CN108599593A - One kind is from the high boost rectifier of current-sharing module large capacity - Google Patents

Abstract

The present invention proposes a kind of from the high boost rectifier of current-sharing module large capacity.Being closed in traditional large capacity promotion repoussage flow field often needs multiple rectification module parallel runnings and transformer to boost, there are power between multiple modules to be unevenly distributed, system reliability is poor, problem of high cost, thus the present invention propose it is a kind of can the large capacity of automatic current equalizing and rectifier output voltage adjustable gain section, modularization, high-gain rectifier.Carried converter includes m（It must be even number）, first module be made of 1 capacitance of n and diode, and other modules are made of n capacitance and diode, compared to currently existing scheme, its number of modules is freely adjustable, and each module can automatic current equalizing, be relatively applicable to the large capacity high-gain rectification occasion of electrical isolation.

Description

One kind is from the high boost rectifier of current-sharing module large capacity

Technical field

It is specifically a kind of from current-sharing module large capacity the present invention relates to a kind of large capacity, high boosting non-isolation type stream device High boost rectifier.

Background technology

Traditional voltage doubling rectifing circuit, though higher voltage output, typically just input and output on the one hand may be implemented Adjustable gain, and device current stress is high and non-adjustable, so in large capacity application scenario parts selection difficulty, on the other hand often Multiple rectification module parallel runnings are needed to increase its capacity, then power is unevenly distributed between there are multiple modules, and system is reliable Property poor, the problems such as stream is difficult.

Invention content

To solve deficiency of the existing rectifier in large capacity height boosts application scenario, the present invention proposes that one kind can automatically Stream, voltage gain height and adjustable large capacity non-isolation type rectifier.

The present invention adopts the following technical scheme that：

One kind includes an input AC source from the high boost rectifier of current-sharing module large capacity, the converter, and m (must be Even number) a module, output diode D₀, filter capacitor C₀, load R_L；

Wherein m module includes：

Module one includes diode D_{1 2}、D_{1 3}···D_1n, capacitance C_{1 2}、C_{1 3}···C_1n.Capacitance C_{1 2}、C_{1 3}···C_1nThe other end be connected, then link together with power supply one end, at the same with diode D_{2 1}Anode and filtered electrical Hold C₀, load R_LThe other end be connected, diode D_{1 2}Cathode and capacitance C_{1 2}One end be connected, diode D_{1 3}Cathode with Capacitance C_{1 3}One end be connected ..., and so on diode D_1nCathode and capacitance C_1nOne end be connected.

Module two includes diode D_{2 1}、D_{2 2}···D_2n, capacitance C_{2 1}、C_{2 2}···C_2n.Capacitance C_{2 1}、C_{2 2}···C_2nThe other end be connected, then link together with the power supply other end, diode D_{2 1}Cathode and capacitance C_{2 1}'s One end is connected, diode D_{2 2}Cathode and capacitance C_{2 2}One end be connected ..., and so on diode D_2nCathode and capacitance C_2nOne end be connected.

Module three includes diode D_{3 1}、D_{3 2}···D_3n, capacitance C_{3 1}、C_{3 2}···C_3n.Capacitance C_{3 1}、C_{3 2}···C_3nThe other end be connected, then link together with power supply one end, diode D_{3 1}Cathode and capacitance C_{3 1}One End is connected, diode D₃₂Cathode and capacitance C_{3 2}One end be connected ..., and so on diode D_3nCathode and capacitance C_3n One end be connected.

And so on, module m-1 includes diode D_{m-1 1}、D_{m-1 2}···D_m-1n, capacitance C_{m-1 1}、C_{m-1 2}··· C_m-1n.Capacitance C_{m-1 1}、C_{m-1 2}···C_m-1nThe other end be connected, then link together with power supply one end, diode D_{m-1 1} Cathode and capacitance C_{m-1 1}One end be connected, diode D_{m-1 2}Cathode and capacitance C_{m-1 2}One end be connected ..., with such Push away diode D_m-1nCathode and capacitance C_m-1nOne end be connected.

Module m includes diode D_{m 1}、D_{m 2}···D_{m n}, capacitance C_{m 1}、C_{m 2}···C_{m n}.Capacitance C_{m 1}、C_{m 2}···C_{m n}The other end be connected, then link together with the other end of power supply, diode D_{m 1}Cathode and capacitance C_{m 1} One end be connected, diode D_{m 2}Cathode and capacitance C_{m 2}One end be connected ..., and so on diode D_{m n}Cathode with Capacitance C_{m n}One end be connected.Diode D_{m n}Cathode and capacitance C_{m n}One end between node and diode D₀Anode phase Even.

