CN108155794A - The control method of electric vehicle and its DC-DC converter and DC-DC converter - Google Patents

Abstract

The invention discloses the control methods of a kind of electric vehicle and its DC DC converters and DC DC converters, wherein, DC DC converters include H bridges, and H bridges include first switch pipe, second switch pipe, third switching tube and the 4th switching tube, control method and include the following steps：In the whole life cycle of DC DC converters, using phase shift modulation control mode and down tube modulate control mode alternately, using phase shift modulation control mode when based on setting time Tx and setting time Ty come select in the first way or second method alternately control H bridges, and it is selected in the control mode for using down tube modulation based on total time TC and total time TD with Third Way or fourth way control H bridges, with to first switch pipe, second switch pipe, third switching tube and the 4th switching tube carry out temperature equalization control, so that the fever relative equilibrium of first to fourth switching tube in H bridges, improve the working life of switching tube in H bridges.

Description

The control method of electric vehicle and its DC-DC converter and DC-DC converter

Technical field

The present invention relates to electric vehicle engineering field, more particularly to a kind of control method of DC-DC converter, a kind of DC- DC converters and a kind of electric vehicle.

Background technology

DC-DC converter is always the important component part of field of power electronics, along with the commercialized hair of electric vehicle Exhibition, DC-DC converter have also become one of important spare part on electric vehicle.The topological structure of DC-DC converter have very much, Medium-and-large-sized power domain, full bridge PWM converter are a kind of most commonly used topologys.

Wherein, the control mode of full bridge PWM converter has very much, and uses the control of phase shift modulation in the relevant technologies mostly Mode and the control mode of down tube modulation.However, using phase shift modulation control mode when, advanced arm Sofe Switch easy to implement, And lagging leg is not easy to realize Sofe Switch, so as to which lagging leg is more serious than the fever of advanced arm；During the control mode modulated using down tube, on Sofe Switch easy to implement is managed, and down tube is not easy to realize Sofe Switch, so as to which down tube is more serious than upper tube fever.

Therefore, both the above control mode can lead to switching tube fever serious problems, influence the working life of switching tube.

Invention content

One of the technical issues of the present invention is directed to solve at least to a certain extent in above-mentioned technology.For this purpose, the present invention First purpose be to propose a kind of control method of DC-DC converter, enables to first to fourth switching tube in H bridges Fever relative equilibrium improves the working life of switching tube in H bridges.

Second object of the present invention is to propose a kind of DC-DC converter.Third object of the present invention is to propose A kind of electric vehicle.

In order to achieve the above objectives, one aspect of the present invention embodiment proposes a kind of control method of DC-DC converter, In, the DC-DC converter includes H bridges, and the H bridges include first switch pipe, second switch pipe, third switching tube and the 4th and open Guan Guan, wherein, the first switch pipe and the second switch pipe form the first bridge arm, the third switching tube and the described 4th Switching tube forms the second bridge arm, and the control method includes the following steps：When the DC-DC converter is worked, obtain Control mode during DC-DC converter last time work, and control when being worked according to the DC-DC converter last time Mode selects control mode during this task, wherein, the control mode of the DC-DC converter includes the control of phase shift modulation Mode and the control mode of down tube modulation；Control mode of the control mode for the phase shift modulation when selecting this work When, acquisition controls setting time Tx of the H bridges and controls the setting time Ty of the H bridges in a second manner in the first way, And according to it is described setting time Tx and it is described setting time Ty to the H bridges carry out alternately control with to the first switch pipe, Second switch pipe, third switching tube and the 4th switching tube carry out temperature equalization control, wherein, with described in first method control During H bridges, using first bridge arm as leading-bridge, and using second bridge arm as lagging leg；With the second method When controlling the H bridges, using second bridge arm as leading-bridge, and using first bridge arm as lagging leg；Work as selection During the control mode that control mode during this task is modulated for the down tube, obtain and the total of the H bridges is controlled with Third Way The time TC and total time TD that the H bridges are controlled with fourth way, and pass through and judge the total time TC and the total time TD Between relationship in a manner of selecting to control the H bridges, to open the first switch pipe, second switch pipe, third It closes pipe and the 4th switching tube carries out temperature equalization control, wherein, when controlling the H bridges with the Third Way, by described first Switching tube and the third switching tube as upper tube and using the second switch pipe and the 4th switching tube as down tube, and The control mode modulated using down tube controls the first switch pipe to the 4th switching tube；With the fourth way When controlling the H bridges, using the first switch pipe and the third switching tube as down tube and by the second switch pipe and 4th switching tube switchs the first switch pipe to the described 4th as upper tube, and using the control mode of down tube modulation Pipe is controlled.

The control method of DC-DC converter according to embodiments of the present invention when DC-DC converter is worked, obtains Control mode when the DC-DC converter last time works, and control mode when work according to the DC-DC converter last time selects Control mode during this task so that the control mode of phase shift modulation and down tube tune in DC-DC converter whole life cycle The control mode of system is alternately.Wherein, it during control mode of the control mode when selecting this work for phase shift modulation, obtains It takes the setting time Tx of control H bridges in the first way and controls the setting time Ty of H bridges in a second manner, then according to Tx and Ty H bridges are carried out alternately to control to carry out temperature equalization to first switch pipe, second switch pipe, third switching tube and the 4th switching tube Control；During the control mode that the control mode when selecting this work is modulated for down tube, obtain with Third Way control H bridges Total time TC and the total time TD with fourth way control H bridges, then judge the relationship between total time TC and total time TD, most The mode controlled afterwards according to the relationship selection between total time TC and total time TD H bridges, with to first switch pipe, second Switching tube, third switching tube and the 4th switching tube carry out temperature equalization control, so as to which in whole life cycle, DC-DC is converted First method and second method alternately control H bridges, DC-DC transformation when device is worked using the control mode of phase shift modulation Total time TC and total time TD during the control mode that device is modulated using down tube is equal as possible so that the fever phase of each switching tube To balance, in the case where not increasing cost, the working life of switching tube in H bridges is improved, so as to extend DC-DC converter Life cycle.

