CN204179676U - A kind of grid-connected energy-storage system - Google Patents

A kind of grid-connected energy-storage system Download PDF

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Publication number
CN204179676U
CN204179676U CN201420580649.0U CN201420580649U CN204179676U CN 204179676 U CN204179676 U CN 204179676U CN 201420580649 U CN201420580649 U CN 201420580649U CN 204179676 U CN204179676 U CN 204179676U
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China
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energy
module
unit
energy storage
grid
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CN201420580649.0U
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Chinese (zh)
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金银
陶倩华
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SUZHOU GAOCHUANGTE NEW ENERGY SOURCES DEVELOPMENT CO., LTD.
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SUZHOU GAOCHUANGTE NEW ENERGY DEVELOPMENT Co Ltd
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    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02EREDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
    • Y02E10/00Energy generation through renewable energy sources
    • Y02E10/50Photovoltaic [PV] energy
    • Y02E10/56Power conversion systems, e.g. maximum power point trackers
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02EREDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
    • Y02E70/00Other energy conversion or management systems reducing GHG emissions
    • Y02E70/30Systems combining energy storage with energy generation of non-fossil origin

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  • Supply And Distribution Of Alternating Current (AREA)
  • Charge And Discharge Circuits For Batteries Or The Like (AREA)

Abstract

The utility model discloses a kind of grid-connected energy-storage system, comprise: photovoltaic array, Inverter Unit, for the control of transformation of electrical energy and current direction energy storage unit, realize power station and automatically control, regulate, dispatch and control the energy management of the regulating power change of energy storage unit and automatically-monitored unit, be connected between described photovoltaic array, Inverter Unit, energy storage unit and energy management with automatically-monitored unit; Include two-way inverter and energy storage device in described energy storage unit, described energy storage device is ferric phosphate lithium cell.By the way, the grid-connected energy-storage system of the one that the utility model provides, is mainly used in the distributed power station of photovoltaic and large-sized photovoltaic surface power station, for solve photovoltaic plant and network process in instability export problem.

