CN203942314U - Electric energy feedback type battery charging and discharging and partial volume equipment - Google Patents
Electric energy feedback type battery charging and discharging and partial volume equipment Download PDFInfo
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- CN203942314U CN203942314U CN201420329880.2U CN201420329880U CN203942314U CN 203942314 U CN203942314 U CN 203942314U CN 201420329880 U CN201420329880 U CN 201420329880U CN 203942314 U CN203942314 U CN 203942314U
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- 238000007600 charging Methods 0.000 title claims abstract description 90
- 238000007599 discharging Methods 0.000 title claims abstract description 71
- 238000002955 isolation Methods 0.000 claims abstract description 81
- 230000002441 reversible effect Effects 0.000 claims abstract description 41
- 238000012545 processing Methods 0.000 claims abstract description 24
- 238000006243 chemical reaction Methods 0.000 claims abstract description 6
- 238000012544 monitoring process Methods 0.000 claims abstract description 4
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- WHXSMMKQMYFTQS-UHFFFAOYSA-N Lithium Chemical compound [Li] WHXSMMKQMYFTQS-UHFFFAOYSA-N 0.000 description 3
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- 229910001416 lithium ion Inorganic materials 0.000 description 2
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- Charge And Discharge Circuits For Batteries Or The Like (AREA)
Abstract
The utility model discloses a kind of electric energy feedback type battery charging and discharging and partial volume equipment, comprising: Buck-Boost reversible transducer, for direct voltage is boosted, step-down processing, provides the constant current constant voltage of battery charging and discharging; Two-way isolation type switch power, for boosting to direct voltage, step-down processing; Two-way DC/AC current transformer, for the conversion between voltage is carried out direct current and exchanged; Control circuit, for monitoring described Buck-Boost reversible transducer, two-way isolation type switch power, two-way DC/AC current transformer.Adopt the utility model, both can realize the constant current charge to battery, can, by battery discharge electric energy feedback to electrical network, realize energy regeneration utilization again, adopt two-way isolation type switch power, improve utilization rate of electrical, reach the effect of economize on electricity, and realize electrical isolation by high-frequency isolation transformer, when charging, adopt high frequency synchronous rectification, raise the efficiency, improve the factor of the harm energy quality such as net side power factor, minimizing harmonic content.
Description
Technical field
The utility model relates to field of power electronics, relates in particular to a kind of electric energy feedback type battery charging and discharging and partial volume equipment.
Background technology
Along with the continuous progress of the fast development of national economy and science and technology, based on storage battery power supply or more and more general with the storage battery power-supply system application of power supply in support.As electric motor car, the DC power system of electric power system, the DC UPS system in the fields such as communication, railway, subway, airport, fire-fighting with exchange uninterrupted system (UPS) and all need to use in a large number various storage batterys.
Battery changes into, and battery is repeatedly charged, is discharged, and is an important step in battery production process, and electric energy feedback type battery charging and discharging and partial volume equipment are the capital equipments that battery changes into.
Due to technology and cost factor, the charge and discharge system of current battery formation device is: charging process adopts conventional linear constant-current source, charging topological structure is fairly simple, adopt uncontrollable rectification meeting to bring the factor of the various reduction qualities of power supply to electrical network simultaneously, cause that net side power factor is low, harmonic content is large, produce a large amount of electric network pollutions source, pollute electrical network; Discharge process adopts resistance or power semiconductor heating power consumption, so that produces amount of heat, causes the waste of energy resources, and a large amount of high power air-conditionings need to be installed and lower the temperature, and consumes a large amount of electric energy, and overall efficiency is low, without electric energy feedback apparatus.
Summary of the invention
Technical problem to be solved in the utility model is, a kind of electric energy feedback type battery charging and discharging simple in structure and partial volume equipment are provided, and both can realize the constant current charge to battery, can, by battery discharge electric energy feedback to electrical network, realize energy regeneration utilization again.
Technical problem to be solved in the utility model is also, a kind of electric energy feedback type battery charging and discharging and partial volume equipment are provided, adopt two-way isolation type switch power, improve utilization rate of electrical, reach the effect of economize on electricity, and utilize high-frequency isolation transformer to realize electrical isolation.
Technical problem to be solved in the utility model is also, a kind of electric energy feedback type battery charging and discharging and partial volume equipment are provided, and adopts high frequency synchronous rectification realization charging, raises the efficiency, and improves the factor of the harm energy quality such as net side power factor, minimizing harmonic content.
In order to solve the problems of the technologies described above, the utility model provides a kind of electric energy feedback type battery charging and discharging and partial volume equipment, comprising: Buck-Boost reversible transducer, for direct voltage is boosted, step-down processing, provides the constant current constant voltage of battery charging and discharging; Two-way isolation type switch power, for boosting to direct voltage, step-down processing; Two-way DC/AC current transformer, for the conversion between voltage is carried out direct current and exchanged; Control circuit, for monitoring described Buck-Boost reversible transducer, two-way isolation type switch power, two-way DC/AC current transformer; Between battery and electrical network, be connected in series successively described Buck-Boost reversible transducer, two-way isolation type switch power, two-way DC/AC current transformer, described Buck-Boost reversible transducer, two-way isolation type switch power, two-way DC/AC current transformer are electrically connected with described control circuit; Grid side alternating voltage is transformed into direct voltage through two-way DC/AC current transformer, direct voltage carries out step-down processing for the first time through two-way isolation type switch power, carry out step-down processing for the second time through Buck-Boost reversible transducer again through the direct voltage after treatment of step-down for the first time, make direct voltage be reduced to the charging voltage of battery, provide to battery through the direct voltage after treatment of step-down for the second time described, battery is carried out to constant current charge processing; The direct voltage of battery output is through the processing of boosting for the first time of Buck-Boost reversible transducer, through the direct voltage after treatment that boosts for the first time again through the processing of boosting for the second time of two-way isolation type switch power, through boosting for the second time, direct voltage after treatment is transformed into alternating voltage by two-way DC/AC current transformer, described alternating voltage is connected to the grid, makes battery discharge electric energy feedback to electrical network.
