Patent Application
20140085936
This non-provisional application claims priority under 35 U.S.C. §119(a) on Patent Application No. 201210134931.1 filed in P.R. China on May 3, 2012, the entire contents of which are hereby incorporated by reference.
Some references, if any, which may include patents, patent applications and various publications, may be cited and discussed in the description of this invention. The citation and/or discussion of such references, if any, is provided merely to clarify the description of the present invention and is not an admission that any such reference is “prior art” to the invention described herein. All references listed, cited and/or discussed in this specification are incorporated herein by reference in their entireties and to the same extent as if each reference was individually incorporated by reference.
The present application relates to a switch power field, and more specifically to a variable frequency converter and an adjusting method for the same.
A switch power converter is widely applied in energy conversion field due to advantages, such as high efficiency, saving energy, and so on. It can be found in various fields, such as a charger in a mobile electronic product (such as a mobile phone, a MP3, and so on), a power supply in a household electrical appliance (such as a TV set, a refrigerator), vehicle electronics, base station communication, new energy technology, military aerospace technology, and so on.
EMI (Electro Magnetic Interference) is a kind of interference more common in an electronic circuit. Whether it is in switch power or in integrated circuit or other electronic fields, how to effectively decrease EMI is a problem which should be considered in designing a circuit or a system by an electronic designer.
According to different modes of operating frequencies, switch power converters may be classified into two types: one type is a constant frequency converter, and the other type is a variable frequency converter. The two types of the converters, as shown in
As shown in
However, the variable frequency signal stage circuit module 202 of the variable frequency converter generally does not comprise an oscillator as shown in
Similarly to the constant frequency converter, the variable frequency converter also has a problem of EMI, an operating frequency of the variable frequency converter will change with change in input or/and output, it is relatively complicated to control the variable frequency converter, and it is relatively difficult to add a frequency jitter to the variable frequency converter. A conventional method is to set an EMI filter at input of variable frequency converter so as to reduce EMI. This not only increases cost, but also causes a large volume of the variable frequency converter.
Although the variable frequency converter with EMI filter has a high efficiency and is widely applied in some middle or lower power switch power systems, EMI is still worse according to certain EMI regulation. Keeping EMI in variable frequency converter as much less as possible is a desired target to be accomplished by the industry.
It is therefore an object of present application to provide a variable frequency (VF) converter, and this converter realizes frequency jitter to extend its operating frequency range so as to reduce the EMI or EMI peak value in the VF converter. The VF converter may reduce the EMI or relatively save the cost by comparing with the conventional VF converter.
A first aspect of the present application discloses a VF converter. The VF converter comprises a power stage circuit module and a variable frequency signal stage circuit module which are connected each other to form a closed-loop circuit system. The VF converter further comprises an adjusting unit outputting a continuous interfering signal and loading the continuous interfering signal into the variable frequency signal stage circuit module so as to extend operating frequency range of the VF converter.
A frequency of the continuous interfering signal is higher than a crossover frequency of the closed-loop circuit system, so that it realizes continuous jitter on the signal loaded into the variable frequency signal stage circuit module and continuous change of the operating frequency of the power stage circuit module.
A second aspect of the present application discloses a VF converter comprising a power stage circuit module and a variable frequency signal stage circuit module which are connected each other to form a closed-loop circuit system. The VF converter further comprises an adjusting unit accessed to the power stage circuit module, and the adjusting unit may change a resonance parameter of the power stage circuit module so as to cause an operating frequency of the power stage circuit module to change continuously.
A third aspect of the present application discloses an adjusting method for a VF converter, the VF converter comprises a power stage circuit module and a variable frequency signal stage circuit module which are connected each other to form a closed-loop circuit system. The adjusting method comprises: providing an adjusting unit to the VF converter, loading a continuous interfering signal into a signal inputted to the power stage circuit module by the variable frequency signal stage circuit module by means of the adjusting unit, so as to cause an output signal of the VF converter to jitter and expand an operating frequency range of the VF converter.
Technical effects of the present application are as follows: in the VF converter, the EMI may be lowered, and EMI filter may be effectively reduced or avoided from using. In the VF converter, the frequency jitter may be realized, the EMI energy may be averaged, and a jitter peak value of the EMI may be lowered.
Hereinafter, specific embodiments of the present application will be presented and described in details accompanied by the drawings.
