CN101938161B - Switched charging device with power conversion function - Google Patents

Abstract

The invention discloses a switched charging device with power conversion function, which comprises a power factor regulating circuit, a rechargeable processor circuit and more than one storage batteries, wherein the power factor regulating circuit is arranged at the power input end and provided with at least a first infinite resonance tank; the rechargeable processor circuit is arranged at the output end of the power factor regulating circuit and electrically connected with the storage batteries; dynamic PFC power factor adjustment resonated with the storage batteries is realized by aid of resonance and damping effects generated by the first infinite resonance tank so as to lead the rechargeable processor circuit capable of resonantly charging the batteries quickly without temperature production in the pattern of output electronic current in frequency adjustment action, and because the charge and discharge paths of the battery are different and the energy consumption problem of the maximum power conversion does not exist, the switched charging device also has the benefits of charging with doubling powers and allowing to charge and discharge simultaneously.

Description

The switch type charging device of tool electric power conversion

Technical field

The present invention relates to a kind of power source charges device, espespecially a kind of switch type charging device of tool electric power conversion.

Background technology

From interchange or the direct current continuity power supply wish battery stores electric power of different kenels, need to see through the power supply processing of charger or charging device, the electric power that meets coupling effectively could be charged to storage battery; Various kenel power supplys, charger or device that generally must be different, these chargers are normally comprised of a PFC power factor regulator and a frequency processor; For example, Fig. 1 is the charging device that in prior art, one is used in AC power (for example civil power), the voltage lifting PFC power factor regulator 12 that should be electrically connected with power input rectifier 11, according to the kenel (resistance) of storage battery 13, to form resonance to produce dynamic impedance matching, and be located at the frequency processor 14 of voltage lifting PFC power factor regulator 12 outputs, the electric current working frequency adjustment for exporting to storage battery 13; Wherein this PFC power factor regulator 12 is to utilize regulation and control chip 120 to trigger the first transistor Q ₁, make input power supply by the first inductance L ₁form and the resonate power supply of (dynamic impedance matching) of storage battery 13, this frequency processor 14, utilizes a frequency modulation chip 140 to trigger a transistor Q ₂, make the power supply after power factor (PF) is adjusted, then via the second inductance L ₂the electric current that generation meets storage battery 13 charge frequency charges to storage battery 13; And for example Fig. 2 is the charging device that in prior art, one is used in high-power DC power supply (as fuel cell), and this DC supply input PFC power factor regulator 22 is also to utilize regulation and control chip 220 to trigger a transistor Q ₁, make input power supply by the first inductance L ₁form and the resonate power supply of (dynamic impedance matching) of storage battery 23, the frequency processor 24 that this is located at PFC power factor regulator 22 outputs, utilizes most frequency modulation chips 240,241,242,243 in parallel to trigger respectively most transistor Q ₂, Q ₃, Q ₄, Q ₅, make the power supply after power factor (PF) is adjusted, then through the second inductance L ₂the electric current that generation meets storage battery 23 charge frequency charges to storage battery 23; No matter be alternating current power supply charging device or DC power supply charging device, all have the following disappearance all the time:

The first inductance L of 1.PFC power factor regulator 12 (or 22) ₁all because of with storage battery 13 (or 23) the bad generation back electromotive force that resonates, hinder the normal operation of PFC, in storage battery 13 (or 23) charging process, have instant cut-off or inhale the situation generation less than electric LDO (Low Drop Out);

2. the second inductance L of frequency processor 14 (or 24) ₂, time and have vortex flow phenomenon to produce, and eliminate slowly again, temperature is high again, causes storage battery 13 (or 23) end current drift (off sat) very large, and the unstable situation of charging easily occurs;

3. the first inductance L ₁and second inductance L ₂all can, because of the problem of coil and iron core gap (gap), cause underpower, and easily saturated (not action or reaction), affect charging normal of battery 13 (or 23), or at least cannot reach (power supply) and fill soon.

4. in storage battery 13 (or 23) when charging, is transferred theorem for the maximum power that meets equivalence shown in Fig. 3, adopt the result that current charges mode is charged, the efficiency that responds is poor, electric power stores few (maximum only has half), charging rate is slow, temperature is high (battery is easily damaged), and because of charge and discharge path identical, therefore charge and discharge simultaneously.

Because industry now is very paid attention to the exploitation of new forms of energy, the various Blast Furnace Top Gas Recovery Turbine Unit (TRT) that obtained electric power by energy conversion, often must electric power be stored by accumulate (energy) equipment, just can make the energy obtain the most fully or the most effectively utilize, and charger or the device of excellent properties, high efficiency and safety will be played the part of very important role in the mechanism of this accumulate; And some need the electronic product of Mobile electric power (rechargable battery), there is especially the market demand of battery request quick charge; But, direct current or AC charger or the charging of device to storage battery, the current circuit forming for electric charge, aforementioned multinomial disappearance can be that power source charges is processed the upper difficult technical barrier that improves or solve always, if can make the power supply of charge in batteries is and the electron stream (for the loop of electronics formation) of electric charge opposite direction certainly will can solve or improve the aforementioned every problem that direct current or AC charger or device face of commonly using;

According to the published resonant cabin with infinite order technology of the inventor, can be used to dynamic impedance matching, separate an open system duality difficult problem, favourable nonlinear dynamic system stabilisation, and comprising dynamic factor adjustment, dynamic adaptable damping, adaptability all-pass filter all can obtain complete parsing; There is resonant cabin with infinite order, though the design that power supply is used or charge the battery with the kenel supply load of electron stream has had the beginning of technical breakthrough, but the construction to resonant cabin with infinite order and assembly use, still must further research and develop again, could real overcoming completely commonly use the disappearance in charger or device use.

Summary of the invention

In order to overcome above-mentioned defect, the switch type charging device that the invention provides a kind of tool electric power conversion, can make various power supply to charge in batteries, can not produce filling soon of temperature, and do not have maximum power transfer problem, can when obtaining doubly charging, also allow to discharge simultaneously.

The present invention for the technical scheme that solves its technical problem and adopt is:

Main purpose of the present invention is a kind of switch type charging device of tool electric power conversion, comprises a step-down PFC power factor (PF) Circuit tuning, a charging process device circuit and at least one storage battery, the power input that this step-down PFC power factor (PF) Circuit tuning sees through a rectifier and AC power is electrically connected, and resonant cabin with infinite order, one first diode and in parallel between the first transistor and resonant cabin with infinite order that the IC chip, that the first transistor, that this step-down PFC power factor (PF) Circuit tuning has an electric connection rectifier triggers the first transistor is electrically connected in series the first transistor is connected in parallel on the first electric capacity of resonant cabin with infinite order output, this charging process device circuit comprises one second diode and one the 3rd electric capacity that are connected in parallel on step-down PFC power factor (PF) Circuit tuning output, the 3rd capacitance series have one and second diode form the second inductance of shunt circuit, and on the shunt circuit between this second diode and this second inductance, be also serially connected with by a transistor seconds of one the 2nd IC chip triggering, the output that this storage battery (can be and fill soon lithium battery) sees through charging process device circuit and step-down PFC power factor (PF) Circuit tuning is electrically connected, and this storage battery and the 3rd Capacitance parallel connection, wherein, the resonant cabin with infinite order of this step-down PFC power factor (PF) Circuit tuning is connected in series mutually by an inductance in parallel one first electrical damper and one second electric capacity are formed, the AC power rectification of rectifier to power input input like this, the one IC chip of step-down PFC power factor (PF) Circuit tuning triggers the action of the first transistor, the resonance producing by resonant cabin with infinite order, damping effect reaches the dynamic PFC power factor (PF) adjustment with storage battery resonance, this makes the 2nd IC chip of charging process device circuit in the frequency adjustment action that triggers transistor seconds, the kenel with output electron stream that can resonate does not produce temperature quick charge to storage battery, and due to the charge and discharge path difference of storage battery and the energy consumption issues that does not have maximum power to transfer, therefore also have, doubly can charge and allow the benefit of charge and discharge simultaneously.

An of the present invention object is to provide a kind of switch type charging device of tool electric power conversion, comprises a voltage lifting PFC power factor (PF) Circuit tuning, a charging process device circuit and at least one storage battery, the power input of this voltage lifting PFC power factor (PF) Circuit tuning and DC power supply (for example small-sized solar battery) is electrically connected, and this voltage lifting PFC power factor (PF) Circuit tuning has the first diode that resonant cabin with infinite order, that the diode, of a power input in parallel be connected in series with power input one utmost point after diode be connected in series with resonant cabin with infinite order, a first transistor in parallel, IC chip, of a triggering the first transistor between resonant cabin with infinite order and the first diode and goes out to hold the first electric capacity of parallel connection at the first diode, this charging process device circuit comprises one second diode and one the 3rd electric capacity that are connected in parallel on voltage lifting PFC power factor (PF) Circuit tuning output, the 3rd capacitance series have one and second diode form the second inductance of shunt circuit, and on the shunt circuit between this second diode and this second inductance, be also serially connected with by a transistor seconds of one the 2nd IC chip triggering, the output that this storage battery (can be and fill soon lithium battery) sees through charging process device circuit and voltage lifting PFC power factor (PF) Circuit tuning is electrically connected, and this storage battery and the 3rd Capacitance parallel connection, wherein, one first electrical damper and one second electric capacity that the resonant cabin with infinite order of this voltage lifting PFC power factor (PF) Circuit tuning is connected in series mutually by one first inductance in parallel are formed, DC power supply is inputted by power input like this, the one IC chip of voltage lifting PFC power factor (PF) Circuit tuning triggers the action of the first transistor, the resonance producing by resonant cabin with infinite order, damping effect reaches the dynamic PFC power factor (PF) adjustment with storage battery resonance, this makes the 2nd IC chip of charging process device circuit in the frequency adjustment action that triggers transistor seconds, the kenel with output electron stream that can resonate does not produce temperature quick charge to storage battery, and due to the charge and discharge path difference of storage battery and the energy consumption issues that does not have maximum power to transfer, therefore also have, doubly can charge and allow the benefit of charge and discharge simultaneously, the output of above-mentioned voltage lifting PFC power factor (PF) Circuit tuning is also parallel with a step-down PFC power factor (PF) Circuit tuning another input as charging process device circuit again, the power input that this step-down PFC power factor (PF) Circuit tuning sees through a rectifier and AC power (can be civil power) is electrically connected, and the 3rd transistor, that this step-down PFC power factor (PF) Circuit tuning has an electric connection rectifier triggers the 3rd IC chip of the 3rd crystal, the electric capacity the 4th that electrical serial connection the 3rd transistorized second resonant cabin with infinite order, the 3rd diode and in parallel between the 3rd transistor AND gate the second resonant cabin with infinite order is connected in parallel on the second resonant cabin with infinite order output, one second electrical damper and one the 5th electric capacity that described the second resonant cabin with infinite order is connected in series mutually by one the 3rd inductance in parallel are formed, power input input ac power is through reorganizer rectification like this, the 3rd IC chip of step-down PFC power factor (PF) Circuit tuning triggers the 3rd transistorized action, the resonance that utilizes the second resonant cabin with infinite order to produce, damping effect reaches the dynamic PFC power factor (PF) adjustment with storage battery resonance, make the 2nd IC chip of charging process device circuit in the frequency adjustment action that triggers transistor seconds, also the kenel with output electron stream of resonance does not produce doubly filling soon of temperature to storage battery, and allow to discharge simultaneously, according to this when DC power supply input has storage battery (P, the N utmost point) electric discharge that (load) electricity shortage situation occurs to charge in batteries, the in good time input that obtains the AC power such as civil power is made electric power and is supplemented.