In order to achieve the above objectives, a kind of DC-DC converter that another aspect of the present invention embodiment proposes, including：H bridges, institute It states H bridges and includes first switch pipe, second switch pipe, third switching tube and the 4th switching tube, wherein, the first switch pipe and institute It states second switch pipe and forms the first bridge arm, the third switching tube and the 4th switching tube form the second bridge arm；Control module, The control module is used to obtain when the DC-DC converter is worked when once working in the DC-DC converter Control mode, and control mode when control mode when being worked according to the DC-DC converter last time selects this task, The control mode of the DC-DC converter includes the control mode of phase shift modulation and the control mode of down tube modulation, wherein, it is elected to When control mode when selecting this task is the control mode of the phase shift modulation, the control module acquisition is controlled in the first way It makes setting time Tx of the H bridges and controls the setting time Ty of the H bridges in a second manner, and according to the setting time Tx The H bridges are carried out alternately to control with to the first switch pipe, second switch pipe, third switching tube with the setting time Ty Temperature equalization control is carried out with the 4th switching tube, wherein, when controlling the H bridges with the first method, by first bridge arm As leading-bridge, and using second bridge arm as lagging leg；When controlling the H bridges with the second method, by described in Second bridge arm is as leading-bridge, and using first bridge arm as lagging leg；Control mode when selecting this work During control mode for down tube modulation, the control module obtain with Third Way control the H bridges total time TC and The total time TD of the H bridges is controlled with fourth way, and passes through the pass judged between the total time TC and the total time TD System is in a manner of selecting to control the H bridges, with to the first switch pipe, second switch pipe, third switching tube and the Four switching tubes carry out temperature equalization control, wherein, when controlling the H bridges with the Third Way, by the first switch pipe and The third switching tube uses down tube as upper tube and using the second switch pipe and the 4th switching tube as down tube The control mode of modulation controls the first switch pipe to the 4th switching tube；With described in fourth way control During H bridges, using the first switch pipe and the third switching tube as down tube and by the second switch pipe and the described 4th Switching tube controls the first switch pipe to the 4th switching tube as upper tube, and using the control mode of down tube modulation System.

When being actuated for work, DC-DC is obtained DC-DC converter according to embodiments of the present invention by control module Control mode when the converter last time works, and control mode when being worked according to the DC-DC converter last time selects this Control mode during work so that the control mode of phase shift modulation and down tube are modulated in DC-DC converter whole life cycle Control mode is alternately.Wherein, during control mode of the control mode when selecting this work for phase shift modulation, pass through control Molding block obtains the setting time Tx of control H bridges in the first way and controls setting the time Ty, Ran Hougen of H bridges in a second manner According to Tx and Ty to H bridges carry out alternately control, with to first switch pipe, second switch pipe, third switching tube and the 4th switching tube into Trip temperature Balance route；During the control mode that the control mode when selecting this work is modulated for down tube, pass through control module It obtains with total time TC of Third Way control H bridges and the total time TD with fourth way control H bridges, then judges total time TC With the relationship between total time TD, finally H bridges are controlled according to the relationship selection between total time TC and total time TD Mode, to carry out temperature equalization control to first switch pipe, second switch pipe, third switching tube and the 4th switching tube, thus In whole life cycle, when being worked using the control mode of phase shift modulation by first method and second method alternately H bridges are controlled, total time TC and the total time TD during control mode modulated using down tube are equal as possible so that each switching tube Fever relative equilibrium in the case where not increasing cost, improves the working life of switching tube in H bridges, so as to extend life Period.

In addition, the embodiment of the present invention also proposed a kind of electric vehicle, including above-mentioned DC-DC converter.

The electric vehicle of the embodiment of the present invention can control DC-DC converter to use phase shift tune in whole life cycle The control mode of control mode and the down tube modulation of system alternately, and when being worked using the control mode of phase shift modulation H bridges are alternately controlled by first method and second method, the total time TC during control mode modulated using down tube with it is total Time, TD was equal as possible, can realize to first switch pipe, second switch pipe, third switching tube and the 4th switching tube in H bridges Carry out temperature equalization control so that the fever relative equilibrium of each switching tube in the case where not increasing cost, is improved in H bridges The working life of switching tube, so as to extend the life cycle of DC-DC converter.

Description of the drawings

Fig. 1 is the circuit diagram according to the DC-DC converter of one embodiment of the invention；

Fig. 2 is the flow chart according to the control method of the DC-DC converter of the embodiment of the present invention；

Fig. 3 A are four when being controlled using first method the H bridges switching tube according to one embodiment of the invention Drive waveforms schematic diagram；

Fig. 3 B are four when being controlled using second method the H bridges switching tube according to one embodiment of the invention Drive waveforms schematic diagram；

Fig. 4 A are four when being controlled using Third Way the H bridges switching tube according to one embodiment of the invention Drive waveforms schematic diagram；

Fig. 4 B are four when being controlled using fourth way the H bridges switching tube according to one embodiment of the invention Drive waveforms schematic diagram；

Fig. 5 is the flow chart according to the control method of the DC-DC converter of a specific embodiment of the invention；

Fig. 6 is the block diagram according to the electric vehicle of the embodiment of the present invention.

Specific embodiment

The embodiment of the present invention is described below in detail, the example of the embodiment is shown in the drawings, wherein from beginning to end Same or similar label represents same or similar element or the element with same or like function.Below with reference to attached The embodiment of figure description is exemplary, it is intended to for explaining the present invention, and is not considered as limiting the invention.

With reference to the accompanying drawings come describe the embodiment of the present invention proposition DC-DC converter control method, DC-DC converter And the electric vehicle with the DC-DC converter.

As shown in Figure 1, DC-DC converter according to an embodiment of the invention includes H bridges, H bridges may include first switch Pipe Q1, second switch pipe Q2, third switching tube Q3 and the 4th switching tube Q4.Wherein, first switch pipe Q1 and second switch pipe Q2 The first bridge arm is formed, third switching tube Q3 and the 4th switching tube Q4 form the second bridge arm, first switch pipe Q1 and second switch pipe Between Q2 there is first node A, there is second node B between third switching tube Q3 and the 4th switching tube Q4.

Also, as shown in Figure 1, the DC-DC converter further includes transformer, the first inductance L1, the first capacitance C1, the second electricity Sense L2 and the second capacitance C2, the 5th switching tube Q5, the 6th switching tube Q6, one end of the first inductance L1 are connected with first node A, the The other end of one inductance L1 is connected with one end of the first capacitance C1, the other end of the first capacitance C1 and the armature winding of transformer One end is connected, and the other end of the armature winding of transformer is connected with second node B.The secondary windings of transformer connects the 5th respectively Switching tube Q5 and the 6th switching tube Q6, the second inductance L2 and the second capacitance C2 are connected to the output terminal of DC-DC converter.

In an embodiment of the present invention, as shown in Fig. 2, the control method of above-mentioned DC-DC converter includes the following steps：

S1 when DC-DC converter is worked, obtains the control mode during work of DC-DC converter last time, and root Control mode when working according to the DC-DC converter last time selects control mode during this task, wherein, DC-DC converter The control mode of control mode including phase shift modulation and the control mode of down tube modulation.

In other words, DC-DC converter starts per task, reads control mode used by the last time, if last work Control mode is the control mode of phase shift modulation used by work, then this task of DC-DC converter will be using down tube modulation Control mode；If last time work used by control mode be down tube modulation control mode, DC-DC converter this Work will be using the control mode of phase shift modulation.In this way, in the whole life cycle of DC-DC converter, the control of phase shift modulation The control mode of mode and down tube modulation processed is alternately.