As the improvement of such scheme, described Buck-Boost reversible transducer comprises Buck-Boost converter major loop and Buck-Boost control circuit, and described Buck-Boost converter major loop comprises Buck circuit and Boost circuit; Described Buck-Boost control circuit is according to Buck-Boost converter major loop described in charging and discharging currents signal and charging/discharging voltage signal controlling, while making to charge, the Buck circuit working of described Buck-Boost converter major loop, when electric discharge, the Boost circuit working of described Buck-Boost converter major loop.
As the improvement of such scheme, described Buck-Boost control circuit comprises the first pulse width modulator and the first adjuster, the input of described the first pulse width modulator is electrically connected with described the first adjuster, and the output of described the first pulse width modulator is electrically connected with described Buck-Boost converter major loop; By sampling, charging and discharging currents signal is sent to described the first pulse width modulator through described the first adjuster, by sampling, charging/discharging voltage signal is sent to described the first pulse width modulator, described the first pulse width modulator is according to described charging and discharging currents signal and charging/discharging voltage signal output pulse width modulation signal, controls the operating state of Buck circuit and Boost circuit in described Buck-Boost converter major loop.
As the improvement of such scheme, described two-way isolation type switch power comprises normal shock-push-pull circuit and two-way isolation type switch power control circuit; Described two-way isolation type switch power control circuit is according to the Voltage Feedback value of described normal shock-push-pull circuit and voltage given value, control described normal shock-push-pull circuit, while making to charge, described normal shock-push-pull circuit is worked in normal shock mode, when electric discharge, described normal shock-push-pull circuit is with push pull mode work.
As the improvement of such scheme, described normal shock-push-pull circuit comprises forward converter and push-pull converter, the input of described forward converter is in parallel with the output of push-pull converter, the output of described forward converter is in parallel with the input of push-pull converter, in described normal shock-push-pull circuit, be provided with high-frequency isolation type transformer, realize electrical isolation; Described two-way isolation type switch power control circuit comprises the second adjuster, the first amplifying circuit, the second amplifying circuit, the second pulse width modulator and the 3rd pulse width modulator, the output of described the second adjuster is electrically connected with the input of the first amplifying circuit and the input of the second amplifying circuit, the output of described the first amplifying circuit is electrically connected with the input of the second pulse width modulator, and the output of described the second amplifying circuit is electrically connected with the input of the 3rd pulse width modulator; Described the second adjuster regulates the pulse-width signal of described the second pulse width modulator and the 3rd pulse width modulator according to the Voltage Feedback value of described normal shock-push-pull circuit and voltage given value, the operating state of described the second pulse width modulator output pulse width modulation signal control forward converter, the operating state of described the 3rd pulse width modulator output pulse width modulation signal control push-pull converter.
As the improvement of such scheme, described two-way isolation type switch power control circuit also comprises the 3rd adjuster, and the output of described the 3rd adjuster is electrically connected with the input of the 3rd pulse width modulator; Described the 3rd adjuster regulates the pulse-width signal of described the 3rd pulse width modulator, the output of Limited Current according to the current feedback value of described normal shock-push-pull circuit and given value of current value.
As the improvement of such scheme, described two-way DC/AC current transformer comprises two-way DC/AC convertor circuit and two-way DC/AC control circuit; Described two-way DC/AC control circuit is by two-way DC/AC convertor circuit described in the control of output pulse width modulation signal.
As the improvement of such scheme, described two-way DC/AC convertor circuit is single-phase bridge circuit.
As the improvement of such scheme, when battery charging, described two-way DC/AC current transformer is operated in high frequency synchronous rectification state; When battery discharge, described two-way DC/AC current transformer is operated in parallel network reverse state.
As the improvement of such scheme, when described two-way DC/AC current transformer is operated in parallel network reverse state, the alternating voltage of the alternating voltage real-time tracking electrical network of described two-way DC/AC current transformer output, makes size, phase place, the frequency of alternating voltage of described two-way DC/AC current transformer output consistent with size, phase place, the frequency of the alternating voltage of electrical network.
Implement the utility model, there is following beneficial effect:
In electric energy feedback type battery charging and discharging and partial volume equipment, the electric energy of electrical network both can be used as charge power supply of battery, realize the constant current charge to battery, can be used as again the discharge load of battery, by Bidirectional variable-flow link by battery discharge electric energy feedback to electrical network, realize energy regeneration utilization, energy-saving effect is obvious, compare traditional battery formation device, its electric energy can reach more than 50%.