Connection relation between module and module and power supply and module is：

Capacitance C in first module_{1 2}The other end and power supply one end between node and second module in diode D_{2 1}Anode be connected, diode D in first module_{1 2}Cathode and C_{1 2}Diode D in node connection module two between one end_{2 2} Anode, diode D in first module_{1 3}Cathode and C_{1 3}Diode D in node connection module two between one end_{2 3}Sun Pole ..., and so on, diode D in first module_1nCathode and capacitance C_1nTwo in node connection module two between one end Pole pipe D_2nAnode.

Diode D in second module_{2 1}Cathode and C_{2 1}Diode D in node connection module three between one end_{3 1}Sun Pole, diode D in second module_{2 2}Cathode and C_{2 2}Diode D in node connection module three between one end_{3 2}Anode ..., And so on, diode D in second module_2nCathode and C_2nDiode D in node connection module three between one end_3nAnode.

And so on, diode D in the m-1 module_{m-1 1}Cathode and capacitance C_{m-1 1}Node connection module m between one end Middle diode D_{m 1}Anode, diode D in the m-1 module_{m-1 2}Cathode and capacitance C_{m-1 2}Node connection module between one end Diode D in m_{m 2}Anode ..., and so on, diode D in the m-1 module_m-1nCathode and capacitance C_m-1nOne end it Between node connection module m in diode D_{m n}Anode.

Diode D in m-th of module_{m 1}Cathode and capacitance C_{m 1}Diode D in node connection module one between one end_{1 2}'s Anode, diode D in m-th of module_{m 2}Cathode and capacitance C_{m 2}Diode D in node connection module one between one end_{1 3}Sun Pole ..., and so on, diode D in m-th of module_{m n-1}Cathode and capacitance C_{m n-1}In node connection module one between one end Diode D_1nAnode.

Load R_LWith C₀Parallel connection loads R_LOne terminating diode D₀Cathode, it is another to terminate to capacitance C in module one_{1 2}Separately Node between one end and power supply one end.Diode D₀Anode and diode D_{m n}Cathode and capacitance C_{m n}One end between Node is connected.Even number module is connected with the other end of power supply, and odd number module is connected with one end of power supply.

For one kind of the invention from the high boost rectifier of current-sharing module large capacity, technique effect is as follows：

1, input and output high gain and adjustable, switching device voltage current stress is low and adjustable.Wherein：

The ratio of output voltage and input voltage is (zero load)：

The voltage stress of diode is：

M is the input number of phases, and n is mould diode in the block and capacitance quantity.

2, each module can realize automatic current equalizing, the power-sharing of transformer.

3, large-scale Industrial Frequency Transformer is eliminated, system bulk and cost are reduced.

Description of the drawings

Fig. 1 is circuit theory total figure of the present invention.

Fig. 2 is m=4 of the present invention, the circuit topology figure of n=2.

Fig. 3 is input and output voltage oscillogram of the present invention.

Fig. 4 is diode D of the present invention₂₁、D₃₁、D₄₁、D_{1 2}Voltage oscillogram.

Fig. 5 is diode D of the present invention₂₁、D₃₁、D₄₁、D_{1 2}Current waveform figure.

Fig. 6 is capacitance C of the present invention₂₁~C₄₂Voltage oscillogram.

Fig. 7 is the simulation waveform of four blocks currents of the invention.

Specific implementation mode

Invention is further described in detail below in conjunction with the accompanying drawings.

As shown in Fig. 2, a kind of from the high boost rectifier of current-sharing module large capacity, it includes an input AC source, 4 Module, 8 capacitance C₀、C_{2 1}、C_{3 1}、C_{4 1}、C_{1 2}、C_{2 2}、C_{3 2}、C_{4 2}, 8 diode D₀、D_{2 1}、D_{3 1}、D_{4 1}、D_{1 2}、D_{2 2}、D_{3 2}、D_{4 2}, a load R_L.Wherein：

In 4 modules：

Module one includes diode D_{1 2}, capacitance C_{1 2}.Capacitance C_{1 2}The other end link together with power supply one end, simultaneously With diode D_{2 1}Anode and filter capacitor C₀, load R_LThe other end be connected, diode D_{1 2}Cathode and capacitance C_{1 2}One End is connected.