A further object of the present invention is a kind of switch type charging device of tool electric power conversion, comprises a step-down PFC power factor (PF) Circuit tuning, high-power charging process device circuit and first and second group storage battery, the power input that this step-down PFC power factor (PF) Circuit tuning sees through a rectifier and high-power ac power is electrically connected, the first transistor, one that described step-down PFC power factor (PF) Circuit tuning has an electric connection rectifier triggers electrically first resonant cabin with infinite order of serial connection the first transistor of an IC chip, of the first transistor, one between the first transistor and the first resonant cabin with infinite order the first diode and in parallel be connected in parallel on the first electric capacity of the first resonant cabin with infinite order output, this high-power charging process device circuit comprises that string is located at one second extreme resonant cabin with infinite order of the output one of step-down PFC power factor (PF) Circuit tuning and is connected in parallel on another one the 3rd extreme resonant cabin with infinite order of output of step-down PFC power factor (PF) Circuit tuning, this second resonant cabin with infinite order sees through one second diode and the first group storage battery one is extremely electrically connected, and between this second resonant cabin with infinite order and the second diode, is also parallel with the transistor seconds being triggered by one the 2nd IC chip, the output one that the 3rd resonant cabin with infinite order sees through a 3rd transistor AND gate step-down PFC power factor (PF) Circuit tuning being triggered by one the 3rd IC chip is extremely electrically connected, and the 3rd resonant cabin with infinite order also sees through one the 3rd diode and the extreme electric connection in parallel of the second group storage battery one, wherein, one first electrical damper and one second electric capacity that described the first resonant cabin with infinite order is connected in series mutually by one first inductance in parallel are formed, and one second electrical damper and the 3rd electric capacity that described the second resonant cabin with infinite order is connected in series mutually by one second inductance in parallel are formed, one the 3rd electrical damper and one the 4th electric capacity that described the 3rd resonant cabin with infinite order is connected in series mutually by one the 3rd inductance in parallel are formed, the high-power ac power rectification of rectifier to power input input like this, the one IC chip of step-down PFC power factor (PF) Circuit tuning triggers the action of the first transistor, the resonance producing by the first resonant cabin with infinite order, damping effect reaches and first, the dynamic PFC power factor (PF) of two group storage battery resonance is adjusted, and the 2nd IC chip of high-power charging process device circuit and the 3rd IC chip trigger respectively transistor seconds and the 3rd transistorized frequency adjustment action, by second, the resonance of three resonant cabin with infinite orders, damping effect produces electrical pumping action, can resonance with electron stream kenel to first, the athermic quick charge of two group storage batteries, due to first, the charge and discharge path of two group storage batteries is different and there is no a maximum power transfer problem, therefore also have, doubly can charge and allow the benefit of charge and discharge simultaneously, in addition, the 3rd inductance of the second inductance of above-mentioned the second resonant cabin with infinite order and the 3rd resonant cabin with infinite order is all by coil and the inductor forming containing the iron core of strong magnetic, the electrical pumping action producing on the second inductance and the 3rd inductance according to this, first and second group storage battery that energy and character are super large capacitor forms coupling, above-mentioned rectifier can be two phase commit device circuit again, provides so the high-power two-phase alternating current power supply of input is carried out to rectification, moreover above-mentioned rectifier also can be three-phase rectifier circuit, there is three utmost point power input: R, S, T utmost point power input, by R, S, the T of R, S, T utmost point power input and high-power three-phase alternating-current power supply, extremely hold electric connection like this, provide according to this power supply that high power three-phase Blast Furnace Top Gas Recovery Turbine Unit (TRT) is sent to carry out rectification.

Another object of the present invention is to provide a kind of switch type charging device of tool electric power conversion, comprises a voltage lifting PFC power factor (PF) Circuit tuning, high-power charging process device circuit and first and second group storage battery, the power input of this voltage lifting PFC power factor (PF) Circuit tuning and high-power DC power supply (for example fuel cell) is electrically connected, this voltage lifting PFC power factor (PF) Circuit tuning has the first resonant cabin with infinite order that the diode, of a power input in parallel is connected in series with power input one utmost point after diode, a diode being connected in series with the first resonant cabin with infinite order, one the first transistor, in parallel between the first resonant cabin with infinite order and diode triggers an IC chip of the first transistor, and one goes out end the first electric capacity in parallel at diode, this high-power charging process device circuit comprises that string is located at one second extreme resonant cabin with infinite order of the output one of voltage lifting PFC power factor (PF) Circuit tuning and is connected in parallel on another one the 3rd extreme resonant cabin with infinite order of output of voltage lifting PFC power factor (PF) Circuit tuning, this second resonant cabin with infinite order sees through one second diode and the extreme electric connection in parallel of the first group storage battery one, and between this second resonant cabin with infinite order and diode, is also parallel with the transistor seconds being triggered by one the 2nd IC chip, the output one that the 3rd resonant cabin with infinite order sees through a 3rd transistor AND gate voltage lifting PFC power factor (PF) Circuit tuning being triggered by one the 3rd IC chip is extremely electrically connected, and the 3rd resonant cabin with infinite order also sees through one the 3rd diode and the extreme electric connection in parallel of the second group storage battery one, wherein, one first electrical damper and one second electric capacity that described the first resonant cabin with infinite order is connected in series mutually by one first inductance in parallel are formed, one second electrical damper and the 3rd electric capacity that described the second resonant cabin with infinite order is connected in series mutually by one second inductance in parallel are formed, and an electrical damper and one the 4th electric capacity that described the 3rd resonant cabin with infinite order is connected in series mutually by one the 3rd inductance in parallel are formed, high-power DC power supply is inputted by power input like this, the one IC chip of voltage lifting PFC power factor (PF) Circuit tuning triggers the action of the first transistor, the resonance producing by the first resonant cabin with infinite order, damping effect reaches and first, the dynamic PFC power factor (PF) of two group storage battery resonance is adjusted, and the 2nd IC chip of high-power charging process device circuit and the 3rd IC chip trigger respectively transistor seconds and the 3rd transistorized frequency adjustment action, by second, the resonance of three resonant cabin with infinite orders, damping effect produces electrical pumping action, can resonance with electron stream kenel to first, the athermic quick charge of two group storage batteries, due to first, the charge and discharge path of two group storage batteries is different and there is no a maximum power transfer problem, therefore also have, doubly can charge and allow the benefit of charge and discharge simultaneously, the 3rd inductance of the second inductance of above-mentioned the second resonant cabin with infinite order and the 3rd resonant cabin with infinite order is all by coil and the inductor forming containing the iron core of strong magnetic again, the electrical pumping action producing on the second inductance and the 3rd inductance according to this, first and second group storage battery that energy and character are super large capacitor forms coupling, again again, the output of above-mentioned voltage lifting PFC power factor (PF) Circuit tuning is also parallel with a step-down PFC power factor (PF) Circuit tuning another input as large power, electrically processor circuit, the power input that this step-down PFC power factor (PF) Circuit tuning sees through a rectifier and high-power ac power is electrically connected, this step-down PFC power factor (PF) Circuit tuning has the 4th transistor of an electric connection rectifier, one triggers the 4th transistorized the 4th IC chip, one is electrically connected the 4th transistorized the 4th resonant cabin with infinite order, the 4th diode and one of one parallel connection between the 4th transistor AND gate the 4th resonant cabin with infinite order is connected in parallel on the 5th electric capacity of the 4th resonant cabin with infinite order output, and one the 4th electrical damper and one the 6th electric capacity that the 4th resonant cabin with infinite order is connected in series mutually by one the 4th inductance in parallel are formed, power input input high-power ac power is through rectifier rectification like this, step-down PFC power factor (PF) Circuit tuning the 4th IC chip triggers the 4th transistorized action, the resonance that utilizes the 4th resonant cabin with infinite order to produce, damping effect reaches and first, the dynamic PFC power factor (PF) of two group storage battery resonance is adjusted, and the 2nd IC chip of high-power charging process device circuit and the 3rd IC chip trigger respectively second, three transistorized frequency adjustment, by second, the resonance of three resonant cabin with infinite orders, damping effect produces electrical pumping action, also resonance with electron stream kenel to first, the athermic quick charge of two group storage batteries, and allow to discharge simultaneously, various high-power generating set (generator) in energy development according to this, no matter be, produce high-power DC power supply or high-power ac power, all can synchronously or divide other quick, stable, safety, doubly can be filled with first, two group storage batteries store or electric discharge is simultaneously used, moreover, the rectifier is here except can be two phase commit device circuit, provide the high-power two-phase alternating current power supply of input is carried out outside rectification, it can also be three-phase rectifier circuit, there is three utmost point power input: R, S, T utmost point power input, by R, S, the T tri-of R, S, T utmost point power input and high-power ac power, extremely hold electric connection like this, provide according to this high power three-phase Blast Furnace Top Gas Recovery Turbine Unit (TRT) (generator) power supply that sends is carried out to rectification.

