Systema Commercialis Integratum Ventus-Solaris-Conditorium

Specialiter pro sceneriis ut rete adiuvandum, commercium et industriae alimenta, et microreticula construenda, systema venti-solaris-conditoriae integra combinat functiones generationis venti, solaris, et conditorio. Centrum in "flexibili disponentia, alta integratione, et gemino digitali", praebet praestantias ut securitas et fides, simul et alta efficacia et conservatio energiae. Non solum potest compensare intermitterentiam venti et solari, sed etiam stabilis alimentum potest praebere rete et usuariae lateri, satisfaciens necessitatibus administrationis energiae variarum sceneriorum.

Core Advantages: 7 Key Features to Address Energy Management Challenges

1. Flexibilis Dispositio Energiae: Coordinatio Multifontium et Allocatio Ad Petitionem

Systema potest intelligenter coordinare fluxum energiae inter ventum, solem, unitates conditorio, et publicum reticulum ad "dispositionem ad petitionem" obtinendi:

• Cum generatio venti et solari abundat, prioritate dat ad satisfaciendum demandae electricitatis onus et superfluam potentiam in unitate conditorio conseruat.

• Cum generatio venti et solari deficiat vel in tempore consumptus electricitatis culminantis, unitas conditorio celeriter decondit ad supplementum energiae vel automaticum trahit potentiam a rete.

• Supportat "extra rete / in rete" commutationem bimodorum. In sceneriis extra rete, ventus + sol + unitates conditorio collaborant ad alendam. In sceneriis in rete, cooperatur cum rete ad regulationem, adaptans ad diversas necessitates energiae.

2. Design Altissime Integratum: Structura Simplificata, Reductio Costi, et Incrementum Efficacitatis

Adoptat architecturam "PV et ESS integrata", photovoltaica inversionem, managementum conditori, et functiones regulationis energiae in unum instrumentum integrantes. Comparatus ad traditionales systemata divisoria:

• Redigit plus quam 50% componentium externorum, reducens spatium plani equipmenti (unum systema salvat 30% comparativus systemis divisoriis).

• Simplificat processum installationis, eliminans necessitatem separati debugging photovoltaica, conditori, et modulis inversorum, reducens wiring on-site per 60% et breviando cyclus deploymentis.

• Redigit complexitatem maintenance postmodum, faciendo detectionem unipunctualis defectus commodius et redigendo costus operationis et maintenance laboris.

3. Control Geminus Digitalis: Mappatura Realis Temporis et Praedictio Precisa

Aequipatum est systema intelligenti managementis energiae (EMS), quod "speculum virtuale" systematis basimur technologia gemina digitali:

• Mappatura realis temporis datae operativae ut velocitas venti, lux intensitas, capacitas conditori, et potentia onus, visibiliter praesentans totum processum "generatio - conditio - consumptio".

• Basimur historica data et algorithmis, praedicit tendentiam supply et demanda energiae proximi 24 horae et praevide adjustat strategiam charging et decharging conditori (exempli gratia, basimur meteorologicis data, praedicit debilis lux et fortitudo venti crastina die et prioritas datur conditori hodierna die).

• Supportat control nubis remotus, permittens adjustmentem parametri operativi per computatorem vel telefonum mobile, sine necessitate monitoring on-site.

4. Operatio Secura et Fida: Protectio Multistratificata, Resiliens ad Riscos

Construit systema garantiae securitatis integrum ab equipmento ad systema, eliminans riscos operationis:

• Securitas electrica: Inversor habet protectionem overvoltage, overcurrent, et short-circuit ad impedimentum damni equipmenti ex fluctuationibus voltage.

• Securitas conditori: Unitas conditori adoptat design flamproof et explosion-proof, equipata monitoria temperature et humiditatis, et automaticam disconnectionem power in casu abnormalitatis.

• Adaptabilitas environmentalis: Componentes core sunt resistentes ad altas et bassas temperaturas (-30°C ad 60°C), vento, sabulo, et pluvia, apta ad climata complexa ut plateaux, regiones litorales, et deserta.