Module two includes diode D_{2 1}、D_{2 2}, capacitance C_{2 1}、C_{2 2}.Capacitance C_{2 1}、C_{2 2}The other end be connected, then with The power supply other end links together, diode D_{2 1}Cathode and capacitance C_{2 1}One end be connected, diode D_{2 2}Cathode with electricity Hold C_{2 2}One end be connected.

Module three includes diode D_{3 1}、D_{3 2}, capacitance C_{3 1}、C_{3 2}.Capacitance C_{3 1}、C_{3 2}Other end phase, even then with Power supply one end links together, diode D_{3 1}Cathode and capacitance C_{3 1}One end be connected, diode D_{3 2}Cathode and capacitance C_{3 2}One end be connected.

Module four includes diode D_{4 1}、D_{4 2}, capacitance C_{4 1}、C_{4 2}.Capacitance C_{4 1}、C_{4 2}The other end be connected, then with Power supply one end links together, diode D_{4 1}Cathode and capacitance C_{4 1}One end be connected, diode D_{4 2}Cathode and capacitance C_{4 2}One end be connected.Diode D_{4 2}Cathode and capacitance C_{4 2}One end between node and diode D₀Anode be connected.

Connection relation between module and module and power supply and module is：

Capacitance C in first module_{1 2}The other end and power supply one end between node and second module in diode D_{2 1}Anode be connected, diode D in first module_{1 2}Cathode and C_{1 2}Diode D in node connection module two between one end_{2 2} Anode,

Diode D in second module_{2 1}Cathode and C_{2 1}Diode D in node connection module three between one end_{3 1}Sun Pole, diode D in second module_{2 2}Cathode and C_{2 2}Diode D in node connection module three between one end_{3 2}Anode.

Diode D in third module_{3 1}Cathode and capacitance C_{3 1}Diode D in node connection module four between one end_{4 1} Anode, diode D in third module_{3 2}Cathode and capacitance C_{3 2}Diode D in node connection module four between one end_{4 2}'s Anode.

Diode D in 4th module_{4 1}Cathode and capacitance C_{4 1}Diode D in node connection module one between one end_{1 2} Anode.

Load R_LWith C₀Parallel connection loads R_LOne terminating diode D₀Cathode, it is another to terminate to capacitance C in module one_{1 2}Separately Node between one end and power supply one end.Diode D₀Anode and diode D_{4 2}Cathode and capacitance C_{4 2}One end between Node is connected.Module one, module three are connected with one end of power supply, and module two, module four are connected with one end of power supply.

It is different according to AC power current direction, circuit can be divided into two kinds of working conditions：

(1), when input AC electricity is in positive axis.Input current passes through diode D_{2 1}To capacitance C_{2 1}Charging, passes through Diode D_{2 2}To capacitance C_{2 2}Charging, capacitance C_{1 2}Electric discharge；Input current passes through diode D simultaneously_{4 1}, to capacitance C_{4 1}Charging, C_{3 1}Electric discharge, passes through diode D_{4 2}To capacitance C_{4 2}Charging, capacitance C_{3 2}Electric discharge；Diode D at this time_{3 2}、D_{1 2}、D_{3 2}、D₀Close It is disconnected.

(2), when input AC electricity is in negative semiaxis, input current passes through diode D₂₃₁, to capacitance C_{3 1}Charging, capacitance C_{2 1}Electric discharge, passes through diode D_{3 2}To capacitance C_{3 2}Charging, capacitance C_{2 2}Electric discharge；Input current passes through diode D simultaneously_{1 2}, to Capacitance C_{1 2}Charging, capacitance C_{4 1}Electric discharge, passes through diode D₀To capacitance C₀Charging, capacitance C_{4 2}Electric discharge, at the same to load R_LFor Electricity；Diode D at this time_{2 1}、D_{4 1}、D_{2 2}、D_{4 2}It is turned off.

Automatic current equalizing principle analysis:

By taking tetra- modules of Fig. 2 as an example.When input AC electricity is in positive axis, all diodes are turned off, capacitance C_{3 1}、 C_{1 2}、C_{3 2}Electric discharge, capacitance C_{2 1}、C_{4 1}、C_{2 2}、C_{4 2}Charging, Uin voltage decrease speeds are much larger than the lower reduction of speed of capacitance voltage Degree.Input voltage Uin is begun to ramp up from 0, when Uin rises above capacitance C_{2 1}Voltage U_{C2 1}When diode D_{2 1}Conducting, Capacitance C_{2 1}It starts to charge up, voltage rises；When Uin rises to (Uin+U_{C1 2}) it is more than U_{C2 2}When diode D_{2 2}Conducting, electricity Hold C_{2 2}It starts to charge up, voltage rises.At the same time, Uin rises to (Uin+U_{C3 1}) it is more than U_{C4 1}When diode D_{4 1}Conducting, Capacitance C_{4 1}It starts to charge up, voltage rises, and Uin rises to (Uin+U_{C3 2}) it is more than U_{C4 2}When diode D_{4 2}Conducting, capacitance C_{4 2} It starts to charge up, voltage rises.Capacitance C_{2 1}、C_{4 1}、C_{2 2}、C_{4 2}Lasting charging, until Uin rises to maximum value Uin_max, next Moment diode D_{2 1}、D_{4 1}、D_{2 2}、D_{4 2}Reversed cut-off, capacitance C_{2 1}、C_{4 1}、C_{2 2}、C_{4 2}Charging finishes, capacitance C_{3 1}、C_{1 2}、 C_{3 2}Discharge off.It is similar in this when input AC electricity is in negative semiaxis, it repeats no more.

According to capacitance C_oAmpere-second equilibrium principle, output current I_oEqual to diode D₀The electric current I flowed through_D0, due to capacitance C_{4 2} Presence, flow through diode D_{4 2}On electric current I_{D4 2}Equal to I_D0, and so on, in the first branch, flow through diode D₁On electricity Flow I_{D2 1}Equal to output current I_o.Similarly, the electric current that other branches flow through also is equal to output current I_o, the present invention realize from It is dynamic to flow.It is similar in this to expand to n module analysis process.

Pass through above-mentioned analysis, it can be seen that the converter eliminates transformer, realizes automatic current equalizing, and modularized design makes Converter capacity greatly increases.

Simulation parameter：Switching frequency f=50Hz, input voltage u_inFor 30V, output voltage u_oClose to 240V, power P= 115.2W.From Tu Nei it can be seen that 4 blocks currents are equal, each module automatic current equalizing is realized.

Claims (2)

1. a kind of from the high boost rectifier of current-sharing module large capacity, it is characterised in that：The converter includes that an exchange inputs Source,mA module,mFor even number, output diode D₀, filter capacitorC ₀, loadR _L ;

WhereinmA module includes：

Module one includes diode D_{1 2}、D_{1 3···}D_{1 n} , capacitanceC _{1 2}、C _{1 3···} C _{1 n} ；CapacitanceC _{1 2}、C _{1 3···} C _{1 n} The other end Be connected, then link together with power supply one end, while with diode D_{2 1}Anode and filter capacitorC ₀, loadR _L The other end It is connected, diode D_{1 2}Cathode and capacitanceC _{1 2}One end be connected, diode D_{1 3}Cathode and capacitanceC _{1 3}One end be connected, , and so on diode D_{1 n} Cathode and capacitanceC _{1 n} One end be connected；

Module two includes diode D_{2 1}、D_{2 2···}D_{2 n} , capacitanceC _{2 1}、C _{2 2···} C _{2 n} ；CapacitanceC _{2 1}、C _{2 2···} C _{2 n} The other end It is connected, then links together with the power supply other end, diode D_{2 1}Cathode and capacitanceC _{2 1}One end be connected, diode D_{2 2} Cathode and capacitanceC _{2 2}One end be connected,, and so on diode D_{2 n} Cathode and capacitanceC _{2 n} One end be connected；

Module three includes diode D_{3 1}、D_{3 2···}D_{3 n} , capacitanceC _{3 1}、C _{3 2···} C _{3 n} ；CapacitanceC _{3 1}、C _{3 2···} C _{3 n} The other end It is connected, then links together with power supply one end, diode D_{3 1}Cathode and capacitanceC _{3 1}One end be connected, diode D_{3 2}'s Cathode and capacitanceC _{3 2}One end be connected,, and so on diode D_{3 n} Cathode and capacitanceC _{3 n} One end be connected；

...