Meanwhile, adopt Buck-Boost reversible transducer, realize constant current charge-discharge, voltage stabilization lifting; Adopt two-way isolation type switch power, improve utilization rate of electrical, reach equally the effect of economize on electricity, and utilize the high-frequency isolation transformer in two-way isolation type switch power to realize electrical isolation; When charging, two-way DC/AC current transformer is operated in high-frequency rectification state, can adopt high frequency synchronous rectification, raises the efficiency, and improves the factor of the harm energy quality such as net side power factor, minimizing harmonic content.
In addition, Buck-Boost reversible transducer, two-way isolation type switch power and two-way DC/AC current transformer are equipped with independently control circuit; Buck-Boost reversible transducer adopts digital-to-analogue to mix control circuit, flexibility and reliability; Two-way isolation type switch power adopts pure analog control circuit, simple in structure, fast response time, and stability is high; Two-way DC/AC current transformer adopts digital-to-analogue to mix control circuit equally, and accuracy, stability are high, and fast response time is controlled flexibly.
Brief description of the drawings
Fig. 1 is the structural representation of the utility model electric energy feedback type battery charging and discharging and partial volume equipment;
Fig. 2 is the topology diagram of Buck-Boost converter major loop in the utility model electric energy feedback type battery charging and discharging and partial volume equipment;
Fig. 3 is the structural representation of Buck-Boost control circuit in the utility model electric energy feedback type battery charging and discharging and partial volume equipment;
Fig. 4 is the topology diagram of normal shock-push-pull circuit in the utility model electric energy feedback type battery charging and discharging and partial volume equipment;
Fig. 5 is the structural representation of two-way isolation type switch power control circuit in the utility model electric energy feedback type battery charging and discharging and partial volume equipment;
Fig. 6 is another structural representation of two-way isolation type switch power control circuit in the utility model electric energy feedback type battery charging and discharging and partial volume equipment;
Fig. 7 is the circuit theory diagrams of two-way DC/AC current transformer in the utility model electric energy feedback type battery charging and discharging and partial volume equipment;
Fig. 8 is the structural representation of two-way DC/AC convertor circuit in the utility model electric energy feedback type battery charging and discharging and partial volume equipment;
Fig. 9 is the structural representation of two-way DC/AC control circuit in the utility model electric energy feedback type battery charging and discharging and partial volume equipment.
Embodiment
For making the purpose of this utility model, technical scheme and advantage clearer, below in conjunction with accompanying drawing, the utility model is described in further detail.
As shown in Figure 1, described electric energy feedback type battery charging and discharging and partial volume equipment comprise Buck-Boost reversible transducer 1, two-way isolation type switch power 2, two-way DC/AC current transformer 3 and control circuit 4.
Buck-Boost reversible transducer 1, for direct voltage is boosted, step-down processing, provides the constant current constant voltage of battery charging and discharging.
Two-way isolation type switch power 2, for boosting to direct voltage, step-down processing.
Two-way DC/AC current transformer 3, for the conversion between voltage is carried out direct current and exchanged.
Control circuit 4, for monitoring described Buck-Boost reversible transducer 1, two-way isolation type switch power 2, two-way DC/AC current transformer 3.
Between battery 5 and electrical network 6, be connected in series successively described Buck-Boost reversible transducer 1, two-way isolation type switch power 2, two-way DC/AC current transformer 3, described Buck-Boost reversible transducer 1, two-way isolation type switch power 2, two-way DC/AC current transformer 3 are electrically connected with described control circuit 4.
When charging, electrical network 6 side alternating voltages are transformed into direct voltage through two-way DC/AC current transformer 3, direct voltage carries out step-down processing for the first time through two-way isolation type switch power 2, carry out step-down processing for the second time through Buck-Boost reversible transducer 1 again through the direct voltage after treatment of step-down for the first time, make direct voltage be reduced to the charging voltage of battery 5, provide to battery 5 through the direct voltage after treatment of step-down for the second time described, realize the constant current charge processing to battery 5.
When electric discharge, the direct voltage that battery 5 is exported is through Buck-Boost reversible transducer 1 processing of boosting for the first time, through the direct voltage after treatment that boosts for the first time again through the processing of boosting for the second time of two-way isolation type switch power 2, through boosting for the second time, direct voltage after treatment is transformed into alternating voltage by two-way DC/AC current transformer 3, described alternating voltage is connected to the grid to 6, makes battery 5 properties be fed back to electrical network 6.
Correspondingly, in the charging of battery 5, discharge process, need be by control circuit 4 ruuning situation of the links to described Buck-Boost reversible transducer 1, two-way isolation type switch power 2, two-way DC/AC current transformer 3 monitor and control.