Description

A kind of grid-connected energy-storage system
Technical field
The utility model relates to a kind of energy-storage system, particularly relates to a kind of grid-connected energy-storage system.
Background technology
1, domestic development situation
China's photovoltaic module output since two thousand seven, occupies the first in the world in continuous 5 years.2011, China's photovoltaic module output was 10 times that increase installed capacity then newly, and the photovoltaic module of 90% needs exportation abroad.
The risk of China's photovoltaic industry heavy dependence overseas market was completely exposed in American-European " two anti-" time.For saving China's photovoltaic industry, country puts into effect the development of policy support distributed photovoltaic power generation this year continuously.In order to respond national policy, State Grid Corporation of China issues distributed photovoltaic power generation related management way, for promoting that solid foundation has been established in the fast development of distributed power generation.
China came into effect bidding for concession from 2009, promoted the construction of ground large photovoltaic plant.In the same year, start " the golden sun " engineering and photoelectricity building demonstrative project, give the subsidy of distributed photovoltaic power generation system, and according to the size of scale of investment, determine to subsidize amount.By the end of the year in 2011, the photoelectricity building demonstrative project scale that country has announced will be about 300,000 kilowatts.The scale that " the golden sun " engineering has been announced is about 1,170,000 kilowatts.Standard, the specification of planning associated in project construction, design, construction, management and operation are unsound, cause manifesting in problem set.
The Correlative plan of national publication proposes, and within 2015, distributed photovoltaic power generation will reach 1,000 ten thousand kilowatts.Meanwhile, clearly propose to encourage the distributed photovoltaic power generation system with Integration of building of building in Middle Eastern.
2014, it was all distributed power station that country increases major part in scale newly to photovoltaic plant, substantially carries out with roof-top manner in distributed power station.Build and will become the trend of following photovoltaic plant with power station, large-sized photovoltaic roof, industrial park.
2, development abroad situation
From external development experience, have some experience can supply to use for reference:
Economic lever is taked to ensure photovoltaic generation installed capacity sustained, stable growth.Germany's Renewable Energy Law defines the subsidy way of photovoltaic generation, and for the application model of all kinds of photovoltaic generations such as roof photovoltaic and ground photovoltaic, its scale is different, and subsidy dynamics is different.
The legal provisions of this state's up-to-date amendment in 2012, the rate for incorporation into the power network of photovoltaic generation divides every kilowatt hour to divide every kilowatt hour to 24.43 Europe from 17.94 Europe.This state also specifies, if installed capacity is more than 3,500,000 kilowatts in following 12 months, rate for incorporation into the power network declines 3%; If more than 7,500,000 kilowatts, rate for incorporation into the power network declines 15%.
Formulate rational distributed photovoltaic power generation way to manage, ensure the safe operation of electrical network.Spain requires that the capacity of the distributed power source that a certain region is installed is less than 50% of the peak load in this region, avoids the anti-power transmission of distributed power source as far as possible.Germany requires that the distributed power source of more than 100 kilowatts must install telecommunication and control device, exerts oneself, and can dispatch so that scheduling understands it in real time.
At present, Hispanic dispatching of power netwoks does not still possess remote monitoring and controls the ability of large-scale photovoltaic generating, reason is the photovoltaic generation installation of project telemetering equipment that transmission of electricity operator only requires more than 10,000 kilowatts, and Spain's also so not large-scale photovoltaic project.Along with increasing of MW class project, these projects lack remote-measuring equipment and will make a significant impact operation of power networks.
Utility model content
The technical problem that the utility model mainly solves is to provide a kind of grid-connected energy-storage system, is mainly used in the distributed power station of photovoltaic and large-sized photovoltaic surface power station, for solve photovoltaic plant and network process in instability export problem; Be specifically related to the content of study and practice three aspects of energy storage unit, energy management unit and automatically-monitored unit.
For solving the problems of the technologies described above, the technical scheme that the utility model adopts is: provide a kind of grid-connected energy-storage system, comprising: photovoltaic array, Inverter Unit, for the control of transformation of electrical energy and current direction energy storage unit, realize power station and automatically control, regulate, dispatch and the energy management that changes of the regulating power controlling energy storage unit and automatically-monitored unit.
Be connected between described photovoltaic array, Inverter Unit, energy storage unit and energy management with automatically-monitored unit.
Include two-way inverter and energy storage device in described energy storage unit, described energy storage device is ferric phosphate lithium cell, and described energy storage unit carries out the conversion of electric energy to energy storage device and the control of current direction is realized by two-way exchange device.