Another object of the present invention is to provide a kind of switch type charging device of tool electric power conversion, comprises a step-down PFC power factor (PF) Circuit tuning, a high power charging process device circuit and at least one (large-scale) storage battery, the power input that this step-down PFC power factor (PF) Circuit tuning sees through a rectifier and high-power ac power is electrically connected, this step-down PFC power factor (PF) Circuit tuning has the first transistor of an electric connection rectifier, one triggers an IC chip of the first transistor, one is electrically connected in series the first resonant cabin with infinite order of the first transistor, one between the first transistor and the first resonant cabin with infinite order the first diode and in parallel be connected in parallel on the first electric capacity of the first resonant cabin with infinite order output, wherein, one first electrical damper and one second electric capacity that the first resonant cabin with infinite order is connected in series mutually by one first inductance in parallel are formed, this high power charging process device circuit includes a three-phase frequency adjuster, a transducer and a damper, this three-phase frequency adjuster and step-down PFC power factor (PF) Circuit tuning output two utmost points are electrically connected, and this three-phase frequency adjuster has three-phase U, V, W utmost point output, this three-phase U, V, between W utmost point output and step-down PFC power factor (PF) Circuit tuning output the two poles of the earth, be parallel with six be connected in series between two respectively by the transistor of a flip chip control, these six between two serial connection by the transistor of a flip chip control, are followed successively by respectively: second of serial connection, three transistors, the 4th of serial connection, the 6th of five transistors and serial connection, seven transistors, control described each transistorized flip chip correspondence and are followed successively by: second, three IC chips, the 4th, five IC chips and the 6th, seven IC chips, this transducer has three-phase U, V, the three-phase U of W utmost point input and three-phase frequency adjuster, V, W utmost point output is electrically connected, and this three-phase U, V, between W utmost point input and this group storage battery two-stage, be parallel with six diodes that are connected in series between two, these six diodes that are connected in series are between two followed successively by: second of serial connection, three diodes, the 4th of serial connection, the 6th of five diodes and serial connection, seven diodes, this damper is by its U, V, W utmost point link is respectively at the three-phase U of transducer, V, on W utmost point input, be electrically connected, this U, V, W utmost point link is also serially connected with respectively second each other, three, four resonant cabin with infinite orders, wherein second, one second electrical damper and one the 3rd electric capacity that resonant cabin with infinite order is connected in series mutually by one second inductance in parallel are formed, one the 3rd electrical damper and one the 4th electric capacity that the 3rd resonant cabin with infinite order is connected in series mutually by one the 3rd inductance in parallel are formed, the 4th electrical damper and one the 5th electric capacity that the 4th resonant cabin with infinite order is connected in series mutually by one the 4th inductance in parallel are respectively formed, the high-power ac power rectification of rectifier to power input input like this, the one IC chip of step-down PFC power factor (PF) Circuit tuning triggers the action of the first transistor, the resonance producing by the first resonant cabin with infinite order, damping effect reaches the dynamic PFC power factor (PF) adjustment with this group storage battery resonance, and each flip chip corresponding each transistorized frequency adjustment and the three-phase U of triggering respectively on the three-phase frequency adjuster of high power charging process device circuit, V, doubly moving of W utmost point output output electron stream, see through the phase transition of transducer, do not having under the situation of maximum power transfer problem, doubly can quick charge to the athermic high power of this group storage battery with electron stream kenel, and because discharging and recharging path difference, also allow charge and discharge simultaneously, and when electron stream charges to this group storage battery, and due to second of damper, three, four resonant cabin with infinite orders and this group storage battery produce resonance, damping effect, therefore can absorb or eliminate back electromotive force or vortex flow, moreover, above-mentioned rectifier can be three-phase rectifier circuit, there is three utmost point power input: R, S, T utmost point power input, extremely hold electric connection with R, S, the T tri-of high-power three-phase alternating-current power supply like this, provide according to this power supply that high-power large-scale three-phase generation device is sent to carry out rectification.

A further object of the present invention is to provide a kind of switch type charging device of tool electric power conversion, comprises a voltage lifting PFC power factor (PF) Circuit tuning, a high power charging process device circuit and at least one group of (large-scale) storage battery, the power input of this voltage lifting PFC power factor (PF) Circuit tuning and high-power DC power supply (for example fuel cell) is electrically connected, this voltage lifting PFC power factor (PF) Circuit tuning has the diode of a power input in parallel, one the first resonant cabin with infinite order being connected in series with power input one utmost point after diode, one the first diode being connected in series with the first resonant cabin with infinite order, one between the first resonant cabin with infinite order and the first diode the first transistor in parallel, an one IC chip and that triggers the first transistor goes out end the first electric capacity in parallel at the first diode, wherein, one first electrical damper and one second electric capacity that the first resonant cabin with infinite order is connected in series mutually by one first inductance in parallel are formed, this high power charging process device circuit includes a three-phase frequency adjuster, a transducer and a damper, this three-phase frequency adjuster and voltage lifting PFC power factor (PF) Circuit tuning output two utmost points are electrically connected, and this three-phase frequency adjuster has three-phase U, V, W utmost point output, this three-phase U, V, between W utmost point output and voltage lifting PFC power factor (PF) Circuit tuning output the two poles of the earth, be parallel with six be connected in series between two respectively by the transistor of a flip chip control, these six between two serial connection by the transistor of a flip chip control, are followed successively by respectively: second of serial connection, three transistors, the 4th of serial connection, the 6th of five transistors and serial connection, seven transistors, control described each transistorized flip chip correspondence and are followed successively by: second, three IC chips, the 4th, five IC chips and the 6th, seven IC chips, this transducer has three-phase U, V, the three-phase U of W utmost point input and three-phase frequency adjuster, V, W utmost point output is electrically connected, and this three-phase U, V, between W utmost point input and this group storage battery two-stage, be parallel with six diodes that are connected in series between two, these six diodes that are connected in series are between two followed successively by: second of serial connection, three diodes, the 4th of serial connection, the 6th of five diodes and serial connection, seven diodes, this damper is by its U, V, W utmost point link is respectively at the three-phase U of transducer, V, on W utmost point input, be electrically connected, this U, V, W utmost point link is also serially connected with respectively second each other, three, four resonant cabin with infinite orders, wherein second, one second electrical damper and one the 3rd electric capacity that resonant cabin with infinite order is connected in series mutually by one second inductance in parallel are formed, one the 3rd electrical damper and one the 4th electric capacity that the 3rd resonant cabin with infinite order is connected in series mutually by one the 3rd inductance in parallel are formed, the 4th electrical damper and one the 5th electric capacity that the 4th resonant cabin with infinite order is connected in series mutually by one the 4th inductance in parallel are respectively formed, high-power DC power supply is inputted by power input like this, the one IC chip of voltage lifting PFC power factor (PF) Circuit tuning triggers the action of the first transistor, the resonance producing by the first resonant cabin with infinite order, damping effect reaches the dynamic PFC power factor (PF) adjustment with this group storage battery resonance, and each flip chip triggers respectively each transistorized frequency adjustment and three-phase U on the three-phase frequency adjuster of high power charging process device circuit, V, doubly moving of W utmost point output output electron stream, see through the phase transition of transducer, do not having under the situation of maximum power transfer problem, doubly can quick charge to the athermic high power of this group storage battery with electron stream kenel, and because discharging and recharging path difference, also allow charge and discharge simultaneously, and when electron stream charges to this group storage battery, and due to second of damper, three, four resonant cabin with infinite orders and this group storage battery produce resonance, damping effect, therefore can absorb or eliminate back electromotive force or vortex flow, again again, the output of above-mentioned voltage lifting PFC power factor (PF) Circuit tuning is also parallel with a step-down PFC power factor (PF) Circuit tuning another input as high power charging process device circuit, the power input that this step-down PFC power factor (PF) Circuit tuning sees through a rectifier and high-power ac power is electrically connected, this step-down PFC power factor (PF) Circuit tuning has the 8th transistor of an electric connection rectifier, one triggers the 8th transistorized the 8th IC chip, one is electrically connected the 8th transistorized the 5th resonant cabin with infinite order, the 8th diode and one of one parallel connection between the 8th transistor AND gate the 5th resonant cabin with infinite order is connected in parallel on the 6th electric capacity of the 5th resonant cabin with infinite order output, and one the 5th electrical damper and one the 7th electric capacity that the 5th resonant cabin with infinite order is connected in series mutually by one the 5th inductance in parallel are formed, power input input high-power ac power is through rectifier rectification like this, the 8th IC chip of step-down PFC power factor (PF) Circuit tuning triggers the 8th transistorized action, the resonance that utilizes the 5th resonant cabin with infinite order to produce, damping effect reaches the dynamic PFC power factor (PF) adjustment with this group storage battery resonance, and each flip chip triggers respectively each transistorized frequency adjustment and three-phase U on the three-phase frequency adjuster of high power charging process device circuit, V, doubly moving of W utmost point output output electron stream, also be the phase transition that sees through transducer, do not having under the situation of maximum power transfer problem, doubly can quick charge to the athermic high power of this group storage battery and permit electric discharge simultaneously with electron stream kenel, and be also by second of damper, three, four resonant cabin with infinite orders and this group storage battery produce resonance, damping effect, absorb or elimination back electromotive force or vortex flow, each high-power large-scale Blast Furnace Top Gas Recovery Turbine Unit (TRT) in energy development according to this, no matter be, produce high-power DC power supply or high-power ac power, all can synchronously or distinguish fast, stable, safety, doubly energy is stored or electric discharge use simultaneously by batteries, moreover, the rectifier here can be three-phase rectifier circuit, there is three utmost point power input: R, S, T utmost point power input, extremely hold electric connection with R, S, the T tri-of high-power three-phase alternating-current power supply like this, provide according to this power supply that high-power large-scale three-phase generation device is sent to carry out rectification.