For example, in general, electric energy feedback type battery charging and discharging and partial volume equipment can provide 512 lithium batteries to change into simultaneously, according to the operation controlling unit of electric energy feedback type battery charging and discharging and partial volume equipment, electric energy feedback type battery charging and discharging and partial volume equipment can be divided into four major parts: 512 road Buck-Boost reversible transducers 1, the control circuit 4 of 2, one two-way DC/AC current transformers 3 of 16 two-way isolation type switch powers and system links.When charging, two-way DC/AC current transformer 3 is operated in high-frequency rectification state, the alternating voltage of net side 6 is transformed into direct voltage through two-way DC/AC current transformer 3, because this direct voltage is higher, so need to direct voltage be reduced to another lower direct voltage through two-way isolation type switch power 2 again, the last charging voltage that through Buck-Boost reversible transducer 1, direct voltage is reduced to again to battery 5 is charged for battery 6.When electric discharge, the direct voltage of battery 6 is elevated to a certain direct voltage through Buck-Boost reversible transducer 1, this direct voltage is increased to another higher direct voltage through two-way isolation type switch power 2 again, is finally transformed into alternating voltage by two-way DC/AC current transformer 3 and in electrical network 6.Therefore, adopt electric energy feedback type battery charging and discharging and partial volume equipment, make the electric energy of electrical network 6 both can be used as the charge power supply of battery 5, realize the constant current charge to battery 5, can be used as again the discharge load of battery 5, the property of battery 5 is fed back to electrical network 6, realizes energy regeneration utilization, energy-saving effect is obvious.
As shown in Figures 2 and 3, described Buck-Boost reversible transducer 1 comprises Buck-Boost converter major loop (referring to Fig. 2) and Buck-Boost control circuit (referring to Fig. 3), and described Buck-Boost converter major loop comprises Buck circuit and Boost circuit.
Correspondingly, control circuit 4 Real-time Collection charging and discharging currents signals and charging/discharging voltage signal, guarantee Buck-Boost reversible transducer 1 is realized constant current charge-discharge, voltage stabilization lifting.Described Buck-Boost control circuit is according to Buck-Boost converter major loop described in charging and discharging currents signal and charging/discharging voltage signal controlling, while making to charge, the Buck circuit working of described Buck-Boost converter major loop, when electric discharge, the Boost circuit working of described Buck-Boost converter major loop.
It should be noted that, each lithium battery all needs independent charge/discharge unit to provide it to charge and discharge voltage, and Buck-Boost converter major loop, as charge/discharge unit, can be realized the non-isolation Bidirectional up-down of DC-to-DC and press.
As shown in Figure 2, Buck-Boost converter major loop is mainly made up of devices such as two power tubes and inductance, electric capacity.When battery is during in charged state, power tube Q1 work, power tube Q2 closes, and work in Buck mode in loop; When battery is during in discharge condition, power tube Q1 closes, power tube Q2 work, and work in Boost mode in loop.
As shown in Figure 3, described Buck-Boost control circuit comprises the first pulse width modulator and the first adjuster, the input of described the first pulse width modulator is electrically connected with described the first adjuster, and the output of described the first pulse width modulator is electrically connected with described Buck-Boost converter major loop.
Sampling by control circuit 4 sends to described the first pulse width modulator by charging and discharging currents signal through described the first adjuster, sampled charging/discharging voltage signal is sent to described the first pulse width modulator by control circuit 4, described the first pulse width modulator is according to described charging and discharging currents signal and charging/discharging voltage signal output pulse width modulation signal.Correspondingly, Buck-Boost converter major loop receives the first pulse width modulator output pulse width modulation signal, and according to the open and-shut mode of pulse-width signal power ratio control pipe Q1 and power tube Q2, realize the conversion between Buck circuit and Boost circuit in described Buck-Boost converter major loop, effectively complete the boosting of voltage, step-down processing.
Preferably, described the first pulse width modulator is voltage-type pulse width modulator.
Preferably, described the first adjuster is pi regulator, and pi regulator regulates the pulse-width signal of the first pulse width modulator according to charging and discharging currents signal and charging and discharging currents set-point, and charging and discharging currents signal is equated with charging and discharging currents set-point, realize constant current charge, electric discharge, stability is high.
As shown in Figures 4 and 5, described two-way isolation type switch power 2 comprises normal shock-push-pull circuit (referring to Fig. 4) and two-way isolation type switch power control circuit (referring to Fig. 5).Described two-way isolation type switch power control circuit is according to the Voltage Feedback value of described normal shock-push-pull circuit and voltage given value, control the automatic switchover of forward converter and push-pull converter in described normal shock-push-pull circuit, while making to charge, described normal shock-push-pull circuit is worked in normal shock mode, when electric discharge, described normal shock-push-pull circuit is with push pull mode work.
It should be noted that, when step-down, the pulse-width signal of two-way isolation type switch power control circuit output particular range, make forward converter in running order, and push-pull converter is in driving blocked styate; While boosting, control circuit is exported the pulse-width signal of another particular range, makes push-pull converter in running order, and forward converter is in driving blocked styate.Correspondingly, the part that the pulse-width signal in two particular ranges does not overlap intersection, has realized the switching between forward converter and push-pull converter.
As shown in Figure 4, described normal shock-push-pull circuit comprises forward converter and push-pull converter, and the input of described forward converter is in parallel with the output of push-pull converter, and the output of described forward converter is in parallel with the input of push-pull converter.Wherein, described forward converter comprises power tube Q3, and described push-pull converter comprises power tube Q4 and power tube Q5.
Preferably, in described normal shock-push-pull circuit, be provided with high-frequency isolation type transformer T1, T2, can effectively realize electrical isolation.
It should be noted that, two-way isolation type switch power control circuit is exported respectively the pulse-width signal of particular range to power tube Q3, power tube Q4 and power tube Q5.In the time that power tube Q3 is driven, power tube Q4 and power tube Q5 are blocked, and forward converter is in running order, and push-pull converter is in driving blocked styate, can realize step-down; In the time that power tube Q3 is blocked, power tube Q4 and power tube Q5 are driven, and push-pull converter is in running order, and forward converter is in driving blocked styate, can realize and boosting.