Described energy management and automatically-monitored unit control automatically to power station, regulate, dispatch by with the access of public electric wire net, cut out realization, and electric network state to be detected and according to the power output of photovoltaic module to control the regulating power change of energy storage unit.
In a preferred embodiment, described photovoltaic array is in parallel with energy storage unit, and outputs to 10KV bus, and described energy management and automatically-monitored unit carry out energy management to energy storage unit and monitor in real time.
In a preferred embodiment, battery module is included in described energy storage unit, some battery units are included in described battery module, some battery strings are included in described each battery unit, be in parallel between each battery strings with other battery strings, and carry out energy exchange by two-way exchange device and 10KV bus.
In a preferred embodiment, include some ferric phosphate lithium cells in described battery strings and ferric phosphate lithium cell is carried out to the battery management module of electric energy balanced management.
In a preferred embodiment, controller module and on-site data gathering module is included in described energy management and automatically-monitored unit, include controller and Controller Area Network BUS in described controller module, in described on-site data gathering module, include data acquisition unit; Described on-site data gathering module carries out communication by Controller Area Network BUS, controller and data acquisition unit.
In a preferred embodiment, include peripheral circuit, start control module and MPPT maximum power point tracking module in described Inverter Unit, described start control module and MPPT maximum power point tracking module are connected with between peripheral circuit respectively.
In a preferred embodiment, include pre-charge contactor, DC air breaker, active inversion apparatus, voltage detection module in described peripheral circuit and exchange air circuit, being electrically connected between described pre-charge contactor, DC air breaker, active inversion apparatus, voltage detection module, interchange air circuit.
In a preferred embodiment, include in described start control module the DC side insulating monitoring module judging pre-charge contactor and whether close, data comparison module voltage, current data being compared to judgement, with judge that whether electric current and voltage data synchronous, control the data simultaneous module judging whether interchange air circuit closes, described DC side insulating monitoring module, data comparison module are connected in order successively with data simultaneous module.
The beneficial effects of the utility model are: 1) energy storage unit: the energy storage unit that the utility model is mentioned adopts lithium battery as the base unit of power storage, is connected, carries out energy exchange by reversible transducer with 10KV ac bus; 2) energy management and automatically-monitored unit: monitor, control, measure, safeguard and the function such as diagnosis, scheduling; Research automatically realizes with the access of public electric wire net, cuts out, and makes power station, whole roof realize automatic control and adjustment, scheduling; In real time the state of grid side is detected, simultaneously according to the power output of the real-time long pass of photovoltaic system, control the change of the regulating power of energy storage unit, realize the functions such as power smooth, reactive power compensation, peak load shifting.
Accompanying drawing explanation
In order to be illustrated more clearly in the technical scheme in the utility model embodiment, below the accompanying drawing used required in describing embodiment is briefly described, apparently, accompanying drawing in the following describes is only embodiments more of the present utility model, for those of ordinary skill in the art, under the prerequisite not paying creative work, other accompanying drawing can also be obtained according to these accompanying drawings, wherein:
Fig. 1 is the Systematical control schematic diagram of a kind of grid-connected energy-storage system one of the present utility model preferred embodiment;
Fig. 2 is the electric energy energy-storage units structure chart of a kind of grid-connected energy-storage system one of the present utility model preferred embodiment;
Fig. 3 is the energy management of a kind of grid-connected energy-storage system one of the present utility model preferred embodiment and automatically-monitored unit schematic diagram;
Fig. 4 is the DCC start control module principle flow chart of a kind of grid-connected energy-storage system one of the present utility model preferred embodiment;
Fig. 5 is the Inverter Unit schematic diagram of a kind of grid-connected energy-storage system one of the present utility model preferred embodiment.
In accompanying drawing, the mark of each parts is as follows: 1, insulating monitoring module; 2, bypass contactor; 3, pre-charge contactor; 4, external power source; SPD1, direct current surge lightning protection device; SPD2, interchange surge lightning protection device; QF1, DC air breaker; QF2, interchange air circuit; R1, charging resistor; B1, DC filtering; B2, ac filter; VSM1, the first voltage detection module; VSM2, the second voltage detection module; FU, fuse; RH1, temperature sensor; VD, counnter attack diode; ALM, active inversion apparatus; PVGF, active power filtering.
Embodiment