The invention has the beneficial effects as follows: power factor (PF) Circuit tuning is located at power input to there is at least one the first resonant cabin with infinite order; Charging process device circuit is located at power factor (PF) Circuit tuning output and storage battery forms electric connection; Resonance, the damping effect that mat the first resonant cabin with infinite order produces reaches the dynamic PFC power factor (PF) adjustment with storage battery resonance, make charging process device circuit in the adjustment action of frequency, the kenel with output electron stream that can resonate does not produce temperature quick charge to storage battery, and due to the charge and discharge path difference of storage battery and the energy consumption issues that does not have maximum power to transfer, therefore also have, doubly can charge and allow the benefit of charge and discharge simultaneously.

Accompanying drawing explanation

The continuity alternating current power supply charging device circuit schematic diagram that Fig. 1 is original technology that the present invention contrasts;

The high power CW DC power supply charging device circuit diagram that Fig. 2 is original technology that the present invention contrasts;

Fig. 3 is the schematic equivalent circuit of maximum power transfer;

Fig. 4 is first embodiment of the invention structure circuit diagram;

Fig. 5 is second embodiment of the invention structure circuit diagram;

Fig. 6 is another structure circuit diagram of second embodiment of the invention;

Fig. 7 is third embodiment of the invention structure circuit diagram;

Fig. 8 is another structure circuit diagram of third embodiment of the invention;

Fig. 9 is fourth embodiment of the invention structure circuit diagram;

Figure 10 is another structure circuit diagram of fourth embodiment of the invention;

Figure 11 is fifth embodiment of the invention structure circuit diagram;

Figure 12 is another structure circuit diagram of fifth embodiment of the invention;

Figure 13 is sixth embodiment of the invention structure circuit diagram;

Figure 14 is another structure circuit diagram of sixth embodiment of the invention;

[explanation of part element numbers]

11---rectifier; 12,22---PFC power factor regulator;

120,220---regulation and control chip; 13,23---storage battery;

14,24---frequency processor;

Q ₁, Q ₂, Q ₃, Q ₄, Q ₅---first, second, third and fourth, five transistors;

L ₁, L ₂---first and second inductance;

140,240,241,242,243---frequency modulation chip.

Embodiment

Embodiment: use after storing for the electric power that in industry, various energy source electric generating devices send, or the storage battery that general electric power energy battery stores action is used is stable, safety, doubly can, fill and allow the demand of discharging while charge soon, the present invention is by reaching these objects and usefulness with each embodiment.

The first embodiment: a kind of switch type charging device of tool electric power conversion, as Fig. 4, comprises a step-down PFC power factor (PF) Circuit tuning 30, a charging process device circuit 40 and at least one storage battery 50; This step-down PFC power factor (PF) Circuit tuning 30 sees through a rectifier 60 and is electrically connected with the power input 71 of AC power 70, and this step-down PFC power factor (PF) Circuit tuning 30 has the first transistor Q of an electric connection rectifier 60 ₁, one trigger the first transistor Q ₁electrically serial connection the first transistor Q of an IC chip 31, ₁resonant cabin with infinite order 32, at the first transistor Q ₁with the first diode D in parallel between resonant cabin with infinite order 32 ₁and first capacitor C that is connected in parallel on resonant cabin with infinite order 32 outputs ₁; This charging process device circuit 40 comprises the one second diode D that is connected in parallel on step-down PFC power factor (PF) Circuit tuning 30 outputs ₂and one the 3rd capacitor C ₃, the 3rd capacitor C ₃be serially connected with one and the second diode D ₂form the second inductance L of shunt circuit ₂, and this second diode D ₂with this second inductance L ₂between shunt circuit on be also serially connected with a transistor seconds Q who is triggered by one the 2nd IC chip 41 ₂; This storage battery 50 (can be and fill soon lithium battery) sees through charging process device circuit 40 and is electrically connected with the output of step-down PFC power factor (PF) Circuit tuning 30, and this storage battery 50 and the 3rd capacitor C ₃in parallel; Wherein, the resonant cabin with infinite order 32 of this step-down PFC power factor (PF) Circuit tuning 30 is by an inductance L ₁one first electrical damper Xu of serial connection mutually in parallel ₁and one second capacitor C ₂institute forms; AC power 70 rectifications that rectifier 60 is inputted power input 71 like this, an IC chip 31 of step-down PFC power factor (PF) Circuit tuning 30 triggers the first transistor Q ₁action, the resonance producing by resonant cabin with infinite order 32, damping effect reach the dynamic PFC power factor (PF) adjustment of resonating with storage battery 50, this 2nd IC chip 41 that makes charging process device circuit 40 is triggering transistor seconds Q ₂frequency adjustment action on, the kenel with output electron stream that can resonate does not produce temperature quick charge to storage battery 50, and due to the charge and discharge path difference of storage battery 50 and the energy consumption issues that does not have maximum power to transfer, therefore also have, doubly can charge and allow the benefit of charge and discharge simultaneously.

The second embodiment: a kind of switch type charging device of tool electric power conversion, as Fig. 5, comprises a voltage lifting PFC power factor (PF) Circuit tuning 30A, a charging process device circuit 40 and at least one storage battery 50; The power input 71A of this voltage lifting PFC power factor (PF) Circuit tuning 30A and DC power supply 70A (for example small-sized solar battery) is electrically connected, and this voltage lifting PFC power factor (PF) Circuit tuning 30A has the diode D of a power input 71A in parallel ₀, the diode D that continues ₀the first diode D that the resonant cabin with infinite order 32A, being connected in series with power input 71A mono-utmost point is afterwards connected in series with resonant cabin with infinite order 32A ₁, one at resonant cabin with infinite order 32A and the first diode D ₁between the first transistor Q in parallel ₁, one trigger the first transistor Q ₁an IC chip 31A, at the first diode D ₁go out end the first capacitor C in parallel ₁; This charging process device circuit 40 comprises the one second diode D that is connected in parallel on voltage lifting PFC power factor (PF) Circuit tuning 30A output ₂and one the 3rd capacitor C ₃, the 3rd capacitor C ₃be serially connected with one and the second diode D ₂form the second inductance L of shunt circuit ₂, and this second diode D ₂with this second inductance L ₂between shunt circuit on be also serially connected with a transistor seconds Q who is triggered by one the 2nd IC chip 41 ₂; This storage battery 50 (can be and fill soon lithium battery) sees through charging process device circuit 40 and is electrically connected with the output of voltage lifting PFC power factor (PF) Circuit tuning 30A, and this storage battery 50 and the 3rd capacitor C ₃in parallel; Wherein, the resonant cabin with infinite order 32A of this voltage lifting PFC power factor (PF) Circuit tuning 30A is by one first inductance L ₁one first electrical damper Xu of serial connection mutually in parallel ₁and one second capacitor C ₂institute forms, and DC power supply 70A is inputted by power input 71A like this, and an I C chip 31A of voltage lifting PFC power factor (PF) Circuit tuning 30A triggers the first transistor Q ₁action, the resonance producing by resonant cabin with infinite order 32A, damping effect reach the dynamic PFC power factor (PF) adjustment of resonating with storage battery 50, this 2nd IC chip 41 that makes charging process device circuit 40 is triggering transistor seconds Q ₂frequency adjustment action on, the kenel with output electron stream that can resonate does not produce temperature quick charge to storage battery 50, and due to the charge and discharge path difference of storage battery 50 and the energy consumption issues that does not have maximum power to transfer, therefore also have, doubly can charge and allow the benefit of charge and discharge simultaneously; As Fig. 6, and the output of above-mentioned voltage lifting PFC power factor (PF) Circuit tuning 30A is also parallel with a step-down PFC power factor (PF) Circuit tuning 30B another input as charging process device circuit 40; This step-down PFC power factor (PF) Circuit tuning 30B sees through a rectifier 60 and is electrically connected with the power input 71 of AC power 70 (can be civil power), and this step-down PFC power factor (PF) Circuit tuning 30B has the 3rd transistor Q of an electric connection rectifier 60 ₃, one trigger the 3rd crystal Q ₃electrically serial connection the 3rd transistor Q of the 3rd IC chip 31B, ₃the second resonant cabin with infinite order 32B, at the 3rd transistor Q ₃with the 3rd diode D in parallel between the second resonant cabin with infinite order 32B ₃and electric capacity the 4th C who is connected in parallel on the second resonant cabin with infinite order 32B output ₄; Described the second resonant cabin with infinite order 32B is by one the 3rd inductance L ₃one second electrical damper Xu of serial connection mutually in parallel ₂and one the 5th capacitor C ₅institute forms, and power input 71 input ac powers 70 are through reorganizer 60 rectifications like this, and the 3rd IC chip 31B of step-down PFC power factor (PF) Circuit tuning 30B triggers the 3rd transistor Q ₃action, resonance, the damping effect of utilizing the second resonant cabin with infinite order 32B to produce reaches the dynamic PFC power factor (PF) adjustment of resonating with storage battery 50, the 2nd IC chip 41 that makes charging process device circuit 40 is triggering transistor seconds Q ₂frequency adjustment action upper, also the kenel with output electron stream of resonance does not produce doubly filling soon of temperature to storage battery 50, and allows to discharge simultaneously; While having storage battery 50 (P, the N utmost point) electric discharge that (load) electricity shortage situation occurs when DC power supply 70A input is charged to storage battery 50 according to this, the in good time input that obtains the AC power such as civil power 70 is made electric power and is supplemented.

