter of insulated gate bipolar triode IGBT8 and then is connected with the collector electrode of insulated gate bipolar triode IGBT10, diode D17, the negative pole of D18 series connection back its diode D17 is connected with the collector electrode of insulated gate bipolar triode IGBT6, the positive pole of diode D18 is connected with the collector electrode of insulated gate bipolar triode IGBT8, diode D15, the negative pole of D16 series connection back its diode D15 is connected with the collector electrode of insulated gate bipolar triode IGBT2, and the positive pole of diode D16 is connected with the collector electrode of insulated gate bipolar triode IGBT4; Capacitor C 1, the positive pole of C2 series connection back capacitor C 1 is connected with the emitter of insulated gate bipolar triode IGBT9, the negative pole of capacitor C 2 is connected with the collector electrode of insulated gate bipolar triode IGBT10, resistance R 1, one end of R2 series connection back resistance R 1 is connected with the emitter of insulated gate bipolar triode IGBT9, the other end of resistance R 2 is connected with the collector electrode of insulated gate bipolar triode IGBT10, diode D13 is connected with the emitter of insulated gate bipolar triode IGBT9 with the negative pole of diode D14 series connection back diode D13, and the positive pole of diode D14 is connected with the collector electrode of insulated gate bipolar triode IGBT10; Form three-phase commutation bridge by diode D1, D2, D3, D4, D5 and D6, diode D1 and D4 are connected in series, diode D2 and D5 are connected in series, diode D3 and D6 are connected in series, then, collector electrode with insulated gate bipolar triode IGBT9 after the negative pole parallel connection of the negative pole of the negative pole of diode D1, diode D2 and diode D3 is connected, and the back anodal in parallel of the positive pole of the positive pole of diode D1, diode D2 and diode D3 is connected with center line; Form another three-phase commutation bridge by diode D7, D8, D9, D10, D11 and D12, diode D7 and D10 are connected in series, diode D8 and D11 are connected in series, diode D9 and D12 are connected in series, then, the anodal in parallel back of the positive pole of the positive pole of diode D10, diode D11 and diode D12 is connected with the emitter of insulated gate bipolar triode IGBT10, is connected with center line after the negative pole of the negative pole of diode D7, diode D8 and the negative pole parallel connection of diode D9; The positive pole of diode D13 is connected with center line with the tie point of the negative pole of diode D14, the tie point of the negative pole of capacitor C 1 and the positive pole of capacitor C 2 is connected with center line, the tie point of resistance R 1 and resistance R 2 is connected with center line, the positive pole of diode D15 is connected with center line with the tie point of the negative pole of diode D16, and the positive pole of diode D17 is connected with center line with the tie point of the negative pole of diode D18; The emitter of insulated gate bipolar triode IGBT2 is connected with the public center line of three-phase with the tie point of the collector electrode of insulated gate bipolar triode IGBT3, and the emitter of insulated gate bipolar triode IGBT6 is connected with the U of motor with the tie point of the collector electrode of insulated gate bipolar triode IGBT7; The collector electrode of the negative pole of the negative pole of the negative pole of diode D1, diode D2, diode D3 and insulated gate bipolar triode IGBT9 links to each other with the positive pole+E of DC power supply, and the emitter of the positive pole of the positive pole of diode D10, diode D11, the positive pole of diode D12 and insulated gate bipolar triode IGBT10 links to each other with the negative pole-E of DC power supply.

Because the present invention has adopted the technical scheme of the form of said structure, therefore, compares with background technology, has following beneficial effect.

(1) the present invention utilizes the combination of low-voltage, low power insulated gate bipolar triode IGBT switch to realize the switching network topological circuit of high-power high voltage frequency conversion voltage adjusting device.

(2) output voltage waveforms of the present invention is five level perfect harmonies, and every index of its overall percent harmonic distortion (THD) all satisfies the requirement of IEEE 519-1992.

(3) circuit of the present invention is easy to control, and available pulse width modulation (PWM) control mode goes the reactive power of the system that finishes to distribute, and then reaches and make the system power factor be tending towards 1 purpose.

