CN205029563U - Active clamp steps up and keeps apart miniature converter device of tandem type - Google Patents

Abstract

The application discloses active clamp steps up and keeps apart miniature converter device of tandem type, the device includes: acquisition circuit for gather input direct current signal of voltage and current and output direct current voltage signal, the controller, it is right to be used for input direct current signal of voltage and current carries out maximum power and tracks, forms switch drive signal, drive circuit is used for the basis switch drive signal controls active clamp boost circuit's main switch and opening or closing of auxiliary switch, active clamp boost circuit for direct current voltage signal to the input carries out the active clamp in high limit and steps up, buffer circuit for to keeping apart with the direct current voltage signal who steps up through the active clamp in high limit, export the high frequency DC voltage after stepping up. Above -mentioned active clamp steps up and keeps apart miniature converter device of tandem type makes the voltage transformation under the prerequisite of guaranteeing the security performance, reduces switch quantity, reduces switch stress, reduces the volume of device, practices thrift the cost.

Description

The miniature convertor device of a kind of active-clamp boosting isolation tandem type

Technical field

The utility model relates to voltage transformation technical field, particularly relates to the miniature convertor device of a kind of active-clamp boosting isolation tandem type.

Background technology

Along with the development of power electronic technology and digital control technology, miniature voltage changer conventional at present has following three kinds:

As shown in Figure 1, Fig. 1 is the schematic diagram of a kind of traditional booster converter of the prior art.Inductance L in this booster converter _fplay a part energy-storage travelling wave tube, when the switch is closed, power supply is to inductance L _fcharging, inductance L _fenergy storage, and when a switch is off, power supply and inductance L _fcommon to release energy to load to capacitor charging, to reach the object of boosted voltage, realize the maximal power tracing of system.

As shown in Figure 2, Fig. 2 is the schematic diagram of a kind of inverse excitation type converter of the prior art.Transformer in this inverse excitation type converter plays a part energy-storage travelling wave tube, can be regarded as the inductance intercoupled for a pair.During the former limit switch conduction of this inverse excitation type converter, the electric current linear growth of former limit winding, inductive energy storage increases, secondary circuit no current, and when former limit switch OFF, the electric current of former limit winding is cut off, the magnetic field energy in transformer is discharged to output by vice-side winding and diode, now secondary circuit has electric current, achieves the transmission of energy.

As shown in Figure 3, Fig. 3 is the schematic diagram of a kind of forward converter of the prior art.The operation principle of this forward converter is just contrary with above-mentioned inverse excitation type converter, during the former limit switch conduction of this forward converter, the exciting current of transformer is by zero, increase linearly along with the increase of time, by transformer to secondary transferring energy, and when former limit switch OFF, the electric current of former limit winding linearly increases, inductive energy storage increases, secondary circuit no current.

Above-mentioned traditional booster converter has that components and parts are few, cost is low, structure is simple and control relatively easy advantage, but without electrical isolation between its input and output, poor safety performance, and although above-mentioned inverse excitation type converter and forward converter can realize the electrical isolation between input and output, but inverse excitation type converter is only suitable for the occasion of smaller power, there is certain restriction in practice, crisscross parallel inverse excitation type converter also could control the converter being no more than 600W, but its switching device is many, control relative complex, forward converter is applicable to the occasion of relatively high power, but its control algolithm is complicated, and transformer primary side not easily realizes magnetic reset, if realize accurate control, just need more switching device, and switch stress is large, volume is large, manufacturing cost is high.

Utility model content

For solving the problem, the utility model provides the miniature convertor device of a kind of active-clamp boosting isolation tandem type, can make voltage transformation under the prerequisite ensureing security performance, reduce number of switches, reduce switch stress, thus reduce the volume of device, cost-saving.

The miniature convertor device of a kind of active-clamp boosting isolation tandem type that the utility model provides, comprising:

Acquisition Circuit, for Gather and input DC voltage and current signal and output dc voltage signal;

Controller, for carrying out maximum power tracing to described input direct voltage current signal, forms switching drive signal;

Drive circuit, for according to described switching drive signal, controls the main switch of active-clamp booster circuit and the unlatching of auxiliary switch or cut out;

Described active-clamp booster circuit, for carrying out flash active-clamp and boosting to the d. c. voltage signal of input;

Buffer circuit, for isolating the d. c. voltage signal through flash active-clamp and boosting, exports the high-frequency direct-current voltage after boosting.