In order to effectively diminish EMI or avoid using an EMI filter, one object of the present application is to realize frequency jitter in a VF converter to extend the operating frequency range of the VF converter, so that EMI in the variable frequency converter is distributed in more wider frequency band and EMI peak value can be suppressed comparing with the EMI in the conventional VF converter.
At a case that an input-output state is constant, an operating frequency of the variable frequency converter is relatively stable, a peak value of the EMI herein is relatively high at the switching frequency and its multiples. The present application actively loads a continuous interfering signal into the variable frequency converter so as to cause the operating frequency of the variable frequency converter to change continuously, so that the EMI peak value can be reduced. At the same time, the continuous interfering signal is required to overcome its attenuation caused by the VF converter in which the continuous interfering signal is loaded, so as to lead that operating frequency of the VF converter has wider frequency range while the input-output of variable converter is relatively stable. The VF converter of the present application will be described by taking a DC-DC power source converter as an example.
The present application discloses the variable frequency converters from two aspects. A VF converter disclosed by a first aspect is by providing an adjusting unit outputting a continuous interfering signal and loading the continuous interfering signal into a variable frequency signal stage circuit module of the VF converter so as to cause an operating frequency of a power stage circuit module controlled by the variable frequency signal stage circuit module to change continuously. A VF converter disclosed by a second aspect is by providing an adjusting unit to a power stage circuit module of the VF converter so as to change a resonance parameter of the power stage circuit module and thus to cause an operating frequency of the power stage circuit module to change continuously.
The VF converter disclosed by the first aspect has the following requirement on the continuous interfering signal outputted by the adjusting unit: the jitter signal is not an instantaneous jitter, since the VF converter is a closed-loop circuit system, the instantaneous jitter signal cannot realize that operating frequency of the power stage circuit module changes continuously. Moreover, if a frequency of the continuous interfering signal is lower than a crossover frequency of the closed-loop circuit system, the jitter signal is also easily attenuated by the closed-loop circuit system itself. Therefore the frequency of the continuous interfering signal outputted by the adjusting unit should be higher than the crossover frequency of the closed-loop circuit system, so as to make the operating frequency of the power stage circuit module change continuously. The continuous interfering signal is a voltage waveform or a current waveform which is periodic or non-periodic and whose amplitude may be constant or variable. It should be noted that, when the input-output of the VF converter is relatively stable, the continuously changing frequency jitter signal would meanwhile cause the output of the VF converter to fluctuate in a certain range. In order to address this fluctuation, a designer may adjust the amplitude of the continuous interfering signal according to requirement on the output range of the VF converter, so as to make the fluctuation of the output of the VF converter stay in an acceptable range.
For an equivalent close-loop system of the VF converter as shown in
Hereinafter, embodiments of the VF converter disclosed in the first aspect will be described in details.
In the VF converter, if a control signal in the variable frequency signal stage circuit module is continuously changed; operating frequency of the power stage circuit module may be caused to change continuously. If the frequency of continuous interfering signal is higher than a crossover frequency of a VF converter, the continuous interfering signal loaded into the variable frequency signal stage circuit module could make operating frequency of the power stage circuit module change continuously, thereby causing the operating frequency of the VF converter to jitter.
In
On a basis of the technical solution of
The variable frequency signal stage circuit module 202 comprises a detection stage circuit and a control stage circuit. Taking a topological graph of a flyback VF converter shown in
In the circuit topology of the flyback VF converter shown in
As can be appreciated by the person skill in the art, a turn-on time of the power switch 307 of the VF converter determines its operating frequency. When the jitter signal generator is not provided, the power switch 307 turns off until the detection signal reaches to a preset value. When the jitter signal generator is provided, when the loaded continuous interfering signal causes the detection signal to be decreased, the power switch 307 of the VF converter will be maintained to turn on, and will turn off until reaching an original magnitude of the detection signal. This causes a driving cycle of the VF converter to be increased and a driving frequency of the VF converter to be decreased, the operating frequency of the VF converter is also correspondingly decreased. When the loaded continuous interfering signal causes the detection signal to be increased, the operating frequency of the VF converter is also increased.
The amplitude of the continuous interfering signal determines magnitude of change in the detection signal so as to cause an effect on the operating frequency. At the same time, when the frequency of the continuous interfering signal is higher than a crossover frequency of the equivalent closed-loop circuit system of the VF converter, the loaded continuous interfering signal will not be attenuated by the closed-loop circuit system of the VF converter itself, so that the operating frequency of the VF converter occurs to change continuously, thereby realizing continuous jitter on the operating frequency of the VF converter.