S2, during control mode for phase shift modulation of control mode when selecting this work, acquisition is controlled in the first way The setting time Tx of the H bridges processed and setting time Ty for controlling H bridges in a second manner, and according to setting time Tx and setting time Ty Alternately control is carried out to H bridges, with equal into trip temperature to first switch pipe, second switch pipe, third switching tube and the 4th switching tube Weighing apparatus control.

Wherein, when controlling the H bridges with the first method, using first bridge arm as leading-bridge, and by described in Second bridge arm is as lagging leg；When controlling the H bridges with the second method, using second bridge arm as leading-bridge, And using first bridge arm as lagging leg.

According to one embodiment of present invention, it when controlling the H bridges with the first method, exports to first switch pipe Q1 Control signal and output to second switch pipe Q2 control signal is complementary and output to third switching tube Q3 control signal With exporting to the control signal complementation of the 4th switching tube Q4, and first switch pipe Q1 previous phase angles super than the 4th switching tube Q4 It opens and second switch pipe Q2 previous phase angles super than third switching tube Q3 is open-minded.

Specifically, the drive of the drive waveforms of first switch pipe Q1, the drive waveforms of second switch pipe Q2, third switching tube Q3 Voltage U between two bridge arms of dynamic waveform, the drive waveforms of the 4th switching tube Q4 and H bridges_ABWaveform is as shown in Figure 3A.From figure 3A can show that the control signal of Q1, Q2 are complementary in four switching tubes of H bridges, and the control signal of Q3, Q4 are complementary, and diagonal is opened Pass pipe Q1 previous phase angles super than Q4 are open-minded, and Q2 is super than Q3, and previous phase angle is open-minded.Also, by adjusting the phase angle Size adjusts output voltage.

Also, when controlling the H bridges with the second method, export to the control signal of first switch pipe Q1 with exporting extremely The control signal of second switch pipe Q2 is complementary and exports to the control signal of third switching tube Q3 and output to the 4th switching tube The control signal of Q4 is complementary, and the 4th switching tube Q4 previous phase angles super than first switch pipe Q1 are opened and third switch Pipe Q3 is super than second switch pipe Q2, and previous phase angle is open-minded.

Specifically, the drive of the drive waveforms of first switch pipe Q1, the drive waveforms of second switch pipe Q2, third switching tube Q3 Voltage U between two bridge arms of dynamic waveform, the drive waveforms of the 4th switching tube Q4 and H bridges_ABWaveform is as shown in Figure 3B.From figure 4 can obtain, the control signal of Q1, Q2 are complementary in four switching tubes of H bridges, and the control signal of Q3, Q4 are complementary, diagonal wiretap Pipe Q4 is super than Q1, and previous phase angle is open-minded, and Q3 is super than Q2, and previous phase angle is open-minded.Equally, by adjusting the big of the phase angle It is small to adjust output voltage.

Wherein, it should be noted that in the course of work that DC-DC converter is carried out using the control mode of phase shift modulation In, if controlled only with first method A H bridges, Sofe Switch is difficult to realize as switching tube Q3, Q4 in lagging leg That is zero voltage switch, therefore the switching loss of switching tube Q3, Q4 are big, cause to overheat.

Similarly, in the course of work carried out in DC-DC converter using the control mode of phase shift modulation, if only with Second method B controls H bridges, and Sofe Switch i.e. zero voltage switch is difficult to realize as switching tube Q1, Q2 in lagging leg, Therefore the switching loss of switching tube Q1, Q2 are big, cause to overheat.

Therefore, in one embodiment of the invention, DC-DC converter is worked using the control mode of phase shift modulation When, Tx and Ty is first set, it, can in the course of work then carried out in DC-DC converter using the control mode of phase shift modulation DC-DC converter, which works, first to be controlled such that H bridges using first method A, until using first method A to H bridges into The time of row control reaches Tx, is switched to and is controlled such that DC-DC converter works to H bridges using second method B, directly Reach Ty to using the time that second method B controls H bridges, so complete a working cycles (i.e. working cycles Time=Tx+Ty), then be switched to and DC-DC converter, which works, to be controlled such that H bridges using first method A, until adopting Reach Tx with the first method A times controlled H bridges, then switch to and H bridges are controlled such that using second method B DC-DC converter works, until reaching Ty using the time that second method B controls H bridges ... ..., so repeatedly It carries out, realizes and alternately control is carried out to H bridges, opened so as to fulfill to first switch pipe, second switch pipe, third switching tube and the 4th It closes pipe and carries out temperature equalization control.Certainly, the course of work carried out in DC-DC converter using the control mode of phase shift modulation In, also can DC-DC converter, which works, first be controlled such that H bridges using second method B, until using second method B The time controlled H bridges reaches Ty, is switched to and is controlled such that DC-DC converter is carried out to H bridges using first method A Work until reaching Tx using the time that first method A controls H bridges, so completes a working cycles, and according to this The working cycles of sample are repeated, until DC-DC converter stops this task.

In other words, in one embodiment of the invention, the H bridges are handed over according to setting time Tx and setting time Ty For control, including：When the time of the H bridges being controlled to reach Tx using the first method, using the second method to institute It states H bridges to be controlled, until the time for controlling the H bridges using the second method reaches Ty；Or when using described second When mode controls the time of the H bridges to reach Ty, the H bridges are controlled using the first method, until described in using First method controls the time of the H bridges to reach Tx.

It should be noted that in an embodiment of the present invention, H bridges are either controlled in the first way still with second Mode controls H bridges, and what DC-DC converter used is all the control mode of phase shift modulation.Wherein, first to fourth switching tube is equal It is driven using 50% duty ratio, the driving voltage of same bridge arm is complementary, phase difference 180 degree, and leading-bridge and lagging leg Between differ a phase angle, adjust output voltage by adjusting the size at the phase angle.

According to one embodiment of present invention, setting time Tx controlled with the first method the H bridges etc. In the setting time Ty controlled with the second method the H bridges, can ensure so in the first way and second party Formula ensures first switch pipe Q1, second switch pipe Q2, third switching tube Q3 and the 4th switching tube Q4 fever phases when alternately controlling H bridges To balance.

It is, of course, understood that in other embodiments of the invention, the H bridges are carried out with the first method Setting time Tx of control can not also be equal with the setting time Ty controlled with the second method the H bridges.

In conclusion when DC-DC converter is worked using the control mode of phase shift modulation, based on setting time Tx First method or second method is selected to carry out alternately control to H bridges with Ty, it can be in DC-DC converter using phase shift modulation The calorific value relative equilibrium of switching tube Q1, Q2, Q3 and Q4 in H bridges are realized in control mode, additional member need not be increased in this way Device reduces cost, and can increase the working life of DC-DC converter, reduces failure rate.