Preferably, in the miniature convertor device of above-mentioned active-clamp boosting isolation tandem type, described active-clamp booster circuit comprises active clamping circuir and booster circuit.

Preferably, in the miniature convertor device of above-mentioned active-clamp boosting isolation tandem type, described booster circuit comprises:

The first inductance element that first end is connected with the positive pole of input voltage;

The main switch that first end is connected with the negative pole of described input voltage;

Resonant inductance is connected with between second end of described main switch and the second end of described first inductance element.

Preferably, in the miniature convertor device of above-mentioned active-clamp boosting isolation tandem type, described active clamping circuir comprises:

The diode that first end is connected with the second end of described first inductance element;

The two ends of described diode are parallel with the first capacity cell;

The second capacity cell that first end is connected with the second end of described main switch;

Auxiliary switch is connected with between second end of described second capacity cell and the second end of described diode.

Preferably, in the miniature convertor device of above-mentioned active-clamp boosting isolation tandem type, described buffer circuit is connected between the second end of described diode and the first end of described main switch.

Preferably, in the miniature convertor device of above-mentioned active-clamp boosting isolation tandem type, described controller comprises STM32 core control panel.

Preferably, in the miniature convertor device of above-mentioned active-clamp boosting isolation tandem type, also comprise: accessory power supply, for being described active-clamp booster circuit, described Acquisition Circuit, described controller and described drive circuitry.

The miniature convertor device of above-mentioned active-clamp boosting isolation tandem type that the utility model provides, comprising: Acquisition Circuit, for Gather and input DC voltage and current signal and output dc voltage signal; Controller, for carrying out maximum power tracing to described input direct voltage current signal, forms switching drive signal; Drive circuit, for according to described switching drive signal, controls the main switch of active-clamp booster circuit and the unlatching of auxiliary switch or cut out; Described active-clamp booster circuit, for carrying out flash active-clamp and boosting to the d. c. voltage signal of input; Buffer circuit, for isolating the d. c. voltage signal through flash active-clamp and boosting, exports the high-frequency direct-current voltage after boosting.This device can make under the premise that security is guaranteed, reduces number of switches, reduces switch stress, thus reduces the volume of device, cost-saving.

Accompanying drawing explanation

In order to be illustrated more clearly in the utility model embodiment or technical scheme of the prior art, be briefly described to the accompanying drawing used required in embodiment or description of the prior art below, apparently, accompanying drawing in the following describes is only embodiment of the present utility model, for those of ordinary skill in the art, under the prerequisite not paying creative work, other accompanying drawing can also be obtained according to the accompanying drawing provided.

Fig. 1 is the schematic diagram of a kind of traditional booster converter of the prior art;

Fig. 2 is the schematic diagram of a kind of inverse excitation type converter of the prior art;

Fig. 3 is the schematic diagram of a kind of forward converter of the prior art;

The schematic diagram of the miniature convertor device of a kind of active-clamp boosting isolation tandem type that Fig. 4 provides for the embodiment of the present application;

Active-clamp booster circuit in the miniature convertor device of active-clamp boosting isolation tandem type that Fig. 5 provides for the embodiment of the present application and the connection diagram of buffer circuit;

Fig. 6 is the schematic diagram of active-clamp boosting buffer circuit switching drive signal;

The hardware structure diagram of the miniature convertor device of active-clamp boosting isolation tandem type that Fig. 7 provides for the embodiment of the present application;

The schematic diagram that the miniature convertor device of active-clamp boosting isolation tandem type that Fig. 8 provides for the embodiment of the present application is connected with DC bus;

The main program flow chart that the miniature convertor device of active-clamp boosting isolation tandem type that Fig. 9 provides for the embodiment of the present application runs;

Figure 10 is input voltage waveform figure;

Figure 11 is input current waveform figure;

Figure 12 is output voltage waveform before DC bus series connection;

Figure 13 is output voltage waveform after DC bus series connection.