As shown in Figure 5, described two-way isolation type switch power control circuit comprises the second adjuster, the first amplifying circuit, the second amplifying circuit, the second pulse width modulator and the 3rd pulse width modulator, the output of described the second adjuster is electrically connected with the input of the first amplifying circuit and the input of the second amplifying circuit, the output of described the first amplifying circuit is electrically connected with the input of the second pulse width modulator, and the output of described the second amplifying circuit is electrically connected with the input of the 3rd pulse width modulator.Described the second adjuster regulates the pulse-width signal of described the second pulse width modulator and the 3rd pulse width modulator according to the Voltage Feedback value of described normal shock-push-pull circuit and voltage given value, the operating state of described the second pulse width modulator output pulse width modulation signal control forward converter, the operating state of described the 3rd pulse width modulator output pulse width modulation signal control push-pull converter.
It should be noted that, the second adjuster is according to normal shock-push-pull circuit voltage U
lvalue of feedback and set-point U
* lthe deviation forming regulates, the output of the second adjuster is divided into two-way, regulate respectively the second pulse width modulator and the 3rd pulse width modulator, the second pulse width modulator output pulse width modulation signal is to power tube Q3, the 3rd pulse width modulator output pulse width modulation signal is to power tube Q4 and power tube Q5, realized the switching between pulse-width modulation and forward converter and the push-pull converter of forward converter and push-pull converter both direction circuit working process.
More preferably, described the second adjuster is pi regulator, can effectively realize floating and regulate, and makes voltage U
lvalue of feedback and set-point U
* lequate, stability is high.
More preferably, described the second pulse width modulator is current source PWM device, has transient response and stability highly fast.
More preferably, described the 3rd pulse width modulator is voltage-type pulse width modulator.
Below in conjunction with specific embodiment, two-way isolation type switch power 2 is described in further detail.
In the time that normal shock-push-pull circuit is unloaded, forward converter work, the second adjuster output level is 3.5V.
As the U at normal shock-push-pull circuit
lwhen end adds load, U
lmagnitude of voltage declines a little, and the feedback voltage of the second adjuster reduces, because the adjusting of the second adjuster is that a kind of floating regulates, in order to make feedback voltage and given voltage U
* lequate, the second adjuster output will reduce, and make the PWM waveform that the second pulse width modulator output duty cycle is larger carry out driving power pipe Q3, make forward converter toward U
lend is carried more energy.
In the time continuing to add heavy load, the second adjuster is exported also along with decline, and the second pulse width modulator output pwm signal duty ratio also increases thereupon.
Work as full load, the second adjuster output level is 0.9V, and the second pulse width modulator output pwm signal will reach maximum pulse width.
On the contrary, when reducing the U of normal shock-push-pull circuit
lend load time, the second adjuster electrical level rising, the second pulse width modulator output pulse width narrows.
Work as U
lwhen end has feedback power loopback, U
lterminal voltage value has some rising a little, and the feedback voltage of the second adjuster raises, in order to make feedback voltage and given voltage U
* lequate, the second adjuster output level increases, and the second pulse width modulator output pwm signal is blocked, and blocks power tube Q3 completely, and forward converter quits work.
In the time that the second adjuster level is elevated to 4.5V, the 3rd pulse width modulator starts output pulse width modulation signal, and push-pull converter is started working, and normal shock-push-pull circuit starts feedback electric energy, and energy is from U
lend is toward U
hend is fed to, and works as U
lthe energy of end loopback is when more, and the second adjuster output level is along with rising, and the 3rd pulse width modulator output pulse width modulation signal duty ratio, along with increase, makes more feedback energies be transmitted back to U
hend, makes voltage U
lvalue of feedback and set-point U
* lequate.
In the time that the second adjuster output level reaches 7.5V, the 3rd pulse width modulator output maximum pulse width, normal shock-push-pull circuit reaches reverse rated power.
As shown in Figure 6, described two-way isolation type switch power control circuit also comprises the 3rd adjuster, and the output of described the 3rd adjuster is electrically connected with the input of the 3rd pulse width modulator; Described the 3rd adjuster regulates the pulse-width signal of described the 3rd pulse width modulator, the output of Limited Current according to the current feedback value of described normal shock-push-pull circuit and given value of current value.
It should be noted that, for making normal shock-push-pull circuit operation more reliable, increased the restriction of discharge stream, the 3rd adjuster is according to electric current I
2value of feedback and set-point I
* 2the deviation forming regulates, and in the time that electric current reaches cut-off current, carrys out the output of Limited Current by limiting the pulse-width signal of the 3rd pulse width modulator.
More preferably, described the 3rd adjuster is pi regulator, can effectively realize floating and regulate, and stability is high.
Therefore, two-way isolation type switch power 2, by utilizing two-way isolation type switch power control circuit to realize the control to normal shock-push-pull circuit, can reduce voltage ripple, improves voltage utilization, raises the efficiency.Wherein, two-way isolation type switch power control circuit coordinates amplifying circuit and pulse width modulator to form by adjuster, adopt pure analog circuit to realize the automatic pulse adjusting of control circuit and the automatic conversion of forward converter and push-pull converter, accuracy, stability are high, circuit structure is simple, fast response time.