The 3rd embodiment: as Fig. 7, a kind of switch type charging device of tool electric power conversion, comprises a step-down PFC power factor (PF) Circuit tuning 30, a high-power charging process device circuit 40A and first and second group storage battery 50A, 50B; This step-down PFC power factor (PF) Circuit tuning 30 sees through a rectifier 60 and is electrically connected with the power input 71 of high-power ac power 70, and described step-down PFC power factor (PF) Circuit tuning 30 has the first transistor Q of an electric connection rectifier 60 ₁, one trigger the first transistor Q ₁electrically serial connection the first transistor Q of an IC chip 31, ₁the first resonant cabin with infinite order 32, at the first transistor Q ₁with the first diode D in parallel between the first resonant cabin with infinite order 32 ₁and first capacitor C that is connected in parallel on the first resonant cabin with infinite order 32 outputs ₁; This high-power charging process device circuit 40A comprises that string is located at one second extreme resonant cabin with infinite order 42 of the output one of step-down PFC power factor (PF) Circuit tuning 30 and is connected in parallel on another one the 3rd extreme resonant cabin with infinite order 43 of output of step-down PFC power factor (PF) Circuit tuning 30; This second resonant cabin with infinite order 42 sees through one second diode D ₂extremely be electrically connected with the first group storage battery 50A mono-, and this second resonant cabin with infinite order 42 and the second diode D ₂between be also parallel with by one the 2nd IC chip 41A trigger transistor seconds Q ₂; The 3rd resonant cabin with infinite order 43 sees through a 3rd transistor Q who is triggered by one the 3rd IC chip 41B ₃extremely be electrically connected with the output one of step-down PFC power factor (PF) Circuit tuning 30, and the 3rd resonant cabin with infinite order 43 also sees through one the 3rd diode D ₃with the extreme electric connection in parallel of the second group storage battery 50B mono-; Wherein, described the first resonant cabin with infinite order 32 is by one first inductance L ₁one first electrical damper Xu of serial connection mutually in parallel ₁and one second capacitor C ₂institute forms, and described the second resonant cabin with infinite order 42 is by one second inductance L ₂one second electrical damper Xu of serial connection mutually in parallel ₂and the 3rd capacitor C ₃institute forms, and described the 3rd resonant cabin with infinite order 43 is by one the 3rd inductance L ₃one the 3rd electrical damper Xu of serial connection mutually in parallel ₃and one the 4th capacitor C ₄institute forms; High-power ac power 70 rectifications that rectifier 60 is inputted power input 71 like this, an IC chip 31 of step-down PFC power factor (PF) Circuit tuning 30 triggers the first transistor Q ₁action, resonance, the damping effect producing by the first resonant cabin with infinite order 32 reaches the dynamic PFC power factor (PF) adjustment with first and second group storage battery 50A, 50B resonance, and the 2nd IC chip 41A of high-power charging process device circuit 40A and the 3rd IC chip 41B trigger respectively transistor seconds Q ₂with the 3rd transistor Q ₃frequency adjustment action, by resonance, the damping effect of second and third resonant cabin with infinite order 42,43, produce electrical pumping action, can resonance with electron stream kenel to first and second group storage battery 50A, the athermic quick charge of 50B, because the charge and discharge path of first and second group storage battery 50A, 50B is different and there is no maximum power transfer problem, therefore also there is the benefit that doubly can charge and allow while charge and discharge; And the second inductance L of above-mentioned the second resonant cabin with infinite order 42 ₂and the 3rd inductance L of the 3rd resonant cabin with infinite order 43 ₃all by coil and the inductor forming containing the iron core of strong magnetic, according to this in the second inductance L ₂and the 3rd inductance L ₃on the electrical pumping action that produces, can and character be super large capacitor first and second group storage battery 50A, 50B form coupling; Above-mentioned rectifier 60 can be two phase commit device circuit again, provides so the high-power two-phase alternating current power supply of input is carried out to rectification; As Fig. 8, moreover above-mentioned rectifier is also three-phase rectifier circuit 60A, there is three utmost point power input 71B:R, S, T utmost point power input, by R, S, the T of R, S, T utmost point power input and high-power three-phase alternating-current power supply, extremely hold electric connection like this, provide according to this high power three-phase Blast Furnace Top Gas Recovery Turbine Unit (TRT) power supply that (generator) sends to carry out rectification.

The 4th embodiment: a kind of switch type charging device of tool electric power conversion, as Fig. 9, comprises a voltage lifting PFC power factor (PF) Circuit tuning 30A, a high-power charging process device circuit 40A and first and second group storage battery 50A, 50B; The power input 71C of this voltage lifting PFC power factor (PF) Circuit tuning 30A and high-power DC power supply 70C (for example fuel cell) is electrically connected, and this voltage lifting PFC power factor (PF) Circuit tuning 30A has the diode D of a power input in parallel ₀, the diode D that continues ₀the the first resonant cabin with infinite order 32A, the diode D who is connected in series with the first resonant cabin with infinite order 32A that are connected in series with power input 71C mono-utmost point afterwards ₁, one at the first resonant cabin with infinite order 32A and diode D ₁between the first transistor Q in parallel ₁, one trigger the first transistor Q ₁an IC chip 31A, one at diode D ₁go out end the first capacitor C in parallel ₁; This high-power charging process device circuit 40A comprises that string is located at one second extreme resonant cabin with infinite order 42 of the output one of voltage lifting PFC power factor (PF) Circuit tuning 30 and is connected in parallel on another one the 3rd extreme resonant cabin with infinite order 43 of output of voltage lifting PFC power factor (PF) Circuit tuning 30A; This second resonant cabin with infinite order 42 sees through one second diode D ₂with the extreme electric connection in parallel of the first group storage battery 50A mono-, and this second resonant cabin with infinite order 42 and diode D ₂between be also parallel with by one the 2nd IC chip 41A trigger transistor seconds Q ₂; The 3rd resonant cabin with infinite order 43 sees through a 3rd transistor Q who is triggered by one the 3rd IC chip 41B ₃extremely be electrically connected with the output one of voltage lifting PFC power factor (PF) Circuit tuning 30A, the 3rd resonant cabin with infinite order 43 also sees through one the 3rd diode D ₃with the extreme electric connection in parallel of the second group storage battery 50B mono-; Wherein, described the first resonant cabin with infinite order 32 is by one first inductance L ₁one first electrical damper Xu of serial connection mutually in parallel ₁and one second capacitor C ₂institute forms, and described the second resonant cabin with infinite order 42 is by one second inductance L ₂one second electrical damper Xu of serial connection mutually in parallel ₂and the 3rd capacitor C ₃institute forms, and described the 3rd resonant cabin with infinite order 43 is by one the 3rd inductance L ₃an electrical damper Xu of serial connection mutually in parallel ₃and one the 4th capacitor C ₄institute forms; High-power DC power supply 70C is inputted by power input 71C like this, and an IC chip 31A of voltage lifting PFC power factor (PF) Circuit tuning 30A triggers the first transistor Q ₁action, resonance, the damping effect producing by the first resonant cabin with infinite order reaches the dynamic PFC power factor (PF) adjustment with first and second group storage battery 50A, 50B resonance, and the 2nd IC chip 41A of high-power charging process device circuit 40A and the 3rd IC chip 41B trigger respectively transistor seconds Q ₂with the 3rd transistor Q ₃frequency adjustment action, by resonance, the damping effect of second and third resonant cabin with infinite order 42,43, produce electrical pumping action, can resonance with electron stream kenel to first and second group storage battery 50A, the athermic quick charge of 50B, because the charge and discharge path of first and second group storage battery 50A, 50B is different and there is no maximum power transfer problem, therefore also there is the benefit that doubly can charge and allow while charge and discharge; And the second inductance L of above-mentioned the second resonant cabin with infinite order 42 ₂and the 3rd inductance L of the 3rd resonant cabin with infinite order 43 ₃all by coil and the inductor forming containing the iron core of strong magnetic, according to this in the second inductance L ₂and the 3rd inductance L ₃on the electrical pumping action that produces, can and character be super large capacitor first and second group storage battery 50A, 50B form coupling; Person again, as Figure 10, the output of above-mentioned voltage lifting PFC power factor (PF) Circuit tuning 30A is also parallel with a step-down PFC power factor (PF) Circuit tuning 30B another input as large power, electrically processor circuit 40A, this step-down PFC power factor (PF) Circuit tuning 30B sees through a rectifier 60 and is electrically connected with the power input 71 of high-power ac power 70, and this step-down PFC power factor (PF) Circuit tuning 30B has the 4th transistor Q of an electric connection rectifier 60 ₄, one trigger the 4th transistor Q ₄the 4th IC chip 31B, one be electrically connected the 4th transistor Q ₄the 4th resonant cabin with infinite order 32B, one at the 4th transistor Q ₄with the 4th diode D in parallel between the 4th resonant cabin with infinite order 32B ₄and the 5th capacitor C that is connected in parallel on the 4th resonant cabin with infinite order 32B output ₅, and the 4th resonant cabin with infinite order 32B is by one the 4th inductance L ₄one the 4th electrical damper Xu of serial connection mutually in parallel ₄and one the 6th capacitor C ₆institute forms, and power input 71 is inputted high-power ac power 70 through rectifier 60 rectifications like this, and step-down PFC power factor (PF) Circuit tuning 30B the 4th IC chip 31B triggers the 4th transistor Q ₄action, resonance, the damping effect of utilizing the 4th resonant cabin with infinite order 32B to produce reaches the dynamic PFC power factor (PF) adjustment with first and second group storage battery 50A, 50B resonance, and the 2nd IC chip 41A of high-power charging process device circuit 40A and the 3rd IC chip 41B trigger respectively second and third transistor Q ₂, Q ₃frequency adjustment, by resonance, the damping effect of second and third resonant cabin with infinite order 42,43, produce electrical pumping action, also resonance with electron stream kenel to first and second group storage battery 50A, the athermic quick charge of 50B, and allow to discharge simultaneously, various high-power generating set (generator) in energy development according to this, no matter be to produce high-power DC power supply or high-power ac power, all can be synchronously or point other fast, stable, safety, doubly can be filled with that first and second group storage battery 50A, 50B store or electric discharge use simultaneously; Moreover, the rectifier 60 is here except can be two phase commit device circuit, provide the high-power two-phase alternating current power supply of input is carried out outside rectification, as Figure 11, it can also be three-phase rectifier circuit, there is three utmost point power input 71B:R, S, T utmost point power input, by R, S, the T tri-of R, S, T utmost point power input and high-power ac power, extremely hold electric connection like this, provide according to this high power three-phase Blast Furnace Top Gas Recovery Turbine Unit (TRT) (generator) power supply that sends is carried out to rectification.