Embodiment

Below in conjunction with the accompanying drawing in the utility model embodiment, be clearly and completely described the technical scheme in the utility model embodiment, obviously, described embodiment is only the utility model part embodiment, instead of whole embodiments.Based on the embodiment in the utility model, those of ordinary skill in the art are not making the every other embodiment obtained under creative work prerequisite, all belong to the scope of the utility model protection.

A kind of active-clamp boosting that the embodiment of the present application provides isolates the miniature convertor device of tandem type as shown in Figure 4, the schematic diagram of the miniature convertor device of a kind of active-clamp boosting isolation tandem type that Fig. 4 provides for the embodiment of the present application.The miniature convertor device 100 of this active-clamp boosting isolation tandem type comprises:

Acquisition Circuit 110, for Gather and input DC voltage and current signal and output dc voltage signal;

Controller 120, for carrying out maximum power tracing to described input direct voltage current signal, forms switching drive signal;

Drive circuit 130, for according to described switching drive signal, controls the main switch of active-clamp booster circuit 140 and the unlatching of auxiliary switch or cut out;

Described active-clamp booster circuit 140, for carrying out flash active-clamp and boosting to the d. c. voltage signal of input;

Buffer circuit 150, for isolating the d. c. voltage signal through flash active-clamp and boosting, exports the high-frequency direct-current voltage after boosting.

The miniature convertor device of above-mentioned active-clamp boosting isolation tandem type that the embodiment of the present application provides, can be applicable to the occasion of middle low power, the electrical isolation of convertor device input and output can not only be realized, and volume is little, security performance is high, cost is also lower, and control more simple, because the former limit booster circuit at this convertor device adds active-clamp booster circuit, the Sofe Switch of switch can be realized, reduce the switching loss of switch, improve the efficiency of convertor device.

In the miniature convertor device of above-mentioned active-clamp boosting isolation tandem type, described active-clamp booster circuit comprises active clamping circuir and booster circuit, for improving output voltage, in order to be described circuit structure, please refer to Fig. 5, active-clamp booster circuit in the miniature convertor device of active-clamp boosting isolation tandem type that Fig. 5 provides for the embodiment of the present application and the connection diagram of buffer circuit, wherein, described active-clamp booster circuit 140 comprises active clamping circuir 141 and booster circuit 142, and described booster circuit 142 comprises:

The first inductance component L that first end is connected with the positive pole of input voltage _f;

The main switch S that first end is connected with the negative pole of described input voltage ₁;

Described main switch S ₁the second end and described first inductance component L _fthe second end between be connected with resonant inductance L _r.

Described active clamping circuir 141 comprises:

First end and described first inductance component L _fsecond end connect diode VD ₁;

Described diode VD ₁two ends be parallel with the first capacity cell;

First end and described main switch S ₁second end connect the second capacity cell C _c;

Described second capacity cell C _cthe second end and second end of described diode VD1 between be connected with auxiliary switch S ₂.

Described buffer circuit 150 is connected to described diode VD ₁the second end and described main switch S ₁first end between.

Above-mentioned active-clamp booster circuit topology can the Reverse recovery of effective twin zener dioder, realize the zero voltage switch of main switch and auxiliary switch simultaneously, the voltage stress of switch is made to be no more than the maximum input voltage of convertor device, structure is simple, switching loss is low, volume is little, be applicable to being applied to the miniature convertor device of tandem type, and add buffer circuit, system safety performance is improved greatly.