(4) in like manner, control the combination of switch of the present invention, and then control current/voltage, make it present various waveforms, start the needs of loading, thereby reach the motor soft start function under various load conditions to satisfy to the motor input.

(5) multiple inverter configuration with system compares, and multipleization method needs 4 two level modules if will export five level waveforms, and every module needs 4 switches at least, so every phase needs 4*4=16 insulated gate bipolar triode IGBT switch at least.And network topology circuit of the present invention has been owing to adopted superimposing technique, and every phase only needs 8 switches.For guaranteeing still exportable five level voltage waveforms when low-frequency and low-voltage moves, need add 2 IGBT switches again as DC chopper, like this, add has 10 switches together.Can save a large amount of expenses.

(6) multiple technology not only needs number of switches many, and the phase shifting transformer power supply that every module also need be independent, so the present invention compares with it, simple in structure, the cost expense is low, and is convenient to control.

Description of drawings

Fig. 1 is 4 switch modules that are used for the exportable two level waveforms of multipleization;

Fig. 2 is the multiple technology connection diagram of the exportable six level waveforms that are composed in series of five modules;

Fig. 3 is each module output waveform of multiple technology and final overlaid waveforms schematic diagram;

Fig. 4 is a switch topology circuit schematic diagram of the present invention;

Fig. 5 is that the present invention exports the five-level switch magnetic operation chart;

Fig. 6 is that the present invention exports five level waveform schematic diagram when four level land;

Fig. 7 is that the present invention exports four level waveform schematic diagram when three level land.

Embodiment

The present invention is described in further detail below in conjunction with drawings and Examples.

As shown in Figure 4, five level perfect harmony switching network topological circuits of the variable reference superimposing technique in the present embodiment, it is made up of three single-phase switching network topological circuits, and U phase switching network topological circuit is made of insulated gate bipolar triode IGBT1～10,18 diode D1～18,10, resistance R 1, R2 and capacitor C 1, C2; Insulated gate bipolar triode IGBT1,2,3 and 4 are connected in series, insulated gate bipolar triode IGBT5,6,7 and 8 are connected in series, the collector electrode of insulated gate bipolar triode IGBT1 in above-mentioned two series circuits is connected in parallel with the collector electrode of insulated gate bipolar triode IGBT5 and then is connected with the emitter of insulated gate bipolar triode IGBT9, the emitter of insulated gate bipolar triode IGBT4 is connected in parallel with the emitter of insulated gate bipolar triode IGBT8 and then is connected with the collector electrode of insulated gate bipolar triode IGBT10, diode D17, the negative pole of D18 series connection back its diode D17 is connected with the collector electrode of insulated gate bipolar triode IGBT6, the positive pole of diode D18 is connected with the collector electrode of insulated gate bipolar triode IGBT8, diode D15, the negative pole of D16 series connection back its diode D15 is connected with the collector electrode of insulated gate bipolar triode IGBT2, and the positive pole of diode D16 is connected with the collector electrode of insulated gate bipolar triode IGBT4; Capacitor C 1, the positive pole of C2 series connection back capacitor C 1 is connected with the emitter of insulated gate bipolar triode IGBT9, the negative pole of capacitor C 2 is connected with the collector electrode of insulated gate bipolar triode IGBT10, resistance R 1, one end of R2 series connection back resistance R 1 is connected with the emitter of insulated gate bipolar triode IGBT9, the other end of resistance R 2 is connected with the collector electrode of insulated gate bipolar triode IGBT10, diode D13 is connected with the emitter of insulated gate bipolar triode IGBT9 with the negative pole of diode D14 series connection back diode D13, and the positive pole of diode D14 is connected with the collector electrode of insulated gate bipolar triode IGBT10; Form three-phase commutation bridge by diode D1, D2, D3, D4, D5 and D6, diode D1 and D4 are connected in series, diode D2 and D5 are connected in series, diode D3 and D6 are connected in series, then, collector electrode with insulated gate bipolar triode IGBT9 after the negative pole parallel connection of the negative pole of the negative pole of diode D1, diode D2 and diode D3 is connected, and the back anodal in parallel of the positive pole of the positive pole of diode D1, diode D2 and diode D3 is connected with center line; Form another three-phase commutation bridge by diode D7, D8, D9, D10, D11 and D12, diode D7 and D10 are connected in series, diode D8 and D11 are connected in series, diode D9 and D12 are connected in series, then, the anodal in parallel back of the positive pole of the positive pole of diode D10, diode D11 and diode D12 is connected with the emitter of insulated gate bipolar triode IGBT10, is connected with center line after the negative pole of the negative pole of diode D7, diode D8 and the negative pole parallel connection of diode D9; The positive pole of diode D13 is connected with center line with the tie point of the negative pole of diode D14, the tie point of the negative pole of capacitor C 1 and the positive pole of capacitor C 2 is connected with center line, the tie point of resistance R 1 and resistance R 2 is connected with center line, the positive pole of diode D15 is connected with center line with the tie point of the negative pole of diode D16, and the positive pole of diode D17 is connected with center line with the tie point of the negative pole of diode D18; The emitter of insulated gate bipolar triode IGBT2 is connected with the public center line of three-phase with the tie point of the collector electrode of insulated gate bipolar triode IGBT3, and the emitter of insulated gate bipolar triode IGBT6 is connected with the U of motor with the tie point of the collector electrode of insulated gate bipolar triode IGBT7; The collector electrode of the negative pole of the negative pole of the negative pole of diode D1, diode D2, diode D3 and insulated gate bipolar triode IGBT9 links to each other with the positive pole+E of DC power supply, and the emitter of the positive pole of the positive pole of diode D10, diode D11, the positive pole of diode D12 and insulated gate bipolar triode IGBT10 links to each other with the negative pole-E of DC power supply.The V of switching network topological circuit is identical with U switching network topological circuit mutually with W all components and parts and connected mode mutually mutually.T1, T2 are the secondary coils of isolating transformer among the figure, and it act as to corresponding diode rectifier bridge power supply.