S3 during the control mode that the control mode when selecting this work is modulated for down tube, is obtained with Third Way control Total time TC of H bridges processed and the total time TD with fourth way control H bridges, and pass through and judge between total time TC and total time TD Relationship in a manner of selecting to control H bridges, to open first switch pipe, second switch pipe, third switching tube and the 4th It closes pipe and carries out temperature equalization control.

Wherein, when controlling the H bridges with the Third Way, using first switch pipe Q1 and third switching tube Q3 as upper tube And using second switch pipe Q2 and the 4th switching tube Q4 as down tube, and the control mode modulated using down tube is to first switch pipe It is controlled to the 4th switching tube；When controlling the H bridges with the fourth way, by first switch pipe Q1 and third switching tube Q3 As down tube and using second switch pipe Q2 and the 4th switching tube Q4 as upper tube, and using down tube modulation control mode to the One switching tube to the 4th switching tube is controlled.

According to one embodiment of present invention, it when controlling the H bridges with the Third Way, exports to first switch pipe Q1 Control signal and output to third switching tube Q3 control signal it is complementary and be fixed duty cycle, and to output to second switch The failing edge of the control signal of pipe Q2 and the 4th switching tube Q4 carries out PWM controls.

Specifically, the drive of the drive waveforms of first switch pipe Q1, the drive waveforms of second switch pipe Q2, third switching tube Q3 Voltage U between two bridge arms of dynamic waveform, the drive waveforms of the 4th switching tube Q4 and H bridges_ABWaveform is as shown in Figure 4 A.From figure 4A can show that the control signal of Q1, Q3 are complementary in four switching tubes of H bridges and are to fix 50% duty ratio, the decline of Q2, Q4 Edge is modulated, and be to adjust output voltage by adjusting the driving voltage failing edge of down tube by PWM rules.

Also, when controlling the H bridges with the fourth way, export to the control signal of second switch pipe Q2 with exporting extremely The control signal of 4th switching tube Q4 is complementary and is fixed duty cycle, and to output to first switch pipe Q1 and third switching tube Q3 Control signal failing edge carry out PWM controls.

Specifically, the drive of the drive waveforms of first switch pipe Q1, the drive waveforms of second switch pipe Q2, third switching tube Q3 Voltage U between two bridge arms of dynamic waveform, the drive waveforms of the 4th switching tube Q4 and H bridges_ABWaveform is as shown in Figure 4 B.From figure 4B can show that the control signal of Q2, Q4 are complementary in four switching tubes of H bridges and are to fix 50% duty ratio, the decline of Q1, Q3 Edge is modulated, and be to adjust output voltage by adjusting the driving voltage failing edge of down tube by PWM rules.

Wherein, it should be noted that in the course of work that DC-DC converter is carried out using the control mode of down tube modulation In, if controlled only with Third Way C H bridges, since the resonant discharge stage can only utilize primary side resonant inductance, because This is difficult to realize Sofe Switch i.e. zero voltage switch as switching tube Q2, Q4 of down tube, so as to the switching loss of switching tube Q2, Q4 Greatly, cause to overheat.

Similarly, in the course of work carried out in DC-DC converter using the control mode of down tube modulation, if only with Fourth way D controls H bridges, since the resonant discharge stage can only utilize primary side resonant inductance, as down tube Switching tube Q1, Q3 are difficult to realize Sofe Switch i.e. zero voltage switch, big so as to the switching loss of switching tube Q1, Q3, cause to overheat.

Therefore, in one embodiment of the invention, DC-DC converter is worked using the control mode of down tube modulation When, when being controlled using Third Way C H bridges, record uses the time that Third Way C controls H bridges, so as to To with the total time TC of Third Way control H bridges, then stored；When being controlled using fourth way D H bridges, record The time controlled using fourth way D H bridges, so as to available total time TD, Ran Houjin with fourth way control H bridges Row storage.In this way DC-DC converter every time using down tube modulation control mode worked when judge total time TC with always Relationship between time TD, and the mode controlled H bridges is selected according to the relationship between total time TC and total time TD, Temperature equalization control is carried out to first switch pipe, second switch pipe, third switching tube and the 4th switching tube so as to realize.

Wherein, the H bridges are controlled according to the relationship selection between the total time TC and the total time TD Mode specifically includes：When the total time TC is more than the total time TD, the fourth way is selected to carry out the H bridges Control；When the total time TC is less than the total time TD, the Third Way is selected to control the H bridges；Work as institute When stating total time TC equal to the total time TD, the Third Way or the fourth way is selected to control the H bridges.

That is, before DC-DC converter is started to work using the control mode of down tube modulation, obtained from storage region It takes with total time TC of Third Way control H bridges and the total time TD with fourth way control H bridges, then to total time TC and always Time, TD was judged, determined to be controlled H bridges using Third Way or controlled using fourth way according to judging result H bridges processed.Wherein, DC-DC converter chooses mode later just during being worked using the control mode of down tube modulation According to fixed form, that is, Third Way or fourth way control H bridges, work total time is recorded when DC-DC converter is stopped, For example, when DC-DC converter this task is using Third Way control H bridges, the total time recorded when being stopped is this It, i.e., will after the every task of DC-DC converter from the total time that storage region obtains plus this working time when task starts Total time is updated, so as to select which kind of mode during convenient lower task to control H bridges.

It should be noted that in an embodiment of the present invention, H bridges are either controlled still with the 4th with Third Way Mode controls H bridges, and what DC-DC converter used is all the control mode of down tube modulation.Wherein, the control modulated using down tube During mode, two switching tubes of upper tube are open-minded in turn by 50% duty ratio, there is no dead time, by adjust down tube two The failing edge of a switching tube driving voltage, realizes the adjusting of output voltage.

Also, in the control mode of down tube modulation, two switching tubes Sofe Switch, that is, no-voltage easy to implement of upper tube is opened It closes, corresponding to the leading-bridge in the control mode of phase shift modulation, and two switching tubes of down tube correspond to the control of phase shift modulation Lagging leg in mode processed is difficult to realize zero voltage switch.

In the embodiment of the present invention, when DC-DC converter uses the control mode of down tube modulation in whole life cycle, It can make temperature by first to fourth switching tube alternately as top tube and down tube, that is, Q1, Q3 and Q2, Q4 alternate plays upper tube, down tube Stress is equivalent in four switching tubes of H bridges to be uniformly distributed, so that the fever relative equilibrium of each switching tube, is realized whole Thermal balance extends the service life of DC-DC converter.

In conclusion when DC-DC converter is worked using the control mode of down tube modulation, by recording DC-DC Converter is that H bridges are controlled using Third Way or fourth way, and total time TC when recording using Third Way and is adopted Total time TD during with fourth way, then the relationship between TC and TD judge, so as to select control H bridges mode, The fever of switching tube Q1, Q2, Q3 and Q4 in H bridges can be realized in control mode of the DC-DC converter using down tube modulation Relative equilibrium is measured, additional component need not be increased in this way, reduce cost, and the working life of DC-DC converter can be increased, Reduce failure rate.