The operation principle of the miniature convertor device of above-mentioned active-clamp boosting isolation tandem type is as follows: at main switch S ₁with diode VD ₁between series connection a resonant inductance L _r, can the Reverse recovery of effective twin zener dioder, but as main switch S ₁during shutoff, resonant inductance L _rcan at main switch S ₁the voltage stress that upper generation is very large, in order to ensure the safe operation of circuit, just must have an active clamping circuir to carry out clamping voltage.Because active clamping circuir structure is simple, it is convenient to control, the Sofe Switch of main switch and auxiliary switch can be realized, be therefore widely used in single-phase miniature convertor device.According to magnetism chain conservation to magnetizing inductance L _msetting up flux linkage equations is V _c=V _in* D/ (1-D), wherein, D is main switch pwm pulse duty ratio, V _cfor clamp capacitor terminal voltage, V _infor input voltage.The wide-range input voltage requirement that active-clamp boosting isolation tandem type miniature convertor device demand fulfillment is certain, therefore by maximum duty cycle D _maxbe designed to: D _max=V _imax/ (V _imax+ V _imin), wherein, V _imaxfor the miniature convertor device maximum input voltage of active-clamp boosting isolation tandem type, V _iminfor the minimum input voltage of the active-clamp boosting isolation miniature convertor device of tandem type.When input voltage is minimum input voltage V _imintime, the miniature convertor device of active-clamp boosting isolation tandem type reaches maximum duty cycle, can obtain: n=(1/ (1-D _max)) * (V _imin/ V), can transformer turns ratio be obtained by formula above: n=(V _imin+ V _imax)/V _out.As shown in Figure 6, Fig. 6 is the schematic diagram of active-clamp boosting buffer circuit switching drive signal, in the miniature convertor device of this active-clamp boosting isolation tandem type, and main switch S ₁with auxiliary switch S ₂drive singal be complementary, and with Dead Time, main switch S ₁with auxiliary switch S ₂alternate conduction.

Further, with reference to the hardware structure diagram of the miniature convertor device of active-clamp boosting isolation tandem type that figure 7, Fig. 7 provides for the embodiment of the present application, wherein, described controller comprises STM32 core control panel.Voltage, the current signal of the input of Acquisition Circuit 110 acquisition system give described STM32 controller, signal through the process of STM32 controller again through maximal power tracing, drive through overdrive circuit 130 pairs of duty cycle signals again, finally give active-clamp booster circuit, cut-offfing of control switch, realize the conversion of direct voltage, low-voltage dc signal is transformed to high-voltage dc signal.In addition, this convertor device also comprises: accessory power supply 160, for powering for described active-clamp booster circuit 140, described Acquisition Circuit 110, described controller 120 and described drive circuit 130.

The miniature convertor device of active-clamp boosting isolation tandem type that the embodiment of the present application provides is connected in series before DC bus, owing to being the series connection of multiple convertor device, so need multi-channel PWM signal to drive variable connector respectively, as shown in Figure 8, the schematic diagram that the miniature convertor device of active-clamp boosting isolation tandem type that Fig. 8 provides for the embodiment of the present application is connected with DC bus.The miniature convertor device of this active-clamp boosting isolation tandem type is except having the many merits of AC module grid connected structure and parallel connection direct bus structure, also possesses following clear superiority: due to its output voltage low (can lower than below 100V), therefore the switching device of low-voltage, high-current very general at present can be adopted, be easy to adopt synchronous rectification simultaneously, thus improve system effectiveness further; The input and output no-load voltage ratio of convertor device is little, and isolated form topology both can have been adopted also can to adopt non-isolation type topology, and system is easy to optimal design, efficiency is high; The energy of system active device and passive device is low, greatly reduces system cost, is easy to form hicap simultaneously.In addition; also comprising boosts with described active-clamp isolates the protection diode 170 that the miniature convertor device of tandem type is connected; when the miniature convertor device series connection of each active-clamp boosting isolation tandem type; add this protection diode and can prevent hot spot effect; when the miniature convertor device module of any one active-clamp boosting isolation tandem type is out of order, the normal use of other modules all can not be affected.

As shown in Figure 9, the main program flow chart that the miniature convertor device of active-clamp boosting isolation tandem type that Fig. 9 provides for the embodiment of the present application runs, the control method such as maximal power tracing algorithm, SPWM algorithm can be realized, the final control realized the miniature convertor device of active-clamp boosting isolation tandem type by calling interruption subroutine.

The miniature convertor device of above-mentioned active-clamp boosting isolation tandem type converts low-voltage direct to high voltage direct current, can be applied in the multiple systems of distributed power grid, as photovoltaic, wind power generation, thermo-electric generation, be described below with the example that is applied as of photovoltaic art.