• Compatibilitas rete: Cum in rete, conformatur standardibus rete voltage et frequency, evitans impactus in rete.

5. Conversionis Energiae Alta Efficacia: Perdita Parva, Transmissio Alta, et Incrementum Revenue

Systema optimizat efficaciam conversionis energiae in omnibus stadiis, redigens perdita energiae:

• Ut module photovoltaica et turbines venti utuntur technologiis generationis altae efficaciae, augmentantes capturam venti et solari.

• Inversor habet altam efficaciam conversionis, et combinatus cum strategiis managementis charging et decharging conditori, redigit perdita energiae in conditore et release.

• Efficacia totalis systematis utilisationis energiae est ≥85%, et adoplando technologiam MPPT magis progressivam, incrementat generationem potentiae per 15% ad 20% comparativus systemis venti-solari traditionalibus sub eadem venti et solari resource.

6. Assurance Longevity Conditori: Durabilis, Consumptio Parva, et Reductio Costi

Unitas conditori utitur cellulis battery long-cycle-life, praebens sequentes advantagia: • Vitae cycle posse attingere ultra 5,000 vices, et sub usu normali, vita excedit 10 annos, redigens costus replacementis medii termini.

• Supportat deep charging et decharging (profunditas decharge ≥ 80%), cum alta utilisatione capacitatis conditori, evitans problemam "false capacity marking".

• Habet functiones self-maintenance, automaticam equalisationem cell voltage, retardans attenuationem capacitatis, et mantinens stabilem capacitatem conditori per longum tempus.

7. Operationis et Maintenance Praemonitio Intelligentis: Detectio Proactiva, Reducens Downtime

Systema EMS habet capability praemonitionis defectus et self-diagnosis, redigens difficultates operationis et maintenance:

• Monitoring realis temporis status componentium, ut turbine venti anormalis, shading photovoltaica, et attenuation cell battery, et praecipiens informationem praemonitionis ante;

• Venit cum guida detectionis defectus, clare statens causam anomalitatis et passus solutionis, permitens non-professionales initio curare;

• Supportat statisticam data operationis et maintenance, automaticam generationem reportorum generationis, conditori, et defectus, facilitans optimisationem strategy operationis et maintenance.

Core Configuration: Coordination Multi-component, Aedificans Systema Stabile Energiae

Systema efficit operationem smooth totius catenae a "generatio - conditio - disposition - output" per efficientem coordinationem componentium core:

• Unitas generationis duobus fontibus: Unitas generationis venti et module photovoltaica solari cooperant, utentes complementarum characteristicarum venti et solari (solaris potentia die et venti potentia nocte vel in ventosi periodi), redigens impactus intermitterentium singulorum fontium energiae;

• Controller turbine venti: Adaptatus ad voltage generationis venti, convertens potentiam venti in stabilis electricitatem, et item habens capability regulationis voltage ad assecurandum qualitatem electricitatis connecta ad systema;

• Equipamentum PV et ESS integratum: Integrans functiones photovoltaica inversionis et managementis charging et decharging conditori, uniformiter regulans electricitatem photovoltaica et conditori, simplificans structuram systematis;

• Systema Intelligentis Managementis Energiae (EMS): Actuens ut "cerebrum systematis", responsibile mappatura gemina digitalis, dispositio energiae, monitoring securitatis, et praemonitio operationis et maintenance, assequens intelligentiam totius processus;

• Design compatibility ampli range: Supportat amplus input range voltage (200V ad 800V), cum rated power coverans 20kW ad 50kW, et capacitas conditori 50kWh ad ultra 100kWh, adaptans ad diversas scalas demandae electricitatis.

Core Applications: 8 Scenarios, Empowering Grids and User Sides

1. Grid peak shaving and valley filling

   Responding to grid load fluctuations, during peak electricity consumption periods (such as afternoons in summer and nights in winter), the energy storage unit releases electricity, reducing the pressure on grid power supply; during off-peak periods (such as early morning), it stores excess solar and wind power or low-cost grid electricity, smoothing the grid load curve and assisting in stable grid operation.