Specifically, according to one embodiment of present invention, as shown in figure 5, the control method of above-mentioned DC-DC converter Include the following steps：

S501, work start, i.e., when DC-DC converter starts and starts to work, output control waveform are needed to come in H bridges Switching tube controlled.

S5011, used control mode when reading the work of DC-DC converter last time.

S5011 judges the last time using the no control mode for phase shift modulation.If so, perform step S507；Such as Fruit is no, performs step S502.

In other words, if control mode is the control mode of phase shift modulation used by last work, DC-DC converter This task will be using the control mode of down tube modulation；If control mode is not phase shift modulation used by last time work Control mode, then this task of DC-DC converter will be using the control mode of phase shift modulation.

S502 sets Tx and Ty.

S503 is controlled such that DC-DC converter works using first method A to H bridges, and is converted in DC-DC Judge whether this task of DC-DC converter terminates in the course of work of device, if so, terminating flow, continue if not, returning Judge.

S504 judges whether the time using first method A control H bridges reaches Tx.If so, perform step S505；Such as Fruit is no, return to step S503.

S505 is controlled such that DC-DC converter works using second method B to H bridges, and is converted in DC-DC Judge whether this task of DC-DC converter terminates in the course of work of device, if so, terminating flow, continue if not, returning Judge.

S506 judges whether the time using second method B control H bridges reaches Ty.Step is performed if so, returning S503；If not, return to step S505.

S507 is read with total time TC of Third Way C control H bridges and the total time TD with fourth way D control H bridges.

S508, judges whether TC is more than TD.If so, perform step S509；If not, perform step S513.

S509 selects fourth way D to control H bridges.

S510, DC-DC converter are in the course of work.

S511, judges whether this course of work of DC-DC converter terminates.If so, perform step S512；If It is no, return to step S510.

S512 records this working time of DC-DC converter, during so as to be started according to DC-DC converter this task Total time TD obtained from storage region updates total time TD plus this working time.

S513, judges whether TC is less than TD.If so, perform step S514；If not, perform step S518.

S514 selects Third Way C to control H bridges.

S515, DC-DC converter are in the course of work.

S516, judges whether this course of work of DC-DC converter terminates.If so, perform step S517；If It is no, return to step S515.

S517 records this working time of DC-DC converter, during so as to be started according to DC-DC converter this task Total time TC obtained from storage region updates total time TC plus this working time.

S518 selects Third Way C or fourth way D to control H bridges.

S519, DC-DC converter are in the course of work.

S520, judges whether this course of work of DC-DC converter terminates.If so, perform step S521；If It is no, return to step S519.

S521 records this working time of DC-DC converter.Wherein, if selection Third Way C controls H bridges, During so as to be started according to DC-DC converter this task from total time TC that storage region obtains plus this working time come more New total time TC；If selection fourth way D controls H bridges, so as to when being started according to DC-DC converter this task from depositing What storage area domain obtained updates total time TD total time TD plus this working time.

Therefore, in an embodiment of the present invention, in the whole life cycle of DC-DC converter, using phase shift modulation Control mode and the control mode of down tube modulation alternately, and are based on the setting time when using the control mode of phase shift modulation Tx and Ty come select in the first way or second method alternately control H bridges and using down tube modulation control mode when base It is selected in total time TC and total time TD with Third Way or fourth way control H bridges, thus in whole life cycle, First method and second method alternately control H bridges when DC-DC converter is worked using the control mode of phase shift modulation, And total time TC and total time TD during the control mode that DC-DC converter is modulated using down tube are equal as possible, it is ensured that The fever relative equilibrium of each switching tube substantially increases the working life of DC-DC converter.

The control method of DC-DC converter according to embodiments of the present invention when DC-DC converter is worked, obtains Control mode when the DC-DC converter last time works, and control mode when work according to the DC-DC converter last time selects Control mode during this task so that the control mode of phase shift modulation and down tube tune in DC-DC converter whole life cycle The control mode of system is alternately.Wherein, it during control mode of the control mode when selecting this work for phase shift modulation, obtains It takes the setting time Tx of control H bridges in the first way and controls the setting time Ty of H bridges in a second manner, then according to Tx and Ty H bridges are carried out alternately to control to carry out temperature equalization to first switch pipe, second switch pipe, third switching tube and the 4th switching tube Control；During the control mode that the control mode when selecting this work is modulated for down tube, obtain with Third Way control H bridges Total time TC and the total time TD with fourth way control H bridges, then judge the relationship between total time TC and total time TD, most The mode controlled afterwards according to the relationship selection between total time TC and total time TD H bridges, with to first switch pipe, second Switching tube, third switching tube and the 4th switching tube carry out temperature equalization control, so as to which in whole life cycle, DC-DC is converted First method and second method alternately control H bridges, DC-DC transformation when device is worked using the control mode of phase shift modulation Total time TC and total time TD during the control mode that device is modulated using down tube is equal as possible so that the fever phase of each switching tube To balance, in the case where not increasing cost, the working life of switching tube in H bridges is improved, so as to extend DC-DC converter Life cycle.

As shown in Figure 1, DC-DC converter according to embodiments of the present invention includes H bridges and such as MCU of control module 100 (Micro Control Unit, microcontroller).Wherein, H bridges include first switch pipe Q1, second switch pipe Q2, third switch Pipe Q3 and the 4th switching tube Q4, first switch pipe Q1 and second switch pipe Q2 form the first bridge arm, third switching tube Q3 and the 4th Switching tube Q4 forms the second bridge arm, has first node A, third switching tube Q3 between first switch pipe Q1 and second switch pipe Q2 There is second node B between the 4th switching tube Q4.

Control module 100 is used to obtain primary work in the DC-DC converter when the DC-DC converter is worked Control mode when making, and control when control mode when being worked according to the DC-DC converter last time selects this task Mode processed, wherein, the control mode of the DC-DC converter includes the control mode of phase shift modulation and the controlling party of down tube modulation Formula.

Also, during control mode of the control mode when selecting this work for the phase shift modulation, control module 100 Acquisition controls setting time Tx of the H bridges and controls the setting time Ty of the H bridges, and root in a second manner in the first way The H bridges are carried out alternately to control with to the first switch pipe, second according to the setting time Tx and the setting time Ty Switching tube, third switching tube and the 4th switching tube carry out temperature equalization control, wherein, the H bridges are controlled with the first method When, using first bridge arm as leading-bridge, and using second bridge arm as lagging leg；It is controlled with the second method During the H bridges, using second bridge arm as leading-bridge, and using first bridge arm as lagging leg.When select this During the control mode that control mode during work is modulated for the down tube, control module 100 is obtained controls the H with Third Way Total time TC of bridge and the total time TD that the H bridges are controlled with fourth way, and pass through judge the total time TC with it is described total Relationship between time TD in a manner of selecting to control the H bridges, with to the first switch pipe, second switch pipe, Third switching tube and the 4th switching tube carry out temperature equalization control, wherein, when controlling the H bridges with the Third Way, by institute State first switch pipe and the third switching tube as upper tube and using the second switch pipe and the 4th switching tube as Down tube, and the first switch pipe to the 4th switching tube is controlled using the control mode of down tube modulation；With described When fourth way controls the H bridges, using the first switch pipe and the third switching tube as down tube and by described second Switching tube and the 4th switching tube as upper tube, and using down tube modulation control mode to the first switch pipe to described 4th switching tube is controlled.