Be clearly and completely described to the technical scheme in the utility model embodiment below, obviously, described embodiment is only a part of embodiment of the present utility model, instead of whole embodiments.Based on the embodiment in the utility model, those of ordinary skill in the art are not making other embodiments all obtained under creative work prerequisite, all belong to the scope of the utility model protection.
Refer to Fig. 1, Fig. 2, Fig. 3, Fig. 4, Fig. 5, the utility model embodiment comprises:
A kind of grid-connected energy-storage system, comprising: photovoltaic array, Inverter Unit, for the control of transformation of electrical energy and current direction energy storage unit, realize power station and automatically control, regulate, dispatch and the energy management that changes of the regulating power controlling energy storage unit and automatically-monitored unit.
Be connected between described photovoltaic array, Inverter Unit, energy storage unit and energy management with automatically-monitored unit.
Include two-way inverter and energy storage device in described energy storage unit, described energy storage device is ferric phosphate lithium cell, and described energy storage unit carries out the conversion of electric energy to energy storage device and the control of current direction is realized by two-way exchange device;
Described energy management and automatically-monitored unit control automatically to power station, regulate, dispatch by with the access of public electric wire net, cut out realization, and electric network state to be detected and according to the power output of photovoltaic module to control the regulating power change of energy storage unit.
Described photovoltaic array is in parallel with energy storage unit, and outputs to 10KV bus, and described energy management and automatically-monitored unit carry out energy management to energy storage unit and monitor in real time.
Battery module is included in described energy storage unit, some battery units are included in described battery module, include some battery strings in described each battery unit, be in parallel between each battery strings with other battery strings, and carry out energy exchange by two-way exchange device and 10KV bus.
Preferably, the quantity of described battery strings is 4.
Include some ferric phosphate lithium cells in described battery strings and ferric phosphate lithium cell is carried out to the battery management module of electric energy balanced management.
Include controller module and on-site data gathering module in described energy management and automatically-monitored unit, in described controller module, include controller and Controller Area Network BUS, in described on-site data gathering module, include data acquisition unit; Described on-site data gathering module carries out communication by Controller Area Network BUS, controller and data acquisition unit.
Include peripheral circuit, start control module and MPPT maximum power point tracking module in described Inverter Unit, described start control module and MPPT maximum power point tracking module are connected with between peripheral circuit respectively.
Include pre-charge contactor, DC air breaker, active inversion apparatus, voltage detection module in described peripheral circuit and exchange air circuit, being electrically connected between described pre-charge contactor, DC air breaker, active inversion apparatus, voltage detection module, interchange air circuit.
Described voltage detection module includes the first voltage detection module and the second voltage detection module.
Include in described start control module the DC side insulating monitoring module judging pre-charge contactor and whether close, data comparison module voltage, current data being compared to judgement, with judge that whether electric current and voltage data synchronous, control the data simultaneous module judging whether interchange air circuit closes, described DC side insulating monitoring module, data comparison module are connected in order successively with data simultaneous module.
In specifically implementing at one, energy storage unit is set to Large Copacity electrical energy storage systems, includes EMS, i.e. EMS in energy management and automatically-monitored unit.
Described power storage is that a unit designs with 500KWH, every 248 pieces of single-unit ferric phosphate lithium cells are connected, 4 strings carry out parallel connection altogether, carry out energy exchange by PCS equipment (reversible transducer) and 10KV bus, and battery pack there is BMS system (battery management system) to carry out electric energy balanced management.
Whole system carries out secondary software Integrated Development based on PVSS, and whole communication is carried out with CAN form.
In EMS, described CAN, namely controller area network (Controller Area Network) belongs to the category of fieldbus, is a kind of serial communication network of effective support dcs.Be by company of German Bosch the eighties in 20th century be specially automobile industry develop a kind of serial communication bus.More and more be subject to people's attention due to the design of its high-performance, high reliability and uniqueness, be widely used in numerous areas.And any mistake of generation can be detected.When signal transmission distance reaches 10km, CAN still can provide the message transmission rate up to 50kbit/s.Because CAN has very high real-time performance and range of application, the express network reaching as high as 1Mbps from bit rate can be arranged in pairs or groups arbitrarily to the multi 50Kbps network of low cost.Therefore, CAN is own through being widely applied in the fields such as car industry, aircraft industry, Industry Control, security protection.