As shown in Fig. 8 and Fig. 9, described two-way DC/AC current transformer 3 comprises two-way DC/AC convertor circuit (referring to Fig. 8) and two-way DC/AC control circuit (referring to Fig. 9); Described two-way DC/AC control circuit is by two-way DC/AC convertor circuit described in the control of output pulse width modulation signal.
It should be noted that, the Main Function of two-way DC/AC current transformer 3 is that the converting direct-current voltage into alternating-current voltage from two-way isolation type switch power 2 is connected with electrical network 6.
As shown in Figure 8, described two-way DC/AC convertor circuit is single-phase bridge inverter circuit.Preferably, described two-way DC/AC convertor circuit adopts the single-phase bridge circuit being made up of IGBT power device.
Preferably, between described two-way DC/AC convertor circuit and electrical network 6, isolate by Industrial Frequency Transformer.
It should be noted that, when battery charges, two-way DC/AC current transformer 3 is operated in high-frequency rectification state, and adopts high frequency synchronous rectification, can effectively raise the efficiency, and improves the factor of the harm energy quality such as net side power factor, minimizing harmonic content.When battery discharge, described two-way DC/AC current transformer is operated in parallel network reverse state.
As shown in Figure 7, when described two-way DC/AC current transformer is operated in parallel network reverse state, the alternating voltage of the alternating voltage real-time tracking electrical network 6 that described two-way DC/AC current transformer 3 is exported, makes size, phase place, the frequency of the alternating voltage that described two-way DC/AC current transformer 3 exports consistent with size, phase place, the frequency of the alternating voltage of electrical network 6.
As shown in Figure 7, U
ifor the output voltage of two-way DC/AC current transformer 3, U
sfor line voltage, R is line resistance, and L is series reactor, I
zfor feedback grid electric current.For ensureing feedback electric current I
zphase place and line voltage U
sphase place is consistent, with U
sfor with reference to phasor, I
zwith U
sphase place is identical, the voltage U at internal resistance R two ends
rwith line voltage U
sphase place is consistent, and inductance both end voltage U
lphase place lag behind U
s90 °.Thus can be in the hope of U
iphase place and amplitude:
U
i=I
z(R+ ω L)+U
s, in formula, ω is electrical network angular frequency.
In side circuit, can U be detected by transducer
sphase place, cycle and amplitude.Because R in real system is difficult to obtain, therefore I
zphase place must be realized by Current Negative Three-Point Capacitance.Current Transformer detects I in real time
z, to guarantee I
zwith U
sphase place is consistent, realizes power factor and be 1 feedback electric energy.
Correspondingly, the key technical indexes that electric energy feedback type battery charging and discharging and partial volume equipment are intended reaching comprises:
(1) input ac power voltage: single-phase AC 220V/50Hz; Be transmitted back to the alternating voltage of electrical network: single-phase AC 220V/50Hz;
(2) battery charging voltage adjustable range: DC 0-4.2V; Battery charging and discharging electric current adjustable range: DC 0-2A;
(3) voltage resolution 5mV, electric current resolution 5mA, temporal resolution 1s, complete machine maximum power dissipation 5000W;
(4) input, output AC electric current are sinusoidal, and percent harmonic distortion is less than 5%, and input and output AC side Power Factor is 0.99.
Correspondingly, compared with electric energy feedback type battery charging and discharging becomes power supply with partial volume equipment with existing lithiumation, its feature is: property is transmitted back to electrical network, further improves electric energy service efficiency; Adopt two-way isolation type switch power, obviously reduce complete machine consumed power; When charging, two-way DC/AC current transformer is operated in high-frequency rectification state, and adopts high frequency synchronous rectification, can effectively raise the efficiency, and improves the factor of the harm energy quality such as net side power factor, minimizing harmonic content.
Analyze aspect energy-conservation with regard to electric energy feedback type battery charging and discharging and partial volume equipment below.
One, while charging, the comparison that two-way isolation type switch power and linear stabilized power supply are energy-conservation
When factory's battery charges at present, generally adopt linear stabilized power supply, reaction speed is fast, and output ripple is less, but its input voltage and output voltage have certain pressure reduction, and has the lower shortcoming of the large efficiency of caloric value.Therefore, adopt linear stabilized power supply when battery is charged, because linear stabilized power supply self approximately has the pressure drop of 3V, the battery charging that therefore will give 4.2V, need provide the voltage of 7.2V.Suppose that charging current is 3A, have,
Battery consumption power: P1=E × I=4.2V × 3A=12.6W;
Power end input power: P2=U × I=7V × 3A=21W;
Charge efficiency: n1=P1 ÷ P2 × 100%=12.6W/21W × 100%=60%;
Relatively, while adopting two-way isolation type switch power, the switching loss of two-way isolation type switch power is about 1W, and on-state loss is about 2W, and the total losses of two-way isolation type switch power are about 3W, and battery consumption power is constant.Now,
The power that input need to provide: P3=P1+3W=15.6W;
Charge efficiency: n2=P1 ÷ P3 × 100%=12.6W/15.6W × 100%=80.7%;
From above relatively: when charging, adopt two-way isolation type switch power than improving approximately 20% by linear stabilized power supply efficiency.