The 5th embodiment: a kind of switch type charging device of tool electric power conversion, as Figure 12, comprises a step-down PFC power factor (PF) Circuit tuning 30, a high power charging process device circuit 80 and at least one (large-scale) storage battery 50C, the power input 71B that this step-down PFC power factor (PF) Circuit tuning 30 sees through a rectifier 60A and high-power ac power 70B is electrically connected, and this step-down PFC power factor (PF) Circuit tuning 30 has the first transistor Q of an electric connection rectifier 60A ₁, one trigger the first transistor Q ₁electrically serial connection the first transistor Q of an IC chip 31, ₁the first resonant cabin with infinite order 32, at the first transistor Q ₁with the first diode D in parallel between the first resonant cabin with infinite order 32 ₁and first capacitor C that is connected in parallel on the first resonant cabin with infinite order 32 outputs ₁, wherein, the first resonant cabin with infinite order 32 is by one first inductance L ₁one first electrical damper Xu of serial connection mutually in parallel ₁and one second capacitor C ₂institute forms, this high power charging process device circuit 80 includes a three-phase frequency adjuster 81, a transducer 82 and a damper 83, this three-phase frequency adjuster 81 is electrically connected with step-down PFC power factor (PF) Circuit tuning 30 output two utmost points, this three-phase frequency adjuster 81 has three-phase U, V, W utmost point output, between this three-phase U, V, W utmost point output and step-down PFC power factor (PF) Circuit tuning 30 output the two poles of the earth, be parallel with six be connected in series between two respectively by the transistor of a flip chip control, these six between two serial connection by the transistor of a flip chip control, are followed successively by respectively: second and third transistor Q of serial connection ₂, Q ₃, serial connection fourth, fifth transistor Q ₄, Q ₅the 6th, the seven transistor Q with serial connection ₆, Q ₇controlling described each transistorized flip chip correspondence is followed successively by: second and third IC chip 81A, 81B, fourth, fifth IC chip 81C, 81D and the 6th, seven IC chip 81E, 81F, three-phase U, V, W utmost point output that this transducer 82 has three-phase U, V, W utmost point input and three-phase frequency adjuster 81 are electrically connected, and between this three-phase U, V, W utmost point input and this group storage battery 50C two-stage, be parallel with six diodes that are connected in series between two, these six diodes that are connected in series are between two followed successively by: second and third diode D of serial connection ₂, D ₃, serial connection fourth, fifth diode D ₄, D ₅the 6th, the seven diode D with serial connection ₆, D ₇, this damper 83 is electrically connected respectively by its U, V, W utmost point link on three-phase U, the V of transducer 82, W utmost point input, this U, V, W utmost point link be also serially connected with respectively each other second and third, four resonant cabin with infinite order 83A, 83B, 83C, wherein second, resonant cabin with infinite order 83A is by one second inductance L ₂one second electrical damper Xu of serial connection mutually in parallel ₂and one the 3rd capacitor C ₃institute forms, and the 3rd resonant cabin with infinite order 83B is by one the 3rd inductance L ₃one the 3rd electrical damper Xu of serial connection mutually in parallel ₃and one the 4th capacitor C ₄institute forms, and the 4th resonant cabin with infinite order 83C is respectively by one the 4th inductance L ₄the 4th electrical damper Xu of serial connection mutually in parallel ₄and one the 5th capacitor C ₅institute forms, the high-power ac power rectification of rectifier 60A to power input 71B input like this, an IC chip 31 of step-down PFC power factor (PF) Circuit tuning 30 triggers the first transistor Q ₁action, resonance, the damping effect producing by the first resonant cabin with infinite order 32 reaches the dynamic PFC power factor (PF) adjustment with this group storage battery 50C resonance, and each flip chip 81A on the three-phase frequency adjuster 81 of high power charging process device circuit 80,81B, 81C, 81D, 81E, 81F are corresponding respectively, triggers each transistor Q ₂, Q ₃, Q ₄, Q ₅, Q ₆, Q ₇frequency adjustment and three-phase U, V, doubly moving of W utmost point output output electron stream, see through the phase transition of transducer 82, do not having under the situation of maximum power transfer problem, doubly can quick charge to the athermic high power of this group storage battery 50C with electron stream kenel, and because discharging and recharging path difference, also allow charge and discharge simultaneously, and when electron stream charges to this group storage battery 50C, and due to second of damper 83, three, four resonant cabin with infinite order 83A, 83B, 83C and this group storage battery 50C produce resonance, damping effect, therefore can absorb or eliminate back electromotive force or vortex flow, moreover, above-mentioned rectifier 60A is three-phase rectifier circuit, there is three utmost point power input 71B:R, S, T utmost point power input, extremely hold electric connection with R, S, the T tri-of high-power three-phase alternating-current power supply 70B like this, provide according to this power supply that high-power large-scale three-phase generation device is sent to carry out rectification.

The 6th embodiment: a kind of switch type charging device of tool electric power conversion, comprises a voltage lifting PFC power factor (PF) Circuit tuning 30A, a high power charging process device circuit 80 and at least one group of (large-scale) storage battery 50C, the power input 71C of this voltage lifting PFC power factor (PF) Circuit tuning 30A and high-power DC power supply 70C (for example fuel cell) is electrically connected, and this voltage lifting PFC power factor (PF) Circuit tuning 30A has the diode D of a power input 71C in parallel ₀, the diode D that continues ₀the the first resonant cabin with infinite order 32A, the first diode D who is connected in series with the first resonant cabin with infinite order 32A that are connected in series with power input 71C mono-utmost point afterwards ₁, one at the first resonant cabin with infinite order 32A and the first diode D ₁between the first transistor Q in parallel ₁, one trigger the first transistor Q ₁an IC chip 31A and at the first diode D ₁go out end the first capacitor C in parallel ₁, wherein, the first resonant cabin with infinite order 32 is by one first inductance L ₁one first electrical damper Xu of serial connection mutually in parallel ₁and one second capacitor C ₂institute forms, this high power charging process device circuit 80 includes a three-phase frequency adjuster 81, a transducer 82 and a damper 83, this three-phase frequency adjuster 81 is electrically connected with voltage lifting PFC power factor (PF) Circuit tuning 30A output two utmost points, this three-phase frequency adjuster 81 has three-phase U, V, W utmost point output, between this three-phase U, V, W utmost point output and voltage lifting PFC power factor (PF) Circuit tuning 30A output the two poles of the earth, be parallel with six be connected in series between two respectively by the transistor of a flip chip control, these six between two serial connection by the transistor of a flip chip control, are followed successively by respectively: second and third transistor Q of serial connection ₂, Q ₃, serial connection fourth, fifth transistor Q ₄, Q ₅the 6th, the seven transistor Q with serial connection ₆, Q ₇controlling described each transistorized flip chip correspondence is followed successively by: second and third IC chip 81A, 81B, fourth, fifth IC chip 81C, 81D and the 6th, seven IC chip 81E, 81F, three-phase U, V, W utmost point output that this transducer 82 has three-phase U, V, W utmost point input and three-phase frequency adjuster 81 are electrically connected, and between this three-phase U, V, W utmost point input and this group storage battery 50C two-stage, be parallel with six diodes that are connected in series between two, these six diodes that are connected in series are between two followed successively by: second and third diode D of serial connection ₂, D ₃, serial connection fourth, fifth diode D ₄, D ₅the 6th, the seven diode D with serial connection ₆, D ₇, this damper 83 is electrically connected respectively by its U, V, W utmost point link on three-phase U, the V of transducer 82, W utmost point input, this U, V, W utmost point link be also serially connected with respectively each other second and third, four resonant cabin with infinite order 83A, 83B, 83C, wherein second, resonant cabin with infinite order 83A is by one second inductance L ₂one second electrical damper Xu of serial connection mutually in parallel ₂and one the 3rd capacitor C ₃institute forms, and the 3rd resonant cabin with infinite order 83B is by one the 3rd inductance L ₃one the 3rd electrical damper Xu of serial connection mutually in parallel ₃and one the 4th capacitor C ₄institute forms, and the 4th resonant cabin with infinite order 83C is respectively by one the 4th inductance L ₄the 4th electrical damper Xu of serial connection mutually in parallel ₄and one the 5th capacitor C ₅institute forms, high-power DC power supply 70C is inputted by power input 71C like this, and an IC chip 31A of voltage lifting PFC power factor (PF) Circuit tuning 30A triggers the first transistor Q ₁action, resonance, the damping effect producing by the first resonant cabin with infinite order 32A reaches the dynamic PFC power factor (PF) adjustment with this group storage battery 50C resonance, and on the three-phase frequency adjuster 81 of high power charging process device circuit 80, each flip chip 81A, 81B, 81C, 81D, 81E, 81F trigger respectively each transistor Q ₂, Q ₃, Q ₄, Q ₅, Q ₆, Q ₇frequency adjustment and three-phase U, V, doubly moving of W utmost point output output electron stream, see through the phase transition of transducer 82, do not having under the situation of maximum power transfer problem, doubly can quick charge to the athermic high power of this group storage battery 50C with electron stream kenel, and because discharging and recharging path difference, also allow charge and discharge simultaneously, and when electron stream charges to this group storage battery 50C, and due to second of damper 83, three, four resonant cabin with infinite order 83A, 83B, 83C and this group storage battery 50C produce resonance, damping effect, therefore can absorb or eliminate back electromotive force or vortex flow, person again, as Figure 14, the output of above-mentioned voltage lifting PFC power factor (PF) Circuit tuning 30A is also parallel with a step-down PFC power factor (PF) Circuit tuning 30B another input as high power charging process device circuit 80, the power input 71B that this step-down PFC power factor (PF) Circuit tuning 30B sees through a rectifier 60B and high-power ac power 70B is electrically connected, and this step-down PFC power factor (PF) Circuit tuning 30B has the 8th transistor Q of an electric connection rectifier 60B ₈, one trigger the 8th transistor Q ₈the 8th IC chip 31B, one be electrically connected the 8th transistor Q ₈the 5th resonant cabin with infinite order 32B, at the 8th transistor Q ₈with the 8th diode D in parallel between the 5th resonant cabin with infinite order 32B ₈and the 6th capacitor C that is connected in parallel on the 5th resonant cabin with infinite order 32B output ₆, and the 5th resonant cabin with infinite order 32B is by one the 5th inductance L ₅one the 5th electrical damper Xu of serial connection mutually in parallel ₅and one the 7th capacitor C ₇institute forms, and power input 71B input high-power ac power 70B is through rectifier 60B rectification like this, and the 8th IC chip 31B of step-down PFC power factor (PF) Circuit tuning 30B triggers the 8th transistor Q ₈action, resonance, the damping effect of utilizing the 5th resonant cabin with infinite order 32B to produce reaches the dynamic PFC power factor (PF) adjustment with this group storage battery 50C resonance, and on the three-phase frequency adjuster of high power charging process device circuit 80, each flip chip 81A, 81B, 81C, 81D, 81E, 81F trigger respectively each transistor Q ₂, Q ₃, Q ₄, Q ₅, Q ₆, Q ₇frequency adjustment and three-phase U, V, doubly moving of W utmost point output output electron stream, also be the phase transition that sees through transducer 82, do not having under the situation of maximum power transfer problem, doubly can quick charge to the athermic high power of this group storage battery 50C and permit electric discharge simultaneously with electron stream kenel, and be also by second of damper 83, three, four resonant cabin with infinite order 83A, 83B, 83C and this group storage battery 50C produce resonance, damping effect, absorb or elimination back electromotive force or vortex flow, each high-power large-scale Blast Furnace Top Gas Recovery Turbine Unit (TRT) in energy development according to this, no matter be, produce high-power DC power supply or high-power ac power, all can synchronously or distinguish fast, stable, safety, doubly energy is stored or electric discharge use simultaneously by batteries 50C, person again, as Figure 14, above-mentioned rectifier 60B is three-phase rectifier circuit, there is three utmost point power input 71B:R, S, T utmost point power input, extremely hold electric connection with R, S, the T tri-of high-power three-phase alternating-current power supply 70B like this, provide according to this power supply that high-power large-scale three-phase generation device is sent to carry out rectification.