2. Stable power output

   Compensating for the intermittency of wind and solar energy, through the energy storage unit's "peak shaving and valley filling", it ensures stable output voltage and frequency (three-phase AC 400V, 50/60Hz), directly supplying power to precision equipment (such as data centers, laboratory instruments), avoiding equipment failures due to voltage fluctuations.

3. Emergency backup power

   When the public grid suddenly experiences a power outage (such as due to natural disasters or line faults), the system can switch to "off-grid mode" within milliseconds, with the energy storage unit quickly releasing electricity, providing continuous power to critical loads (such as hospital ICUs, communication base stations, emergency command centers), avoiding significant losses caused by power outages.

4. Independent power supply in microgrids

   In remote areas without a grid (such as mountain villages, remote mining areas), the system can build an independent microgrid, generating power through the coordination of "wind + solar + storage", meeting the electricity needs of residents and production within the area, without relying on long-distance grid transmission, reducing grid construction costs.

5. Grid frequency and voltage regulation

   As an auxiliary service device for the power grid, the system can quickly respond to fluctuations in grid frequency and voltage (such as frequency deviations caused by sudden increases or decreases in wind power or photovoltaic power), adjust the charging and discharging power of energy storage, and compensate for changes in grid load in real time, helping the grid maintain frequency stability (50/60Hz ± 0.2Hz) and enhance grid resilience.

6. Energy conservation and cost reduction for industrial and commercial users

   In response to the pain point of "large peak-valley electricity price difference" for industrial and commercial users, the system stores low-cost grid electricity or surplus wind and solar power during off-peak hours (such as late at night) and releases stored energy during peak hours (such as during the day for production), replacing high-cost grid electricity and reducing enterprise electricity expenses. In some scenarios, electricity savings of 20% to 30% can be achieved.

7. Integration of renewable energy

   Deployed near large-scale wind and solar power stations, the system stores excess electricity generated by the stations (preventing "abandonment of wind and solar power") and supplies the electricity to the grid when needed, improving the utilization rate of wind and solar energy and contributing to the achievement of the "dual carbon" goals. At the same time, it creates additional revenue for the power stations.

8. Protection of sensitive loads

   For loads with high requirements for power stability (such as semiconductor production lines and precision testing equipment), the system provides "uninterrupted power support". It continuously monitors the quality of the grid and immediately switches to energy storage power supply without interruption if problems such as voltage sags or harmonics occur in the grid, ensuring that the loads do not shut down and reducing production losses.

Precise application scenarios: covering six core areas

• Industrial and commercial parks

  Supplying power to production workshops, office buildings, and supporting facilities within the park, reducing electricity costs through "peak shaving and valley filling", and serving as an emergency power source to ensure uninterrupted production lines, suitable for industries such as mechanical manufacturing and electronic processing.

• Remote mining areas / villages

  In remote areas without a grid or with unstable grids, an independent microgrid is constructed to meet the electricity needs of mining equipment (such as small crushers) and village residents, replacing diesel generators and reducing pollution and fuel costs.

• Large public buildings

  Supplying power to hospitals, data centers, and transportation hubs (airports, high-speed railway stations), providing stable output to ensure the operation of sensitive loads, and serving as an emergency power source during grid outages to prevent medical accidents, data loss, or transportation disruptions.

• Supporting facilities for renewable energy power stations

  Cooperating with wind and photovoltaic power stations, the system stores excess electricity from the stations, improving the integration rate of renewable energy, and providing stable power for the power stations' auxiliary equipment (such as monitoring and maintenance facilities), reducing the power stations' dependence on the grid.

• Auxiliary services for urban power grids

  Deployed in urban power grid load centers (such as commercial areas and residential areas), participating in peak shaving, valley filling, and frequency and voltage regulation, alleviating the pressure on power grid supply, especially suitable for areas with dense electricity loads and difficult grid expansion.

• Field operation scenarios

  Supplying power to field operation sites such as geological exploration, field scientific research, and border guard posts. The system's lightweight design is suitable for field transportation, and it can achieve "wind + solar + storage" autonomous power supply without complex installation, meeting the electricity needs of equipment operation and personnel living.

 System configuration