The method to realize frequency jitter by changing magnitude of the detection signal (for example, a magnitude of a sampling current) is similarly applicable to a buck or boost VF converter. Referring to
Rcs in
Similar to
The variable frequency signal stage circuit module comprises a detection stage circuit and a control stage circuit. Wherein, a power stage circuit module comprises an electrolytic capacitor Cbus 301, a transformer 302, a rectifier diode D 303, an output electrolytic capacitor C0 304, and a power switch 307. A detection stage circuit comprises a detecting resistor Rcs 308, a resistor 305, and an optocoupler 306. The resistor 305 is used for sampling voltage output by the VF converter. Wherein, the detecting resistor Rcs 308 belongs to an input detection stage circuit, the resistor 305 and the optocoupler 306 belong to an output detection stage circuit. The input detection stage circuit and the output detection stage circuit respectively detect an input and an output of the power stage circuit module and output a signal to the control stage circuit. The control stage circuit comprises a driving apparatus and a feedback control circuit. The feedback control circuit receives a signal of the optocoupler 306 and outputs a feedback signal to the driving apparatus; the driving apparatus outputs a control signal to the power stage circuit module. In the present embodiment, an adjusting unit is a jitter signal generator 107. An output signal of the jitter signal generator 107 is loaded into the detection stage circuit, specifically loaded into the output detection stage circuit, so that cause a signal jitter of the control stage circuit by changing the signal of the output detection stage circuit continuously. Specifically, the output signal of the jitter signal generator 107 is loaded into a terminal of the resistor 305, so as to affect the sampling voltage at the resistor 305 detected by the output detection stage circuit.
In a circuit topology of the flyback VF converter shown in
The voltage detection signal with continuous interfering signal is transmitted to the optocoupler 306, and then transmitted to the feedback control circuit through the optocoupler, so as to affect the feedback signal outputted by the feedback control circuit. The feedback signal affects control signal outputted by the driving apparatus so that turn-on time of the switch in the power stage circuit module will be changed, and so is the operating frequency of the VF converter.
If the continuous interfering signal causes the voltage detection signal to increase, the turn-on time of the power switch will increase; thereby causing a driving cycle to be increased, but driving frequency or the operating frequency of the VF converter is correspondingly decreased. Accordingly, if the continuous interfering signal causes the voltage detection signal to decrease, the driving cycle will be decreased, and the operating frequency of the VF converter will be increased. Amplitude of the continuous interfering signal generated by the jitter signal generator determines magnitude of change in the voltage detection signal, and affects the operating frequency. When a frequency of the continuous interfering signal is higher than a crossover frequency of the VF converter, the voltage detection signal may be caused to change continuously, so as to cause the operating frequency of the VF converter to change continuously, thereby realizing continuous jitter on the operating frequency.
The way that the adjusting unit 106 with the jitter signal generator is connected to the output detection stage circuit is similarly applicable to an output detection stage circuit of a buck or boost VF converter, or other kind of VF converter.
An adjusting unit 106 may be arranged in the control stage circuit.
A frequency of an output signal of the jitter signal generator should be higher than the crossover frequency of the whole closed-loop circuit system of the VF converter, so as to realize the continuous jitter on the operating frequency of the VF converter. The amplitude of the waveform of the continuous interfering signal determines the magnitude of change in the feedback signal, and then affects the magnitude of change in the operating frequency. If the feedback signal changes continuously, it will cause the continuous jitter on the operating frequency of the VF converter, thereby realizing the continuous jitter on the operating frequency.
In fact, the adjusting unit 106 may be arranged in any position in the control stage circuit, i.e., the continuous interfering signal may be not only loaded into the feedback signal, but also loaded into other signals existed in the control stage circuit.
The method to load the continuous interfering signal generated by the adjusting unit 106 into a signal outputted by the feedback control circuit to the driving apparatus in the control stage circuit so as to realize frequency jitter is similarly applicable to a buck or boost VF converter, as respectively shown in
The continuous interfering signal generated by the adjusting unit 106 may be also loaded into a control signal outputted by the control stage circuit to the power stage circuit module, for example, as shown in
Line {circle around (1)} is a peak value line, a quasi-peak value at a certain frequency may be obtained by calculation; Line {circle around (2)} is an EMI average value line. As can be seen from
As can be seen in
At the same time, to some extent, the peak value line also has improvement according to test result (line {circle around (1)} is a peak value line, and line {circle around (2)} is an average value line).