According to one embodiment of present invention, the control module according to setting time Tx and sets time Ty to the H When bridge alternately control, wherein, when the time of the H bridges being controlled to reach Tx using the first method, the control mould Block controls the H bridges using the second method, until the time for controlling the H bridges using the second method reaches Ty；Or when the time of the H bridges being controlled to reach Ty using the second method, the control module uses the first party Formula controls the H bridges, until the time for controlling the H bridges using the first method reaches Tx.

That is, in an embodiment of the present invention, DC-DC converter is carried out every time using the control mode of phase shift modulation During work, control module first sets Tx and Ty, the work then carried out in DC-DC converter using the control mode of phase shift modulation During work, can DC-DC converter, which works, first be controlled such that H bridges using first method A, until using first party The time that formula A controls H bridges reaches Tx, is switched to and is controlled such that DC-DC converter to H bridges using second method B It works, until reaching Ty using the time that second method B controls H bridges, so completes a working cycles (i.e. one A net cycle time=Tx+Ty), then be switched to and be controlled such that DC-DC converter is carried out to H bridges using first method A Work until reaching Tx using the time that first method A controls H bridges, is then switched to using second method B to H bridges It is controlled such that DC-DC converter works, until reaching using the time that second method B controls H bridges Ty ... ... is so repeated, and realizes and alternately control is carried out to H bridges, so as to fulfill to first switch pipe, second switch pipe, the Three switching tubes and the 4th switching tube carry out temperature equalization control.Certainly, the control mode of phase shift modulation is used in DC-DC converter In the course of work carried out, control module also first H bridges can be controlled such that using second method B DC-DC converter into Row work, until the time controlled H bridges using second method B reach Ty, be switched to using first method A to H bridges into Row controls so that DC-DC converter works, until reaching Tx using the time that first method A controls H bridges, so A working cycles are completed, and are repeated according to such working cycles, until DC-DC converter stops this task.

Wherein, in a preferred embodiment of the invention, the setting controlled with the first method the H bridges Time Tx can be equal to the setting time Ty controlled with the second method the H bridges.It can ensure with first party in this way Formula and second method ensure first switch pipe Q1, second switch pipe Q2, the switches of third switching tube Q3 and the 4th when alternately controlling H bridges Pipe Q4 fever relative equilibriums.

It is, of course, understood that in other embodiments of the invention, the H bridges are carried out with the first method Setting time Tx of control can not also be equal with the setting time Ty controlled with the second method the H bridges.

According to one embodiment of present invention, with the first method control the H bridges when, the control module export to The control signal of the first switch pipe and the control signal of output to the second switch pipe be complementary and output is to described the The control signal of three switching tubes and the control signal of output to the 4th switching tube are complementary, and described in the first switch pipe ratio The super previous phase angle of 4th switching tube is opened and the second switch pipe previous phase angle super than the third switching tube It is open-minded.

Also, when controlling the H bridges with the second method, the control module is exported to the control of the first switch pipe Signal processed controls signal complementation and output to the control signal of the third switching tube with output to the second switch pipe With exporting to the control signal complementation of the 4th switching tube, and the 4th switching tube is super more previous than the first switch pipe Phase angle is opened and the third switching tube previous phase angle super than the second switch pipe is open-minded.

According to one embodiment of present invention, the control module is according between the total time TC and the total time TD Relationship selection the H bridges are controlled mode when, wherein, when the total time TC is more than the total time TD, institute Stating control module selects the fourth way to control the H bridges；When the total time TC is less than the total time TD, The control module selects the Third Way to control the H bridges；When the total time TC is equal to the total time TD When, the control module selects the Third Way or the fourth way to control the H bridges.

That is, in one embodiment of the invention, DC-DC converter is carried out using the control mode of down tube modulation During work, when control module controls H bridges using Third Way C, what record controlled H bridges using Third Way C Time so as to the available total time TC with Third Way control H bridges, is then stored；Control module uses fourth way D When controlling H bridges, record uses the time that fourth way D controls H bridges, is controlled so as to available with fourth way The total time TD of H bridges, is then stored.Work is carried out using the control mode of down tube modulation every time in DC-DC converter in this way Control module judges the relationship between total time TC and total time TD when making, and according to the pass between total time TC and total time TD System selects the mode controlled H bridges, so as to realize to first switch pipe, second switch pipe, third switching tube and 4th switching tube carries out temperature equalization control.

According to one embodiment of present invention, with the Third Way control the H bridges when, the control module export to The control signal of the first switch pipe is complementary with the control signal of output to the third switching tube and is fixed duty cycle, and PWM controls are carried out to the failing edge for exporting the control signal to the second switch pipe and the 4th switching tube.

Also, when controlling the H bridges with the fourth way, the control module is exported to the control of the second switch pipe Signal processed is with exporting to the control signal complementation of the 4th switching tube and being fixed duty cycle, and output to described first is opened The failing edge of the control signal of third switching tube described in Guan Guanhe carries out PWM controls.

In an embodiment of the present invention, as shown in Figure 1, first switch pipe Q1, second switch pipe Q2, third switching tube Q3 and 4th switching tube Q4 is IGBT (Insulated Gate Bipolar Transistor, insulated gate bipolar transistor), when So, in other embodiments of the invention, first switch pipe Q1, second switch pipe Q2, third switching tube Q3 and the 4th switching tube Q4 may be metal-oxide-semiconductor.

When being actuated for work, DC-DC is obtained DC-DC converter according to embodiments of the present invention by control module Control mode when the converter last time works, and control mode when being worked according to the DC-DC converter last time selects this Control mode during work so that the control mode of phase shift modulation and down tube are modulated in DC-DC converter whole life cycle Control mode is alternately.Wherein, during control mode of the control mode when selecting this work for phase shift modulation, pass through control Molding block obtains the setting time Tx of control H bridges in the first way and controls setting the time Ty, Ran Hougen of H bridges in a second manner According to Tx and Ty to H bridges carry out alternately control, with to first switch pipe, second switch pipe, third switching tube and the 4th switching tube into Trip temperature Balance route；During the control mode that the control mode when selecting this work is modulated for down tube, pass through control module It obtains with total time TC of Third Way control H bridges and the total time TD with fourth way control H bridges, then judges total time TC With the relationship between total time TD, finally H bridges are controlled according to the relationship selection between total time TC and total time TD Mode, to carry out temperature equalization control to first switch pipe, second switch pipe, third switching tube and the 4th switching tube, thus In whole life cycle, when being worked using the control mode of phase shift modulation by first method and second method alternately H bridges are controlled, total time TC and the total time TD during control mode modulated using down tube are equal as possible so that each switching tube Fever relative equilibrium in the case where not increasing cost, improves the working life of switching tube in H bridges, so as to extend life Period.