Along with CAN is in the extensive use in industry-by-industry and field, stricter requirement be it is also proposed to its communication format standardization.1991 CAN technical specification (Version2.0) formulate and issue.This technical specification comprises A and B two parts altogether.Wherein 2.0A gives CAN message reference format, and 2.0B give standard with expansion two kinds of forms.The Automotive Engineering Society SAE of the U.S. proposed J1939 agreement in 2000, and after this this agreement becomes the universal standard of lorry and passenger vehicle middle controller local area network (LAN).
Therefore, in the whole system of native system, field data with the communication of CAN form, then by PLC(Programmable Logic Controller) or data acquisition unit carry out Ethernet telecommunication, data are passed to remote data center, is managed by remote data center.
Include inverter in described Inverter Unit, described inverter is preferably high-power combining inverter.
Described high-power inverter designs based on Siemens S120 system, designed, designed peripheral circuit, DCC control program and MPPT maximum power point tracking algorithm.
Include pre-charge contactor, DC air breaker, active inversion apparatus, voltage detection module in described peripheral circuit and exchange air circuit, being electrically connected between described pre-charge contactor, DC air breaker, active inversion apparatus, voltage detection module, interchange air circuit.
Include in described DCC control program the DC side insulating monitoring module judging pre-charge contactor and whether close, data comparison module voltage, current data being compared to judgement, with judge that whether electric current and voltage data synchronous, control the data simultaneous module judging whether interchange air circuit closes, described DC side insulating monitoring module, data comparison module are connected in order successively with data simultaneous module.
In the concrete enforcement of DCC control program, first judge whether key is pressed, when key is pressed, DC side insulating monitoring module is utilized to detect, judge that insulation sides detects whether to pass through, when obstructed out-of-date, report an error, when passing through, close pre-charge contactor KM1, wait for that bus capacitor charges, and closed upper QF1, then the electric current that 2 voltage detection module VSM1 and VSM2 collect is compared, voltage data, thus judge that whether data are synchronous, when data are asynchronous, return to the electric current comparing VSM1 and VSM2 and collect, voltage data, until data syn-chronization, thus closed QF2.
About MPPT maximum power point tracking algorithm, in native system, adopt triangle test.
Specifically, triangle test refers to and to judge maximum power point by constantly adjusting voltage step size △ U and to control, and finally utilizes threshold value △ U to judge whether to reach optimum point.Near photovoltaic cell P-U characteristic curve peak point, specifically from left to right get voltage and the power of A, B, C tri-points successively, then adjust PWM with the power comparative result of three points, thus realize following the tracks of fast.The method has following four features: (1) algorithm inherently can trace into maximum power point quickly and accurately; (2) avoid near maximum power point because of power loss that disturbance causes, but in 3 comparison procedure, owing to more all needing the voltage and the power that first gather three points at every turn, and system is not operated in maximum power point between Harvest time, cause the loss of power, therefore, after have found maximum power point, interval long time should carry out again at 3 and compare; (3) complexity of algorithm determines needs to process mass data, proposes high requirement to the performance of hardware system; (4) when light intensity is undergone mutation, can not blindly mobile working point, need follow the trail of again after sunshine amount is stable.
Because triangle test adopts software control, in algorithm, " Pa >=Pb and Pb≤Pc " this situation (namely cloud block is had in sky in vain) is included into the situation that system has reached maximum power point, both make same process: do not follow the quick change of sunshine amount and blindly adjust operating voltage, the vibration that the system that avoids is too fast.
This kind of process can cause sub-fraction power loss, but be worth relative to bringing whole system steady running: suppose that original system is on maximum working voltage Umax1, the phase induced current detected is Imax1, the maximum working voltage that sunshine should reach after sudden change is Umax2, phase induced current is Imax2, then the system power loss that mobile working point does not cause is P=Pmax2-Pmax1=Umax2Imax2-Umax1Imax1, because the sun returns to original sunshine amount very soon, the Umax1 do not changed becomes maximum working voltage again, the original stable state of System recover.
In in the concrete enforcement that photovoltaic plant is built, increase the grid-connected energy-storage system that the utility model is mentioned, have the following advantages:
1, delayed electric grid investment construction, reduced electric energy line loss, there is good energy-saving and emission-reduction benefit;
2, to electrical network, there is certain Peak Load Adjustment;
3, without the need to other occupation of land, land resource has been saved;
4, photovoltaic generation unsteadiness is solved;
5, the quality of power supply of photovoltaic electric station grid connection is improved;
6, improve system band load capacity, alleviate the pressure of bulk power grid.
The foregoing is only embodiment of the present utility model; not thereby the scope of the claims of the present utility model is limited; every utilize the utility model description to do equivalent structure or equivalent flow process conversion; or be directly or indirectly used in other relevant technical field, be all in like manner included in scope of patent protection of the present utility model.