Based on photovoltaic generation, the miniature convertor device of above-mentioned active-clamp boosting isolation tandem type is emulated, Figure 10, Figure 11, Figure 12 and Figure 13 are the simulation waveforms utilizing MATLAB/SIMU1512263LINK simulation software to obtain, wherein, Figure 10 is input voltage waveform figure, Figure 11 is input current waveform figure, Figure 12 is output voltage waveform before DC bus series connection, and Figure 13 is output voltage waveform after DC bus series connection.As can be seen from Figure 10, the voltage stabilization of input is at about 35V, and as can be seen from Figure 11, input current is probably stabilized in about 7A, and whole input power is probably 250W.Figure 12 is the output voltage waveforms before DC bus series connection, and system parameter settings is at 100V, and as seen from Figure 13, after of short duration adjustment, output voltage stabilization is at 100V, and boosting and the buffer action of circuit embody thus.Figure 13 is the output voltage waveforms after DC bus series connection, what native system adopted is the miniature convertor device series connection of two active-clamp boosting isolation tandem types, the voltage magnitude of the miniature convertor device of active-clamp boosting isolation tandem type after the series connection obtained in theory is 200V, as seen from Figure 13, after overregulating, output voltage has finally been stabilized in 200V, achieve effective series connection of the miniature convertor device of active-clamp boosting isolation tandem type, improve overall output voltage, and reduce the voltage stress of corresponding device, security performance is improved.

In sum, the miniature convertor device of active-clamp boosting isolation tandem type that the application provides has following features: switching device is few, volume is little, lightweight, system controllability and measurability is strong, be applicable to being applied to the occasions such as distributed micro-capacitance sensor, and adopt be controlled by inversion prime active-clamp boosting isolated variable method, grading control is so that series connection before realizing DC bus, control circuit is simple, dynamic property is good, security performance is high, stability is strong, be convenient to Multi-stage minitype convertor device and carry out DC bus series connection, improve the output voltage of DC bus entirety.Prove under input signal situation of change, to there is good control characteristic, its maximum power can be followed the trail of to greatest extent, device is inputted with maximum power through emulation and experiment.

To the above-mentioned explanation of the disclosed embodiments, professional and technical personnel in the field are realized or uses the utility model.To be apparent for those skilled in the art to the multiple amendment of these embodiments, General Principle as defined herein when not departing from spirit or scope of the present utility model, can realize in other embodiments.Therefore, the utility model can not be restricted to these embodiments shown in this article, but will meet the widest scope consistent with principle disclosed herein and features of novelty.

Claims (7)

1. the miniature convertor device of active-clamp boosting isolation tandem type, is characterized in that, comprising:

Acquisition Circuit, for Gather and input DC voltage and current signal and output dc voltage signal;

Controller, for carrying out maximum power tracing to described input direct voltage current signal, forms switching drive signal;

Drive circuit, for according to described switching drive signal, controls the main switch of active-clamp booster circuit and the unlatching of auxiliary switch or cut out;

Described active-clamp booster circuit, for carrying out flash active-clamp and boosting to the d. c. voltage signal of input;

Buffer circuit, for isolating the d. c. voltage signal through flash active-clamp and boosting, exports the high-frequency direct-current voltage after boosting.

2. the miniature convertor device of active-clamp boosting isolation tandem type according to claim 1, it is characterized in that, described active-clamp booster circuit comprises active clamping circuir and booster circuit.

3. the miniature convertor device of active-clamp boosting isolation tandem type according to claim 2, it is characterized in that, described booster circuit comprises:

The first inductance element that first end is connected with the positive pole of input voltage;

The main switch that first end is connected with the negative pole of described input voltage;

Resonant inductance is connected with between second end of described main switch and the second end of described first inductance element.

4. the miniature convertor device of active-clamp boosting isolation tandem type according to claim 3, it is characterized in that, described active clamping circuir comprises:

The diode that first end is connected with the second end of described first inductance element;

The two ends of described diode are parallel with the first capacity cell;

The second capacity cell that first end is connected with the second end of described main switch;

Auxiliary switch is connected with between second end of described second capacity cell and the second end of described diode.

5. the miniature convertor device of active-clamp boosting isolation tandem type according to claim 4, it is characterized in that, described buffer circuit is connected between the second end of described diode and the first end of described main switch.

6. the miniature convertor device of active-clamp boosting isolation tandem type according to any one of claim 1-5, it is characterized in that, described controller comprises STM32 core control panel.

7. the miniature convertor device of active-clamp boosting isolation tandem type according to claim 6, is characterized in that, also comprise: accessory power supply, for being described active-clamp booster circuit, described Acquisition Circuit, described controller and described drive circuitry.