In addition, as shown in fig. 6, the embodiment of the present invention also proposed a kind of electric vehicle 10, including above-mentioned DC-DC Converter 20.

The electric vehicle of the embodiment of the present invention can control DC-DC converter to use phase shift tune in whole life cycle The control mode of control mode and the down tube modulation of system alternately, and when being worked using the control mode of phase shift modulation H bridges are alternately controlled by first method and second method, the total time TC during control mode modulated using down tube with it is total Time, TD was equal as possible, can realize to first switch pipe, second switch pipe, third switching tube and the 4th switching tube in H bridges Carry out temperature equalization control so that the fever relative equilibrium of each switching tube in the case where not increasing cost, is improved in H bridges The working life of switching tube, so as to extend the life cycle of DC-DC converter.

In the description of the present invention, it is to be understood that term " " center ", " longitudinal direction ", " transverse direction ", " length ", " width ", " thickness ", " on ", " under ", "front", "rear", "left", "right", " vertical ", " level ", " top ", " bottom " " interior ", " outer ", " up time The orientation or position relationship of the instructions such as needle ", " counterclockwise ", " axial direction ", " radial direction ", " circumferential direction " be based on orientation shown in the drawings or Position relationship is for only for ease of the description present invention and simplifies description rather than instruction or imply that signified device or element must There must be specific orientation, with specific azimuth configuration and operation, therefore be not considered as limiting the invention.

In addition, term " first ", " second " are only used for description purpose, and it is not intended that instruction or hint relative importance Or the implicit quantity for indicating indicated technical characteristic.Define " first " as a result, the feature of " second " can be expressed or Implicitly include at least one this feature.In the description of the present invention, " multiple " are meant that at least two, such as two, three It is a etc., unless otherwise specifically defined.

In the present invention unless specifically defined or limited otherwise, term " installation ", " connected ", " connection ", " fixation " etc. Term should be interpreted broadly, for example, it may be being fixedly connected or being detachably connected or integral；Can be that machinery connects It connects or is electrically connected；It can be directly connected, can also be indirectly connected by intermediary, can be in two elements The connection in portion or the interaction relationship of two elements, unless otherwise restricted clearly.For those of ordinary skill in the art For, the concrete meaning of above-mentioned term in the present invention can be understood as the case may be.

In the present invention unless specifically defined or limited otherwise, fisrt feature can be with "above" or "below" second feature It is that the first and second features are in direct contact or the first and second features pass through intermediary mediate contact.Moreover, fisrt feature exists Second feature " on ", " top " and " above " but fisrt feature right over second feature or oblique upper or be merely representative of Fisrt feature level height is higher than second feature.Fisrt feature second feature " under ", " lower section " and " below " can be One feature is immediately below second feature or obliquely downward or is merely representative of fisrt feature level height less than second feature.

In the description of this specification, reference term " one embodiment ", " example ", " is specifically shown " some embodiments " The description of example " or " some examples " etc. means specific features, structure, material or the spy for combining the embodiment or example description Point is contained at least one embodiment of the present invention or example.In the present specification, schematic expression of the above terms are not It must be directed to identical embodiment or example.Moreover, particular features, structures, materials, or characteristics described can be in office It is combined in an appropriate manner in one or more embodiments or example.In addition, without conflicting with each other, the skill of this field Art personnel can tie the different embodiments or examples described in this specification and the feature of different embodiments or examples It closes and combines.

Although the embodiments of the present invention has been shown and described above, it is to be understood that above-described embodiment is example Property, it is impossible to limitation of the present invention is interpreted as, those of ordinary skill in the art within the scope of the invention can be to above-mentioned Embodiment is changed, changes, replacing and modification.

Claims (13)

1. a kind of control method of DC-DC converter, which is characterized in that the DC-DC converter includes H bridges, and the H bridges include First switch pipe, second switch pipe, third switching tube and the 4th switching tube, wherein, the first switch pipe and described second is opened It closes pipe and forms the first bridge arm, the third switching tube and the 4th switching tube form the second bridge arm, and the control method includes Following steps：

When the DC-DC converter is worked, the control mode during DC-DC converter last time work is obtained, and Control mode when being worked according to the DC-DC converter last time selects control mode during this task, wherein, it is described The control mode of DC-DC converter includes the control mode of phase shift modulation and the control mode of down tube modulation；

During control mode for the phase shift modulation of control mode when selecting this work, acquisition controls institute in the first way It states setting time Tx of H bridges and controls the setting time Ty of the H bridges in a second manner, and according to the setting time Tx and institute Setting time Ty is stated the H bridges are carried out alternately to control with to the first switch pipe, second switch pipe, third switching tube and the Four switching tubes carry out temperature equalization control, wherein, with the first method control the H bridges when, using first bridge arm as Leading-bridge, and using second bridge arm as lagging leg；When controlling the H bridges with the second method, by described second Bridge arm is as leading-bridge, and using first bridge arm as lagging leg；

During the control mode that the control mode when selecting this work is modulated for the down tube, obtain and institute is controlled with Third Way State total time TC of H bridges and the total time TD of the H bridges controlled with fourth way, and pass through judge the total time TC with it is described Relationship between total time TD is in a manner of selecting to control the H bridges, with to the first switch pipe, second switch Pipe, third switching tube and the 4th switching tube carry out temperature equalization control, wherein, it, will when controlling the H bridges with the Third Way The first switch pipe and the third switching tube are made as upper tube and by the second switch pipe and the 4th switching tube Control mode for down tube, and use down tube modulation controls the first switch pipe to the 4th switching tube；With institute When stating fourth way and controlling the H bridges, using the first switch pipe and the third switching tube as down tube and by described the Two switching tubes and the 4th switching tube are as upper tube, and the control mode modulated using down tube is to the first switch pipe to institute The 4th switching tube is stated to be controlled.

2. the control method of DC-DC converter as described in claim 1, which is characterized in that according to it is described setting time Tx and The setting time Ty carries out the H bridges alternately control, specifically includes：

When the time of the H bridges being controlled to reach Tx using the first method, the H bridges are carried out using the second method Control, until reaching Ty using the time of the second method control H bridges；Or

When the time of the H bridges being controlled to reach Ty using the second method, the H bridges are carried out using the first method Control, until reaching Tx using the time of the first method control H bridges.