Claims (8)

1. a grid-connected energy-storage system, it is characterized in that, comprise: photovoltaic array, Inverter Unit, for the control of transformation of electrical energy and current direction energy storage unit, realize power station and automatically control, regulate, dispatch and control the energy management of the regulating power change of energy storage unit and automatically-monitored unit, be connected between described photovoltaic array, Inverter Unit, energy storage unit and energy management with automatically-monitored unit;
Include two-way inverter and energy storage device in described energy storage unit, described energy storage device is ferric phosphate lithium cell, and described energy storage unit carries out the conversion of electric energy to energy storage device and the control of current direction is realized by two-way exchange device;
Described energy management and automatically-monitored unit control automatically to power station, regulate, dispatch by with the access of public electric wire net, cut out realization, electric network state to be detected and according to the power output of photovoltaic module to control the regulating power change of energy storage unit.
2. grid-connected energy-storage system according to claim 1, is characterized in that, described photovoltaic array is in parallel with energy storage unit, and outputs to 10KV bus, and described energy management and automatically-monitored unit carry out energy management to energy storage unit and monitor in real time.
3. grid-connected energy-storage system according to claim 2, it is characterized in that, battery module is included in described energy storage unit, some battery units are included in described battery module, some battery strings are included in described each battery unit, be in parallel between each battery strings with other battery strings, and carry out energy exchange by two-way exchange device and 10KV bus.
4. grid-connected energy-storage system according to claim 3, is characterized in that, includes some ferric phosphate lithium cells and ferric phosphate lithium cell is carried out to the battery management module of electric energy balanced management in described battery strings.
5. grid-connected energy-storage system according to claim 1, it is characterized in that, controller module and on-site data gathering module is included in described energy management and automatically-monitored unit, include controller and Controller Area Network BUS in described controller module, in described on-site data gathering module, include data acquisition unit; Described on-site data gathering module carries out communication by Controller Area Network BUS, controller and data acquisition unit.
6. grid-connected energy-storage system according to claim 2, it is characterized in that, include peripheral circuit, start control module and MPPT maximum power point tracking module in described Inverter Unit, described start control module and MPPT maximum power point tracking module are connected with between peripheral circuit respectively.
7. grid-connected energy-storage system according to claim 6, it is characterized in that, include pre-charge contactor, DC air breaker, active inversion apparatus, voltage detection module in described peripheral circuit and exchange air circuit, being electrically connected between described pre-charge contactor, DC air breaker, active inversion apparatus, voltage detection module, interchange air circuit.
8. grid-connected energy-storage system according to claim 7, it is characterized in that, include in described start control module the DC side insulating monitoring module judging pre-charge contactor and whether close, data comparison module voltage, current data being compared to judgement, with judge that whether electric current and voltage data synchronous, control the data simultaneous module judging whether interchange air circuit closes, described DC side insulating monitoring module, data comparison module are connected in order successively with data simultaneous module.
CN201420580649.0U 2014-10-10 2014-10-10 A kind of grid-connected energy-storage system Expired - Fee Related CN204179676U (en)

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Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN110098734A (en) * 2019-05-15 2019-08-06 广东省华虎新能源科技有限公司 A kind of voltage method for transformation for ferric phosphate lithium cell group
CN111293725A (en) * 2020-03-24 2020-06-16 安徽海螺新能源有限公司 Control method of photovoltaic energy storage system combining light storage with stable output

Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN110098734A (en) * 2019-05-15 2019-08-06 广东省华虎新能源科技有限公司 A kind of voltage method for transformation for ferric phosphate lithium cell group
CN110098734B (en) * 2019-05-15 2021-01-29 广东省华虎新能源科技有限公司 Voltage conversion method for lithium iron phosphate battery pack
CN111293725A (en) * 2020-03-24 2020-06-16 安徽海螺新能源有限公司 Control method of photovoltaic energy storage system combining light storage with stable output
CN111293725B (en) * 2020-03-24 2023-07-21 安徽海螺新能源有限公司 Control method of photovoltaic energy storage system combining light storage with stable output

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CF01 Termination of patent right due to non-payment of annual fee

Granted publication date: 20150225

Termination date: 20171010