More than explanation, sincerely belongs to the inventive method preferred embodiment, and the simple and easy change of equivalent method of such as doing with regard to above-described embodiment, must belong to the technology of the present invention category.

Claims (15)

1. a switch type charging device for tool electric power conversion, is characterized in that: comprise a voltage lifting PFC power factor (PF) Circuit tuning (30A), a charging process device circuit (40) and at least one storage battery (50); This voltage lifting PFC power factor (PF) Circuit tuning (30A) is electrically connected with the power input (71A) of DC power supply (70A), and this voltage lifting PFC power factor (PF) Circuit tuning (30A) has the diode (D of a power input in parallel (71A) ₀), the diode (D that continues ₀) rear resonant cabin with infinite order (32A), a first diode (D who is connected in series with resonant cabin with infinite order (32A) who is connected in series with power input (71A) utmost point ₁), one at resonant cabin with infinite order (32A) and the first diode (D ₁) between the first transistor (Q in parallel ₁), one trigger the first transistor (Q ₁) an IC chip (31A), at the first diode (D ₁) go out the first in parallel electric capacity (C of end ₁); This charging process device circuit (40) comprises the one second diode (D that is connected in parallel on voltage lifting PFC power factor (PF) Circuit tuning (30A) output ₂) and one the 3rd electric capacity (C ₃), the 3rd electric capacity (C ₃) be serially connected with one and the second diode (D ₂) form the second inductance (L of shunt circuit ₂), and this second diode (D ₂) and this second inductance (L ₂) between shunt circuit on be also serially connected with by one the 2nd IC chip (41) trigger a transistor seconds (Q ₂); This storage battery (50) sees through charging process device circuit (40) and is electrically connected with the output of voltage lifting PFC power factor (PF) Circuit tuning (30A), and this storage battery (50) and the 3rd electric capacity (C ₃) parallel connection; Wherein, the resonant cabin with infinite order (32A) of this voltage lifting PFC power factor (PF) Circuit tuning (30A) is by one first inductance (L ₁) one first electrical damper (Xu of serial connection mutually in parallel ₁) and one second electric capacity (C ₂) institute form; The output of described voltage lifting PFC power factor (PF) Circuit tuning (30A) is also parallel with a step-down PFC power factor (PF) Circuit tuning (30B) another input as charging process device circuit (40); This step-down PFC power factor (PF) Circuit tuning (30B) sees through a rectifier (60) and is electrically connected with the power input (71) of AC power (70), and this step-down PFC power factor (PF) Circuit tuning (30B) has the 3rd transistor (Q of an electric connection rectifier (60) ₃), one trigger the 3rd crystal (Q ₃) electrically serial connection the 3rd transistor (Q of the 3rd IC chip (31B), ₃) the second resonant cabin with infinite order (32B), at the 3rd transistor (Q ₃) with the second resonant cabin with infinite order (32B) between the 3rd diode (D in parallel ₃) and a 4th electric capacity (C who is connected in parallel on the second resonant cabin with infinite order (32B) output ₄); Described the second resonant cabin with infinite order (32B) is by one the 3rd inductance (L ₃) one second electrical damper (Xu of serial connection mutually in parallel ₂) and one the 5th electric capacity (C ₅) institute form.

2. a switch type charging device for tool electric power conversion, is characterized in that: comprise a step-down PFC power factor (PF) Circuit tuning (30), a high-power charging process device circuit (40A) and first and second group storage battery (50A, 50B); This step-down PFC power factor (PF) Circuit tuning (30) sees through a rectifier (60) and is electrically connected with the power input (71) of high-power ac power (70), and described step-down PFC power factor (PF) Circuit tuning (30) has the first transistor (Q of an electric connection rectifier (60) ₁), one trigger the first transistor (Q ₁) electrically serial connection the first transistor (Q of an IC chip (31), ₁) the first resonant cabin with infinite order (32), one at the first transistor (Q ₁) with the first resonant cabin with infinite order (32) between the first diode (D in parallel ₁) and a first electric capacity (C who is connected in parallel on the first resonant cabin with infinite order (32) output ₁); This high-power charging process device circuit (40A) comprises that string is located at one second extreme resonant cabin with infinite order (42) of the output one of step-down PFC power factor (PF) Circuit tuning (30) and is connected in parallel on another one the 3rd extreme resonant cabin with infinite order (43) of output of step-down PFC power factor (PF) Circuit tuning (30); This second resonant cabin with infinite order (42) sees through one second diode (D ₂) be extremely electrically connected with the first group storage battery (50A), and this second resonant cabin with infinite order (42) and the second diode (D ₂) between be also parallel with by one the 2nd IC chip (41A) trigger transistor seconds (Q ₂); The 3rd resonant cabin with infinite order (43) sees through a 3rd transistor (Q who is triggered by one the 3rd IC chip (41B) ₃) be extremely electrically connected with the output one of step-down PFC power factor (PF) Circuit tuning (30), and the 3rd resonant cabin with infinite order (43) also sees through one the 3rd diode (D ₃) with the extreme electric connection in parallel of the second group storage battery (50B); Wherein, described the first resonant cabin with infinite order (32) is by one first inductance (L ₁) one first electrical damper (Xu of serial connection mutually in parallel ₁) and one second electric capacity (C ₂) institute forms, and described the second resonant cabin with infinite order (42) is by one second inductance (L ₂) one second electrical damper (Xu of serial connection mutually in parallel ₂) and the 3rd electric capacity (C ₃) institute form, described the 3rd resonant cabin with infinite order (43) is by one the 3rd inductance (L ₃) one the 3rd electrical damper (Xu of serial connection mutually in parallel ₃) and one the 4th electric capacity (C ₄) institute form.

3. the switch type charging device of tool electric power conversion according to claim 2, is characterized in that: the second inductance (L of described the second resonant cabin with infinite order (42) ₂) and the 3rd inductance (L of the 3rd resonant cabin with infinite order (43) ₃) be all by coil and the inductor forming containing the iron core of strong magnetic.

4. the switch type charging device of tool electric power conversion according to claim 2, is characterized in that: described rectifier (60) is two phase commit device circuit.

5. the switch type charging device of tool electric power conversion according to claim 2, is characterized in that: described rectifier is three-phase rectifier circuit (60A) having three utmost point power inputs (71B): R, S, T utmost point power input.

6. the switch type charging device of a tool electric power conversion, it is characterized in that: comprise a voltage lifting PFC power factor (PF) Circuit tuning (30A), a high-power charging process device circuit (40A) and first and second group storage battery (50A, 50B); This voltage lifting PFC power factor (PF) Circuit tuning (30A) is electrically connected with the power input (71C) of high-power DC power supply (70C), and this voltage lifting PFC power factor (PF) Circuit tuning (30A) has the diode (D of a power input in parallel ₀), the diode (D that continues ₀) rear the first resonant cabin with infinite order (32A), a diode (D who is connected in series with the first resonant cabin with infinite order (32A) who is connected in series with power input (71C) utmost point ₁), one at the first resonant cabin with infinite order (32A) and diode (D ₁) between the first transistor (Q in parallel ₁), one trigger the first transistor (Q ₁) an IC chip (31A), one at diode (D ₁) go out the first in parallel electric capacity (C of end ₁); This high-power charging process device circuit (40A) comprises that string is located at one second extreme resonant cabin with infinite order (42) of the output one of voltage lifting PFC power factor (PF) Circuit tuning (30A) and is connected in parallel on another one the 3rd extreme resonant cabin with infinite order (43) of output of voltage lifting PFC power factor (PF) Circuit tuning (30A); This second resonant cabin with infinite order (42) sees through one second diode (D ₂) with the extreme electric connection in parallel of the first group storage battery (50A), and this second resonant cabin with infinite order (42) and diode (D ₂) between be also parallel with by one the 2nd IC chip (41A) trigger transistor seconds (Q ₂); The 3rd resonant cabin with infinite order (43) sees through a 3rd transistor (Q who is triggered by one the 3rd IC chip (41B) ₃) be extremely electrically connected with the output one of voltage lifting PFC power factor (PF) Circuit tuning (30A), the 3rd resonant cabin with infinite order (43) also sees through one the 3rd diode (D ₃) with the extreme electric connection in parallel of the second group storage battery (50B); Wherein, described the first resonant cabin with infinite order (32) is by one first inductance (L ₁) one first electrical damper (Xu of serial connection mutually in parallel ₁) and one second electric capacity (C ₂) institute form, described the second resonant cabin with infinite order (42) is by one second inductance (L ₂) one second electrical damper (Xu of serial connection mutually in parallel ₂) and the 3rd electric capacity (C ₃) institute form, described the 3rd resonant cabin with infinite order (43) is by one the 3rd inductance (L ₃) an electrical damper (Xu of serial connection mutually in parallel ₃) and one the 4th electric capacity (C ₄) institute form.