And so on, modulem- 1 includes diode D _{m-1 1}、D _{m-1 2···}D _{m-1 n} , capacitanceC _{m-1 1}、C _{m-1 2···} C _{m-1 n} ；CapacitanceC _{m-1 1}、C _{m-1 2···} C _{m-1 n} The other end be connected, then link together with power supply one end, diode D _{m-1 1}Cathode and capacitanceC _{m-1 1}One end be connected, diode D _{m-1 2}Cathode and capacitanceC _{m-1 2}One end be connected,, and so on diode D _{m-1 n} Cathode and capacitanceC _{m-1 n} One end be connected；

ModulemIncluding diode D _{m 1}、D _{m 2···}D _mn , capacitanceC _{m 1}、C _{m 2···} C _mn ；CapacitanceC _{m 1}、C _{m 2···} C _mn Other end phase Even, it then links together with the other end of power supply, diode D _{m 1}Cathode and capacitanceC _{m 1}One end be connected, diode D _{m 2} Cathode and capacitanceC _{m 2}One end be connected,, and so on diode D _mn Cathode and capacitanceC _mn One end be connected；Two Pole pipe D _mn Cathode and capacitanceC _mn One end between node and diode D₀Anode be connected；

Connection relation between module and module and power supply and module is：

Capacitance in first moduleC _{1 2}The other end and power supply one end between node and second module in diode D_{2 1}'s Anode is connected, diode D in first module_{1 2}Cathode withC _{1 2}Diode D in node connection module two between one end_{2 2}Sun Pole, diode D in first module_{1 3}Cathode withC _{1 3}Diode D in node connection module two between one end_{2 3}Anode ..., And so on, diode D in first module_{1 n} Cathode and capacitanceC _{1 n} Diode in node connection module two between one end D_{2 n} Anode；

Diode D in second module_{2 1}Cathode withC _{2 1}Diode D in node connection module three between one end_{3 1}Anode, Diode D in two modules_{2 2}Cathode withC _{2 2}Diode D in node connection module three between one end_{3 2}Anode ..., with such It pushes away, diode D in second module_{2 n} Cathode withC _{2 n} Diode D in node connection module three between one end_{3 n} Anode；

And so on, themDiode D in -1 module _{m-1 1}Cathode and capacitanceC _{m-1 1}Node connection module between one endmIn two poles Pipe D _{m 1}Anode,mDiode D in -1 module _{m-1 2}Cathode and capacitanceC _{m-1 2}Node connection module between one endmIn two poles Pipe D _{m 2}Anode ..., and so on,mDiode D in -1 module _{m-1 n} Cathode and capacitanceC _{m-1 n} Between one end Node connection modulemMiddle diode D _mn Anode；

ThemDiode D in a module _{m 1}Cathode and capacitanceC _{m 1}Diode D in node connection module one between one end_{1 2}Anode, ThemDiode D in a module _{m 2}Cathode and capacitanceC _{m 2}Diode D in node connection module one between one end_{1 3}Anode ..., And so on, themDiode D in a module _mn-1Cathode and capacitanceC _mn-1Diode D in node connection module one between one end_{1 n} Anode；

LoadR _L WithC ₀Parallel connection, loadR _L One terminating diode D₀Cathode, it is another to terminate to capacitance in module oneC _{1 2}The other end with Node between power supply one end；Diode D₀Anode and diode D _mn Cathode and capacitanceC _mn One end between node phase Even；Even number module is connected with the other end of power supply, and odd number module is connected with one end of power supply.

2. a kind of from the high boost rectifier of current-sharing module large capacity according to claim 1, it is characterised in that：According to exchange Source current direction is different, and circuit is divided into two kinds of working conditions：

（1）, when input AC electricity is in positive axis；Input current passes through diode D_{2 1}To capacitanceC _{2 1}Charging, passes through two poles Pipe D_{2 2}To capacitanceC _{2 2}Charging, capacitanceC _{1 2}Electric discharge；Input current passes through diode D simultaneously_{4 1}, to capacitanceC _{4 1}Charging,C _{3 1}It puts Electricity passes through diode D_{4 2}To capacitanceC _{4 2}Charging, capacitanceC _{3 2}Electric discharge；Diode D at this time_{3 2}、D_{1 2}、D_{3 2}、D₀It is turned off；

When input AC electricity is in negative semiaxis, input current passes through diode D₂₃₁, to capacitanceC _{3 1}Charging, capacitanceC _{2 1}It puts Electricity passes through diode D_{3 2}To capacitanceC _{3 2}Charging, capacitanceC _{2 2}Electric discharge；Input current passes through diode D simultaneously_{1 2}, to capacitanceC _{1 2} Charging, capacitanceC _{4 1}Electric discharge, passes through diode D₀To capacitanceC ₀Charging, capacitanceC _{4 2}Electric discharge, while to loadR _L Power supply；At this time two Pole pipe D_{2 1}、D_{4 1}、D_{2 2}、D_{4 2}It is turned off.