3. the control method of DC-DC converter as claimed in claim 1 or 2, which is characterized in that wherein,

When controlling the H bridges with the first method, control signal to the first switch pipe and output are exported to described the The control signal of two switching tubes is complementary and exports to the control signal of the third switching tube and output to the described 4th switch The control signal of pipe is complementary, and the first switch pipe previous phase angle super than the 4th switching tube is opened and described Second switch pipe previous phase angle super than the third switching tube is open-minded；

When controlling the H bridges with the second method, control signal to the first switch pipe and output are exported to described the The control signal of two switching tubes is complementary and exports to the control signal of the third switching tube and output to the described 4th switch The control signal of pipe is complementary, and the 4th switching tube previous phase angle super than the first switch pipe is opened and described Third switching tube previous phase angle super than the second switch pipe is open-minded.

4. the control method of DC-DC converter as described in claim 1, which is characterized in that according to the total time TC and institute The mode that the selection of the relationship between total time TD controls the H bridges is stated, is specifically included：

When the total time TC is more than the total time TD, the fourth way is selected to control the H bridges；

When the total time TC is less than the total time TD, the Third Way is selected to control the H bridges；

When the total time TC is equal to the total time TD, the Third Way or the fourth way are selected to the H bridges It is controlled.

5. the control method of DC-DC converter as described in claim 1 or 4, which is characterized in that wherein,

When controlling the H bridges with the Third Way, control signal to the first switch pipe and output are exported to described the The control signal of three switching tubes is complementary and is fixed duty cycle, and to output to the second switch pipe and the 4th switching tube Control signal failing edge carry out PWM controls；

When controlling the H bridges with the fourth way, control signal to the second switch pipe and output are exported to described the The control signal of four switching tubes is complementary and is fixed duty cycle, and to output to the first switch pipe and the third switching tube Control signal failing edge carry out PWM controls.

6. the control method of the DC-DC converter as described in any one of claim 1-5, which is characterized in that with described first When setting time Tx that mode controls the H bridges is equal to the setting controlled the H bridges with the second method Between Ty.

7. a kind of DC-DC converter, which is characterized in that including：

H bridges, the H bridges include first switch pipe, second switch pipe, third switching tube and the 4th switching tube, wherein, described first Switching tube and the second switch pipe form the first bridge arm, and the third switching tube and the 4th switching tube form the second bridge Arm；

Control module, the control module are used to obtain the DC-DC converter when the DC-DC converter is worked Control mode during one action, and control mode when being worked according to the DC-DC converter last time selects this task When control mode, the control mode of the DC-DC converter includes the control mode of phase shift modulation and the control of down tube modulation Mode, wherein,

During control mode for the phase shift modulation of control mode when selecting this work, the control module is obtained with the One mode controls setting time Tx of the H bridges and controls the setting time Ty of the H bridges in a second manner, and set according to described The time Tx and setting time Ty is put the H bridges are carried out alternately to control with to the first switch pipe, second switch pipe, the Three switching tubes and the 4th switching tube carry out temperature equalization control, wherein, when controlling the H bridges with the first method, by described in First bridge arm is as leading-bridge, and using second bridge arm as lagging leg；The H bridges are controlled with the second method When, using second bridge arm as leading-bridge, and using first bridge arm as lagging leg；

During the control mode that the control mode when selecting this work is modulated for the down tube, the control module is obtained with the Three modes are controlled total time TC of the H bridges and the total time TD of the H bridges are controlled with fourth way, and pass through judge it is described total Relationship between time TC and the total time TD is in a manner of selecting to control the H bridges, with to the first switch Pipe, second switch pipe, third switching tube and the 4th switching tube carry out temperature equalization control, wherein, it is controlled with the Third Way During the H bridges, using the first switch pipe and the third switching tube as upper tube and by the second switch pipe and described 4th switching tube as down tube, and using down tube modulation control mode to the first switch pipe to the 4th switching tube into Row control；When controlling the H bridges with the fourth way, using the first switch pipe and the third switching tube as down tube with And using the second switch pipe and the 4th switching tube as upper tube, and the control mode modulated using down tube is to described first Switching tube to the 4th switching tube is controlled.

8. DC-DC converter as claimed in claim 7, which is characterized in that the control module is according to the setting time Tx When to the H bridges alternately control with the setting time Ty, wherein,

When the time of the H bridges being controlled to reach Tx using the first method, the control module uses the second method The H bridges are controlled, until the time for controlling the H bridges using the second method reaches Ty；Or

When the time of the H bridges being controlled to reach Ty using the second method, the control module uses the first method The H bridges are controlled, until the time for controlling the H bridges using the first method reaches Tx.

9. DC-DC converter as claimed in claim 7 or 8, which is characterized in that wherein,

When controlling the H bridges with the first method, the control module export control signal to the first switch pipe with The control signal of output to the second switch pipe is complementary and exports to the control signal of the third switching tube with exporting extremely The control signal of 4th switching tube is complementary, and the first switch pipe previous phase angle super than the 4th switching tube is opened Logical and described second switch pipe previous phase angle super than the third switching tube is open-minded；

When controlling the H bridges with the second method, the control module export control signal to the first switch pipe with The control signal of output to the second switch pipe is complementary and exports to the control signal of the third switching tube with exporting extremely The control signal of 4th switching tube is complementary, and the 4th switching tube previous phase angle super than the first switch pipe is opened Logical and described third switching tube previous phase angle super than the second switch pipe is open-minded.

10. DC-DC converter as claimed in claim 7, which is characterized in that the control module according to the total time TC with During the mode that the relationship selection between the total time TD controls the H bridges, wherein,

When the total time TC is more than the total time TD, the control module select the fourth way to the H bridges into Row control；

When the total time TC is less than the total time TD, the control module select the Third Way to the H bridges into Row control；

When the total time TC is equal to the total time TD, the control module selects the Third Way or the four directions Formula controls the H bridges.

11. the DC-DC converter as described in claim 7 or 10, which is characterized in that wherein,

When controlling the H bridges with the Third Way, the control module export control signal to the first switch pipe with The control signal of output to the third switching tube is complementary and is fixed duty cycle, and to output to the second switch pipe and institute The failing edge for stating the control signal of the 4th switching tube carries out PWM controls；

When controlling the H bridges with the fourth way, the control module export control signal to the second switch pipe with The control signal of output to the 4th switching tube is complementary and is fixed duty cycle, and to output to the first switch pipe and institute The failing edge for stating the control signal of third switching tube carries out PWM controls.

12. the DC-DC converter as described in any one of claim 7-11, which is characterized in that with the first method to institute Stating setting time Tx that H bridges are controlled is equal to the setting time Ty controlled with the second method the H bridges.

13. a kind of electric vehicle, which is characterized in that including the DC-DC converter as described in any one of claim 7-12.