The
Arranging the adjusting unit in other position in the control stage circuit of the variable frequency signal stage circuit module may similarly realize the frequency jitter function, but it is not limited to the above embodiments.
In addition to directly changing magnitude of a detection signal or a feedback signal, the magnitude of the detection signal may be also indirectly changed by controlling resistance of a detecting resistor, so as to change an operating frequency of the VF converter, referring to
The variable frequency signal stage circuit module 202 comprises a detection stage circuit and a control stage circuit, the detection stage circuit comprises an input detection stage circuit and an output detection stage circuit, an adjusting unit 106 and the input detection stage circuits are electrically connected.
For more detail, please refer to
A detecting resistor Rcs 308 belongs to the input detection stage circuit; the adjusting unit 106 and the detecting resistor Rcs 308 are electrically connected. The adjusting unit 106 comprises an adjusting element and an adjusting element controller matched with the adjusting element. The adjusting element 106 may be a variable resistor and a corresponding variable resistor controller, the resistance of the variable resistor changes with time under control of the variable resistor controller matched with the variable resistor, so as to realize that a continuous interfering signal is loaded into the input stage detection circuit.
Specifically, the variable resistor is a variable resistor Rt, the detecting resistor Rcs 308 is in series or in parallel connected to the variable resistor Rt, a connection in parallel is shown in
More specifically, as shown in
In the flyback topology, peak value of primary side current passing through the power switch is relevant to the turn-on time of the switch, the peak value is higher, the turn-on time of the switch is longer, and the turn-on time is relevant to the operating frequency of the VF converter.
In the short time of several switching cycles of the switch, it is considered that voltage sampling signal Vcs at two terminals of the detecting resistor Rcs is constant, wherein Vcs=Ipeak*Rcs, Ipeak is the peak value current passing through the detecting resistor Rcs. When the transistor is connected in parallel, if the same Vcs sampling voltage valve is required for the two terminals of the detecting resistor Rcs, a peak value current passing through the detecting resistor Rcs at this time is Ipeak2=Ipeak*RcsRt/(Rcs+Rt). As can be seen from this equation, peak value current Ipeak2 is a variable relevant to Rt, and the peak value current Ipeak2 changes as Rt changes.
According to this embodiment disclosed here, the conclusion that the peak value current is higher and the turn-on time of the power switch is longer can be obtained. For the same Vcs, the turn-on time Ton2 of the switch in the topology in which the detecting resistor is connected with the variable resistor Rt in parallel is longer than the turn-on time Ton of the switch in the topology in which there is no variable resistor Rt. Referring to
The continuous jitter on the operating frequency may average EMI energy, or decrease the EMI peak value in the VF converter, and or decrease the volume of the EMI filter or avoid using an EMI filter referred in conventional technology.
Although only five embodiments of the VF converter from the first aspect of the present application are illustrated, the protective scope of the present application is not limited to the above embodiments but defined by the appended claims. For some kind of the VF converters, the crossover frequency may be affected by the load connected to the VF converters; therefore a range of the crossover frequency may be determined according to the range of the load connected to the VF converter. The frequency of the continuous interfering signal generated by the adjusting unit 106 is higher than a maximum crossover frequency in the range of the crossover frequency, namely continuous jitter on the operating frequency thereof may be realized in the range of the load connected to the VF converter. Although the embodiments of the VF converter illustrated from the first aspect of the present application are described by taking a DC-DC type VF converter as an example, the VF converter may also be other type of VF converter, such as AC-DC, DC-AC, or AC-AC.
Hereinafter, a VF converter from a second aspect of the present application will be described in details.
In addition to the above embodiments, employing an adjusting unit so as to change a parameter of a power stage circuit module, especially change the parameter of a resonant element in resonance state, the operating frequency on the VF converter may also change continuously, thereby realizing frequency continuously jitter.
More specifically, referring to
On a basis of
Wherein, an adjusting unit 106 is electrically connected to the drain of the power switch 307, the adjusting element is a variable capacitor 1061, and the adjusting element controller is a control circuit 1062. Such a variable capacitor Ct 1061 may be a digital variable capacitor or a solid variable capacitor.