Insulated gate bipolar triode IGBT1 in the foregoing circuit, 5,4,8 is as pulse width modulation (PWM) control action, insulated gate bipolar triode IGBT2,3,6,7 is clamping diode as the level superposition with diode D15, D16, D17, the D18 of its corresponding connection.

Switch operation principle of the present invention is: as shown in Figure 5, when mutually switch (insulated gate bipolar triode IGBT) 2,7,8 conductings of switch (the insulated gate bipolar triode IGBT) 3,4 and 5,6 of U phase and V, when on the switch (insulated gate bipolar triode IGBT) 1 of V phase, applying pulse width modulation (PWM) signal, will produce five level signals as shown in Figure 6.

As shown in Figure 5, when mutually switch (insulated gate bipolar triode IGBT) 2,7 conductings of switch (the insulated gate bipolar triode IGBT) 3,4 and 5,6 of U phase and V, when on the switch (insulated gate bipolar triode IGBT) 1 of V phase, applying pulse width modulation (PWM) signal, will produce four level signals as shown in Figure 7.

According to above-mentioned principle, cooperate different on off states, can produce 0, E, 2E, 3E, five level signals of 4E.On each level step, can simulate the waveform of this section, thereby can form the comparison perfect sine wave according to pulse width modulation (PWM) signal of distinct pulse widths again.

In the time need regulating to the size of output voltage.Pulse width modulation (PWM) pulse duration of chopping switch (insulated gate bipolar triode IGBT9,10) that can be by regulating each phase is regulated.When carrying out the copped wave operation, diode D13, D14 and resistance R 1, R2 play the afterflow effect, and capacitor C 1, C2 play filtering and pressure stabilization function.