7. the switch type charging device of tool electric power conversion according to claim 6, is characterized in that: the second inductance (L of described the second resonant cabin with infinite order (42) ₂) and the 3rd inductance (L of the 3rd resonant cabin with infinite order (43) ₃) be all by coil and the inductor forming containing the iron core of strong magnetic.

8. the switch type charging device of tool electric power conversion according to claim 6, it is characterized in that: the output of described voltage lifting PFC power factor (PF) Circuit tuning (30A) is also parallel with a step-down PFC power factor (PF) Circuit tuning (30B) another input as large power, electrically processor circuit (40A), this step-down PFC power factor (PF) Circuit tuning (30B) sees through a rectifier (60) and is electrically connected with the power input (71) of high-power ac power (70), this step-down PFC power factor (PF) Circuit tuning (30B) has the 4th transistor (Q of an electric connection rectifier (60) ₄), one trigger the 4th transistor (Q ₄) the 4th IC chip (31B), one be electrically connected the 4th transistor (Q ₄) the 4th resonant cabin with infinite order (32B), one at the 4th transistor (Q ₄) with the 4th resonant cabin with infinite order (32B) between the 4th diode (D in parallel ₄) and a 5th electric capacity (C who is connected in parallel on the 4th resonant cabin with infinite order (32B) output ₅), and the 4th resonant cabin with infinite order (32B) is by one the 4th inductance (L ₄) one the 4th electrical damper (Xu of serial connection mutually in parallel ₄) and one the 6th electric capacity (C ₆) institute form.

9. the switch type charging device of tool electric power conversion according to claim 8, is characterized in that: described rectifier (60) is two phase commit device circuit.

10. the switch type charging device of tool electric power conversion according to claim 8, is characterized in that: described rectifier (60) is three-phase rectifier circuit, has three utmost point power inputs (71B): R, S, T utmost point power input.

The switch type charging device of 11. 1 kinds of tool electric power conversions, is characterized in that: comprise a step-down PFC power factor (PF) Circuit tuning (30), a high power charging process device circuit (80) and at least one storage battery (50C), this step-down PFC power factor (PF) Circuit tuning (30) sees through a rectifier (60A) and is electrically connected with the power input (71B) of high-power ac power (70B), and this step-down PFC power factor (PF) Circuit tuning (30) has the first transistor (Q of an electric connection rectifier (60A) ₁), one trigger the first transistor (Q ₁) electrically serial connection the first transistor (Q of an IC chip (31), ₁) the first resonant cabin with infinite order (32), at the first transistor (Q ₁) with the first resonant cabin with infinite order (32) between the first diode (D in parallel ₁) and a first electric capacity (C who is connected in parallel on the first resonant cabin with infinite order (32) output ₁), wherein, the first resonant cabin with infinite order (32) is by one first inductance (L ₁) one first electrical damper (Xu of serial connection mutually in parallel ₁) and one second electric capacity (C ₂) institute form, this high power charging process device circuit (80) includes a three-phase frequency adjuster (81), a transducer (82) and a damper (83), this three-phase frequency adjuster (81) is electrically connected with step-down PFC power factor (PF) Circuit tuning (30) output two utmost points, this three-phase frequency adjuster (81) has three-phase U, V, W utmost point output, between this three-phase U, V, W utmost point output and step-down PFC power factor (PF) Circuit tuning (30) output the two poles of the earth, be parallel with six be connected in series between two respectively by the transistor of a flip chip control, these six between two serial connection by the transistor of a flip chip control, are followed successively by respectively: second and third transistor (Q of serial connection ₂, Q ₃), serial connection fourth, fifth transistor (Q ₄, Q ₅) and serial connection the 6th, seven transistor (Q ₆, Q ₇), controlling described each transistorized flip chip correspondence is followed successively by: second, three IC chip (81A, 81B), the 4th, five IC chip (81C, the 81D) He six, seven IC chip (81E, 81F), this transducer (82) has three-phase U, V, the three-phase U of W utmost point input and three-phase frequency adjuster (81), V, W utmost point output is electrically connected, and this three-phase U, V, between W utmost point input and this storage battery (50C) two-stage, be parallel with six diodes that are connected in series between two, these six diodes that are connected in series are between two followed successively by: second of serial connection, three diode (D ₂, D ₃), serial connection fourth, fifth diode (D ₄, D ₅) and serial connection the 6th, seven diode (D ₆, D ₇), this damper (83) is electrically connected respectively by its U, V, W utmost point link on three-phase U, the V of transducer (82), W utmost point input, this U, V, W utmost point link be also serially connected with respectively each other second and third, four resonant cabin with infinite orders (83A, 83B, 83C), wherein the second resonant cabin with infinite order (83A) is by one second inductance (L ₂) one second electrical damper (Xu of serial connection mutually in parallel ₂) and one the 3rd electric capacity (C ₃) institute form, the 3rd resonant cabin with infinite order (83B) is by one the 3rd inductance (L ₃) one the 3rd electrical damper (Xu of serial connection mutually in parallel ₃) and one the 4th electric capacity (C ₄) institute form, the 4th resonant cabin with infinite order (83C) is respectively by one the 4th inductance (L ₄) the 4th electrical damper (Xu of serial connection mutually in parallel ₄) and one the 5th electric capacity (C ₅) institute form.

The switch type charging device of 12. tool electric power conversions according to claim 11, is characterized in that: described rectifier (60A) is three-phase rectifier circuit, has three utmost point power inputs (71B): R, S, T utmost point power input.

The switch type charging device of 13. 1 kinds of tool electric power conversions, is characterized in that: comprise a voltage lifting PFC power factor (PF) Circuit tuning (30A), a high power charging process device circuit (80) and at least one group storage battery (50C), this voltage lifting PFC power factor (PF) Circuit tuning (30A) is electrically connected with the power input (71C) of high-power DC power supply (70C), and this voltage lifting PFC power factor (PF) Circuit tuning (30A) has the diode (D of a power input in parallel (71C) ₀), the diode (D that continues ₀) rear the first resonant cabin with infinite order (32A), a first diode (D who is connected in series with the first resonant cabin with infinite order (32A) who is connected in series with power input (71C) utmost point ₁), one at the first resonant cabin with infinite order (32A) and the first diode (D ₁) between the first transistor (Q in parallel ₁), one trigger the first transistor (Q ₁) an IC chip (31A) and at the first diode (D ₁) go out the first in parallel electric capacity (C of end ₁), wherein, the first resonant cabin with infinite order (32) is by one first inductance (L ₁) one first electrical damper (Xu of serial connection mutually in parallel ₁) and one second electric capacity (C ₂) institute form, this high power charging process device circuit (80) includes a three-phase frequency adjuster (81), a transducer (82) and a damper (83), this three-phase frequency adjuster (81) is electrically connected with voltage lifting PFC power factor (PF) Circuit tuning (30A) output two utmost points, this three-phase frequency adjuster (81) has three-phase U, V, W utmost point output, between this three-phase U, V, W utmost point output and voltage lifting PFC power factor (PF) Circuit tuning (30A) output the two poles of the earth, be parallel with six be connected in series between two respectively by the transistor of a flip chip control, these six between two serial connection by the transistor of a flip chip control, are followed successively by respectively: second and third transistor (Q of serial connection ₂, Q ₃), serial connection fourth, fifth transistor (Q ₄, Q ₅) and serial connection the 6th, seven transistor (Q ₆, Q ₇), controlling described each transistorized flip chip correspondence is followed successively by: second, three IC chip (81A, 81B), the 4th, five IC chip (81C, the 81D) He six, seven IC chip (81E, 81F), this transducer (82) has three-phase U, V, the three-phase U of W utmost point input and three-phase frequency adjuster (81), V, W utmost point output is electrically connected, and this three-phase U, V, between W utmost point input and this group storage battery (50C) two-stage, be parallel with six diodes that are connected in series between two, these six diodes that are connected in series are between two followed successively by: second of serial connection, three diode (D ₂, D ₃), serial connection fourth, fifth diode (D ₄, D ₅) and serial connection the 6th, seven diode (D ₆, D ₇), this damper (83) is electrically connected respectively by its U, V, W utmost point link on three-phase U, the V of transducer (82), W utmost point input, this U, V, W utmost point link be also serially connected with respectively each other second and third, four resonant cabin with infinite orders (83A, 83B, 83C), wherein the second resonant cabin with infinite order (83A) is by one second inductance (L ₂) one second electrical damper (Xu of serial connection mutually in parallel ₂) and one the 3rd electric capacity (C ₃) institute form, the 3rd resonant cabin with infinite order (83B) is by one the 3rd inductance (L ₃) one the 3rd electrical damper (Xu of serial connection mutually in parallel ₃) and one the 4th electric capacity (C ₄) institute form, the 4th resonant cabin with infinite order (83C) is respectively by one the 4th inductance (L ₄) the 4th electrical damper (Xu of serial connection mutually in parallel ₄) and one the 5th electric capacity (C ₅) institute form.

The switch type charging device of 14. tool electric power conversions according to claim 13, it is characterized in that: the output of described voltage lifting PFC power factor (PF) Circuit tuning (30A) is also parallel with a step-down PFC power factor (PF) Circuit tuning (30B) another input as high power charging process device circuit (80), this step-down PFC power factor (PF) Circuit tuning (30B) sees through a rectifier (60B) and is electrically connected with the power input (71B) of high-power ac power (70B), this step-down PFC power factor (PF) Circuit tuning (30B) has the 8th transistor (Q of an electric connection rectifier (60B) ₈), one trigger the 8th transistor (Q ₈) the 8th IC chip (31B), one be electrically connected the 8th transistor (Q ₈) the 5th resonant cabin with infinite order (32B), at the 8th transistor (Q ₈) with the 5th resonant cabin with infinite order (32B) between the 8th diode (D in parallel ₈) and a 6th electric capacity (C who is connected in parallel on the 5th resonant cabin with infinite order (32B) output ₆), and the 5th resonant cabin with infinite order (32B) is by one the 5th inductance (L ₅) one the 5th electrical damper (Xu of serial connection mutually in parallel ₅) and one the 7th electric capacity (C ₇) institute form.

The switch type charging device of 15. tool electric power conversions according to claim 14, is characterized in that: described rectifier (60B) is three-phase rectifier circuit, has three utmost point power inputs (71B): R, S, T utmost point power input.

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