Two, inversion grid connection analysis on energy saving effect
Current most of formation of Li-ion batteries equipment is to adopt resistance that the power consumption of battery the inside is fallen in its discharge process.And electric energy feedback type battery charging and discharging of the present utility model and partial volume equipment are that battery discharge electric energy is sent back to electrical network, power is about 12.6W, lithium battery discharging efficiency is about 80%, emits power and is about 10.4W, and the loss of removing Switching Power Supply 3W also has 7.4W to send electrical network back to.
Three, total analysis on energy saving effect
Two processes of above charging and discharging are calculated altogether:
The power that need to consume with linear stabilized power supply: P2=21.6W;
The power that will consume with two-way isolation type switch power: P4=15.6W-7.4W=8.2W;
Whole process energy conservation efficiency: n3=(P2-P4)/P2*100%=(21.6W-8.2W)/21.6W*100%=62%.
Therefore,, if calculate with required formation of Li-ion batteries equipment approximately 300 covers of medium-sized enterprise, adopt original pattern, within 10 hours, calculate with continuous operation every day, it is 7000 watts that every cover needs consumed power, within 1 year, consumes electric energy approximately 25000 degree, and the total electric weight of 300 cover consumption is 7,500,000 degree.If adopt electric energy feedback type battery charging and discharging of the present utility model and partial volume equipment, be 62% to calculate by energy-saving efficiency, approximately 4,650,000 degree that can economize on electricity for a year, can save approximately 4,000,000 yuan of the electricity charge.Visible, its economic and social benefit is very obvious.
As from the foregoing, in electric energy feedback type battery charging and discharging and partial volume equipment, the electric energy of electrical network both can be used as charge power supply of battery, realize constant current charge to battery, can be used as again the discharge load of battery, by Bidirectional variable-flow link by battery discharge electric energy feedback to electrical network, realize energy regeneration utilization, energy-saving effect is obvious, compares traditional battery formation device, and its electric energy can reach more than 50%.Meanwhile, adopt Buck-Boost reversible transducer, realize constant current charge-discharge, voltage stabilization lifting; Adopt two-way isolation type switch power, improve utilization rate of electrical, reach equally the effect of economize on electricity, and utilize the high-frequency isolation transformer in two-way isolation type switch power to realize electrical isolation; When charging, two-way DC/AC current transformer 3 is operated in high-frequency rectification state, can adopt high frequency synchronous rectification, raises the efficiency, and improves the factor of the harm energy quality such as net side power factor, minimizing harmonic content; When electric discharge, described two-way DC/AC current transformer is operated in parallel network reverse state.In addition, Buck-Boost reversible transducer, two-way isolation type switch power and two-way DC/AC current transformer are equipped with independently control circuit; Buck-Boost reversible transducer adopts digital-to-analogue to mix control circuit, flexibility and reliability; Two-way isolation type switch power adopts pure analog control circuit, simple in structure, fast response time, and stability is high; Two-way DC/AC current transformer adopts digital-to-analogue to mix control circuit equally, and accuracy, stability are high, and fast response time is controlled flexibly.
The above is preferred implementation of the present utility model; it should be pointed out that for those skilled in the art, do not departing under the prerequisite of the utility model principle; can also make some improvements and modifications, these improvements and modifications are also considered as protection range of the present utility model.
Claims (9)
1. electric energy feedback type battery charging and discharging and a partial volume equipment, is characterized in that, described electric energy feedback type battery charging and discharging and partial volume equipment comprise:
Buck-Boost reversible transducer, for direct voltage is boosted, step-down processing, provides the constant current constant voltage of battery charging and discharging;
Two-way isolation type switch power, for boosting to direct voltage, step-down processing;
Two-way DC/AC current transformer, for the conversion between voltage is carried out direct current and exchanged;
Control circuit, for monitoring described Buck-Boost reversible transducer, two-way isolation type switch power, two-way DC/AC current transformer.
2. electric energy feedback type battery charging and discharging as claimed in claim 1 and partial volume equipment, is characterized in that,
Between battery and electrical network, be connected in series successively described Buck-Boost reversible transducer, two-way isolation type switch power, two-way DC/AC current transformer, described Buck-Boost reversible transducer, two-way isolation type switch power, two-way DC/AC current transformer are electrically connected with described control circuit;
Grid side alternating voltage is transformed into direct voltage through two-way DC/AC current transformer, direct voltage carries out step-down processing for the first time through two-way isolation type switch power, carry out step-down processing for the second time through Buck-Boost reversible transducer again through the direct voltage after treatment of step-down for the first time, make direct voltage be reduced to the charging voltage of battery, provide to battery through the direct voltage after treatment of step-down for the second time described, battery is carried out to constant current charge processing;
The direct voltage of battery output is through the processing of boosting for the first time of Buck-Boost reversible transducer, through the direct voltage after treatment that boosts for the first time again through the processing of boosting for the second time of two-way isolation type switch power, through boosting for the second time, direct voltage after treatment is transformed into alternating voltage by two-way DC/AC current transformer, described alternating voltage is connected to the grid, makes battery discharge electric energy feedback to electrical network.