The operation procedure shown in
When the resonance occurs, the resonant frequency fm may be determined by an oscillation between the magnetizing inductor L and a parasitic capacitor Ci of the drain of the power switch 307, i.e. fm=1/T.
T=2π√{square root over (L·Ci)} (1)
Wherein T is an operating cycle. Herein, by employing a variable capacitor which capacitance is controllable set at the drain of the switch, the equivalent parasitic capacitor Ci of the power switch may change, so that the whole resonant time Tosc may be changed by changing the resonant frequency fm and finally an on-off cycle may change. An embodiment could be described based on the variable capacitor illustrated in
On a basis of
In series or parallel connection LLC resonant circuit, an on-off frequency varies with the resonant frequency, and the on-off frequency is namely the operating frequency of the VF converter.
The resonant frequency is relevant to resonance parameters of resonant elements in the resonant circuit; therefore, if capacitance of the resonant capacitor Cs is able to change continuously, the resonant frequency may change continuously, so that the operating frequency of the LLC converter may change continuously.
An adjusting element is a variable capacitor Ct connected in parallel with the resonant capacitor Cs, the variable capacitor Ct may be a digital variable capacitor or a solid variable capacitor. An adjusting element controller is a control circuit, the capacitance of the variable capacitor Ct changes with time under the control of the control circuit. As shown in
The following will disclose another embodiment, in addition to embodiment disclosed above. Continuously changing inductance of a resonant inductor Ls could also reach the purpose of changing the resonant frequency, so as to change the on-off frequency of the VF converter and realize frequency jitter. As shown in
In the present embodiment, an adjusting element is a variable inductor Lt connected in parallel with a resonant inductance Ls. An adjusting element controller is a control circuit, an inductance of the variable inductor Lt changes with time under the control of the control circuit. As shown in
An adjusting element may comprise a combination of a variable capacitor and a variable inductor. An adjusting element controller controls the parameter of the variable capacitor and the variable inductor to change with time.
For example, the variable inductor Lt and corresponding control circuit thereof as shown in
The method to change parameters of the resonant elements in the power stage circuit module is also applicable to a quasi-resonant buck or boost VF converter, as shown in
The present application may further comprise many other various embodiments in addition to above embodiments. For example, the adjusting unit 106 could set in both the power stage circuit module and the variable frequency signal stage circuit module, so as to realize a VF converter with frequency jitter while input and output keep stable.
The third aspect of the present application discloses an adjusting method for a VF converter, and the adjusting method is as follows.
The VF converter comprises a power stage circuit module and a variable frequency signal stage circuit module. The variable frequency signal stage circuit module and the power stage circuit module are connected to form a closed-loop circuit system. The adjusting method comprises: setting an adjusting unit in the VF converter, loading a continuous interfering signal into signal inputted to the power stage circuit module by the variable frequency signal stage circuit module through the adjusting unit, so as to cause output of the VF converter to jitter in pre-set range and expand operating frequency range of the VF converter. The frequency of the continuous interfering signal is higher than a crossover frequency of the closed-loop circuit system, thereby realizing expansion of the operating frequency range of VF converter. The continuous interfering signal is a voltage waveform or a current waveform whose amplitude could be constant or variable, and the continuous interfering signal could be periodic or non-periodic. Wherein, the adjusting unit could be a jitter signal generator and inputs the continuous interfering signal generated by the jitter signal generator to the variable frequency signal stage circuit module, so as to realize adjusting the signal inputted to the power stage circuit module by the variable frequency signal stage circuit module. The variable frequency signal stage circuit module comprises an input detection stage circuit and a control stage circuit, the input detection stage circuit outputs a signal to the control stage circuit, the adjusting unit may use an adjusting element and a matched adjusting element controller, the adjusting element is connected to the input detection stage circuit, parameters of the adjusting element is controlled to change with time under the control of the adjusting element controller so as to load the continuous interfering signal into the signal of input detection stage circuit transferred to the control stage circuit.
These control methods may be applied in a variety of VF converters which operate in boundary current mode, or discontinuous current mode, and so on, but not limited to those.
The present application may decrease EMI in the VF converter, and decrease the volume of EMI filter or avoid using an EMI filter. In the VF converter, a continuous jitter on the operating frequency is realized so as to average EMI energy, reduce EMI peak value.
The person skilled in the art may also make various modifications without departing from the spirit and scope of the present application defined by the appending claims. Therefore the present application is not only limited to the disclosure as the above, but defined by the scope of the appending claims.