Claims (1)

1. five level perfect harmony switching network topological circuits of a variable reference superimposing technique, it is characterized in that: it is made up of three single-phase switching network topological circuits at least, and every phase switching network topological circuit is made of insulated gate bipolar triode IGBT1～10,18 diode D1～18,10, resistance R 1, R2 and capacitor C 1, C2; Insulated gate bipolar triode IGBT1,2,3 and 4 are connected in series, insulated gate bipolar triode IGBT5,6,7 and 8 are connected in series, the collector electrode of insulated gate bipolar triode IGBT1 in above-mentioned two series circuits is connected in parallel with the collector electrode of insulated gate bipolar triode IGBT5 and then is connected with the emitter of insulated gate bipolar triode IGBT9, the emitter of insulated gate bipolar triode IGBT4 is connected in parallel with the emitter of insulated gate bipolar triode IGBT8 and then is connected with the collector electrode of insulated gate bipolar triode IGBT10, diode D17, the negative pole of D18 series connection back its diode D17 is connected with the collector electrode of insulated gate bipolar triode IGBT6, the positive pole of diode D18 is connected with the collector electrode of insulated gate bipolar triode IGBT8, diode D15, the negative pole of D16 series connection back its diode D15 is connected with the collector electrode of insulated gate bipolar triode IGBT2, and the positive pole of diode D16 is connected with the collector electrode of insulated gate bipolar triode IGBT4; Capacitor C 1, the positive pole of C2 series connection back capacitor C 1 is connected with the emitter of insulated gate bipolar triode IGBT9, the negative pole of capacitor C 2 is connected with the collector electrode of insulated gate bipolar triode IGBT10, resistance R 1, one end of R2 series connection back resistance R 1 is connected with the emitter of insulated gate bipolar triode IGBT9, the other end of resistance R 2 is connected with the collector electrode of insulated gate bipolar triode IGBT10, diode D13 is connected with the emitter of insulated gate bipolar triode IGBT9 with the negative pole of diode D14 series connection back diode D13, and the positive pole of diode D14 is connected with the collector electrode of insulated gate bipolar triode IGBT10; Form three-phase commutation bridge by diode D1, D2, D3, D4, D5 and D6, diode D1 and D4 are connected in series, diode D2 and D5 are connected in series, diode D3 and D6 are connected in series, then, collector electrode with insulated gate bipolar triode IGBT9 after the negative pole parallel connection of the negative pole of the negative pole of diode D1, diode D2 and diode D3 is connected, and the back anodal in parallel of the positive pole of the positive pole of diode D1, diode D2 and diode D3 is connected with center line; Form another three-phase commutation bridge by diode D7, D8, D9, D10, D11 and D12, diode D7 and D10 are connected in series, diode D8 and D11 are connected in series, diode D9 and D12 are connected in series, then, the anodal in parallel back of the positive pole of the positive pole of diode D10, diode D11 and diode D12 is connected with the emitter of insulated gate bipolar triode IGBT10, is connected with center line after the negative pole of the negative pole of diode D7, diode D8 and the negative pole parallel connection of diode D9; The positive pole of diode D13 is connected with center line with the tie point of the negative pole of diode D14, the tie point of the negative pole of capacitor C 1 and the positive pole of capacitor C 2 is connected with center line, the tie point of resistance R 1 and resistance R 2 is connected with center line, the positive pole of diode D15 is connected with center line with the tie point of the negative pole of diode D16, and the positive pole of diode D17 is connected with center line with the tie point of the negative pole of diode D18; The emitter of insulated gate bipolar triode IGBT2 is connected with the public center line of three-phase with the tie point of the collector electrode of insulated gate bipolar triode IGBT3, and the emitter of insulated gate bipolar triode IGBT6 is connected with the U of motor with the tie point of the collector electrode of insulated gate bipolar triode IGBT7; The collector electrode of the negative pole of the negative pole of the negative pole of diode D1, diode D2, diode D3 and insulated gate bipolar triode IGBT9 links to each other with the positive pole+E of DC power supply, and the emitter of the positive pole of the positive pole of diode D10, diode D11, the positive pole of diode D12 and insulated gate bipolar triode IGBT10 links to each other with the negative pole-E of DC power supply.

Images