3. electric energy feedback type battery charging and discharging as claimed in claim 2 and partial volume equipment, it is characterized in that, described Buck-Boost reversible transducer comprises Buck-Boost converter major loop and Buck-Boost control circuit, and described Buck-Boost converter major loop comprises Buck circuit and Boost circuit;
Described Buck-Boost control circuit is according to Buck-Boost converter major loop described in charging and discharging currents signal and charging/discharging voltage signal controlling, while making to charge, the Buck circuit working of described Buck-Boost converter major loop, when electric discharge, the Boost circuit working of described Buck-Boost converter major loop.
4. electric energy feedback type battery charging and discharging as claimed in claim 3 and partial volume equipment, it is characterized in that, described Buck-Boost control circuit comprises the first pulse width modulator and the first adjuster, the input of described the first pulse width modulator is electrically connected with described the first adjuster, and the output of described the first pulse width modulator is electrically connected with described Buck-Boost converter major loop;
By sampling, charging and discharging currents signal is sent to described the first pulse width modulator through described the first adjuster, by sampling, charging/discharging voltage signal is sent to described the first pulse width modulator, described the first pulse width modulator is according to described charging and discharging currents signal and charging/discharging voltage signal output pulse width modulation signal, controls the operating state of Buck circuit and Boost circuit in described Buck-Boost converter major loop.
5. electric energy feedback type battery charging and discharging as claimed in claim 2 and partial volume equipment, is characterized in that, described two-way isolation type switch power comprises normal shock-push-pull circuit and two-way isolation type switch power control circuit;
Described two-way isolation type switch power control circuit is according to the Voltage Feedback value of described normal shock-push-pull circuit and voltage given value, control described normal shock-push-pull circuit, while making to charge, described normal shock-push-pull circuit is worked in normal shock mode, when electric discharge, described normal shock-push-pull circuit is with push pull mode work.
6. electric energy feedback type battery charging and discharging as claimed in claim 5 and partial volume equipment, it is characterized in that, described normal shock-push-pull circuit comprises forward converter and push-pull converter, the input of described forward converter is in parallel with the output of push-pull converter, the output of described forward converter is in parallel with the input of push-pull converter, in described normal shock-push-pull circuit, be provided with high-frequency isolation type transformer, realize electrical isolation;
Described two-way isolation type switch power control circuit comprises the second adjuster, the first amplifying circuit, the second amplifying circuit, the second pulse width modulator and the 3rd pulse width modulator, the output of described the second adjuster is electrically connected with the input of the first amplifying circuit and the input of the second amplifying circuit, the output of described the first amplifying circuit is electrically connected with the input of the second pulse width modulator, and the output of described the second amplifying circuit is electrically connected with the input of the 3rd pulse width modulator;
Described the second adjuster regulates the pulse-width signal of described the second pulse width modulator and the 3rd pulse width modulator according to the Voltage Feedback value of described normal shock-push-pull circuit and voltage given value, the operating state of described the second pulse width modulator output pulse width modulation signal control forward converter, the operating state of described the 3rd pulse width modulator output pulse width modulation signal control push-pull converter.
7. electric energy feedback type battery charging and discharging as claimed in claim 6 and partial volume equipment, it is characterized in that, described two-way isolation type switch power control circuit also comprises the 3rd adjuster, and the output of described the 3rd adjuster is electrically connected with the input of the 3rd pulse width modulator;
Described the 3rd adjuster regulates the pulse-width signal of described the 3rd pulse width modulator, the output of Limited Current according to the current feedback value of described normal shock-push-pull circuit and given value of current value.
8. electric energy feedback type battery charging and discharging as claimed in claim 2 and partial volume equipment, is characterized in that, described two-way DC/AC current transformer comprises two-way DC/AC convertor circuit and two-way DC/AC control circuit;
Described two-way DC/AC control circuit is by two-way DC/AC convertor circuit described in the control of output pulse width modulation signal.
9. electric energy feedback type battery charging and discharging as claimed in claim 8 and partial volume equipment, is characterized in that, described two-way DC/AC convertor circuit is single-phase bridge circuit.
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Cited By (4)
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CN104079029A (en) * | 2014-06-20 | 2014-10-01 | 佛山市贝瑞尔电气科技有限公司 | Electric energy feedback type battery charging-discharging and capacity grading device |
CN105867575A (en) * | 2016-05-05 | 2016-08-17 | 浪潮电子信息产业股份有限公司 | Charging and discharging chip architecture applied to server backup battery |
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2014
- 2014-06-20 CN CN201420329880.2U patent/CN203942314U/en not_active Expired - Lifetime
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CN104079029A (en) * | 2014-06-20 | 2014-10-01 | 佛山市贝瑞尔电气科技有限公司 | Electric energy feedback type battery charging-discharging and capacity grading device |
CN104079029B (en) * | 2014-06-20 | 2016-09-28 | 佛山市贝瑞尔电气科技有限公司 | Electric energy feedback type battery charging and discharging and partial volume equipment |
CN105867575A (en) * | 2016-05-05 | 2016-08-17 | 浪潮电子信息产业股份有限公司 | Charging and discharging chip architecture applied to server backup battery |
CN105867575B (en) * | 2016-05-05 | 2018-08-14 | 浪潮电子信息产业股份有限公司 | Charging and discharging chip architecture applied to server backup battery |
CN107370222A (en) * | 2017-09-13 | 2017-11-21 | 合肥亮天新能源科技有限公司 | A kind of energy complement formula grading system |
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