Types of 20kWh Lithium-Ion Batteries
A 20kWh lithium-ion battery is a high-capacity energy storage solution widely used in residential, commercial, and off-grid applications. These batteries are engineered to store renewable energy—especially solar power—for later use, reducing reliance on the grid and lowering electricity costs. The classification of these batteries is primarily based on their internal chemistry, manufacturer-specific technology, and application design. Below is a detailed comparison of five leading 20kWh lithium-ion battery systems available today, each offering unique advantages in efficiency, safety, integration, and scalability.
Tesla Powerwall 2
A premium home energy storage solution designed for seamless integration with solar systems and grid backup.
Advantages
- Seamless integration with solar panels and Tesla solar ecosystem
- Provides reliable backup power during outages
- High round-trip efficiency (~90%)
- User-friendly app for real-time energy monitoring
- Scalable with multiple units for higher capacity
Limitations
- Higher upfront cost compared to competitors
- Installation typically requires certified Tesla partners
- Limited availability in some international markets
Best for: Homeowners with solar systems seeking smart energy management and reliable backup power
LG Chem RESU 20H
A compact, high-efficiency energy storage system ideal for maximizing self-consumption of solar energy.
Advantages
- Space-saving, wall-mounted design
- High energy efficiency (up to 95%)
- Proven reliability in diverse climates
- Compatible with multiple inverters and third-party solar systems
- Excellent thermal management system
Limitations
- Discontinued in some regions, replaced by newer models
- Battery degradation may accelerate in extreme temperatures
- Software updates less frequent than Tesla’s ecosystem
Best for: Medium to large homes and small businesses needing efficient, space-conscious energy storage
Samsung 20kWh Lithium-Ion Batteries
High-density storage solutions built for performance and long-term reliability in large-scale installations.
Advantages
- High energy density for compact footprint
- Durable construction with long cycle life
- Advanced battery management system (BMS)
- Suitable for both residential and commercial applications
- Strong global supply chain and support network
Limitations
- Less consumer-focused branding and interface
- Fewer direct-to-consumer sales channels
- May require additional hardware for full system integration
Best for: Large energy systems, commercial installations, and integrators prioritizing performance and scalability
BYD 20kWh Lithium-Ion Batteries
Engineered with Lithium Iron Phosphate (LFP) chemistry for superior safety and extended lifespan.
Advantages
- Uses inherently safer LFP chemistry (less risk of thermal runaway)
- Exceptionally long lifespan (6,000+ cycles)
- Wide operating temperature range
- Modular design allows easy expansion
- Ideal for off-grid and hybrid systems
Limitations
- Slightly lower energy density than NMC-based batteries
- Heavier than some alternatives due to LFP chemistry
- Less brand recognition in consumer markets
Best for: Safety-conscious users, off-grid systems, and applications requiring maximum durability
GoodWe 20kWh Lithium-Ion Batteries
Designed for large-scale solar energy storage with a focus on longevity and intelligent energy management.
Advantages
- Optimized for integration with GoodWe hybrid inverters
- Advanced energy management and remote monitoring
- High cycle life and deep discharge capability
- Cost-effective solution for solar-plus-storage setups
- Strong performance in commercial and industrial applications
Limitations
- Best performance when paired with GoodWe inverters
- Customer support varies by region
- Interface less intuitive than Tesla or LG Chem
Best for: Homeowners and businesses using GoodWe inverters or seeking affordable, scalable storage
| Brand | Chemistry | Lifespan (Cycles) | Efficiency | Best Use Case |
|---|---|---|---|---|
| Tesla Powerwall 2 | NMC (Nickel Manganese Cobalt) | 5,000–7,000 | ~90% | Solar homes, backup power, smart energy |
| LG Chem RESU 20H | NMC | 6,000 | Up to 95% | Residential energy independence |
| Samsung 20kWh | NMC | 5,000+ | ~92% | Commercial & large-scale storage |
| BYD 20kWh | LFP (Lithium Iron Phosphate) | 6,000+ | ~90% | Off-grid, safety-critical, long-life needs |
| GoodWe 20kWh | LFP or NMC (model-dependent) | 6,000 | ~90–93% | Solar integration, cost-effective storage |
Expert Tip: When selecting a 20kWh lithium-ion battery, consider not only capacity but also chemistry (LFP vs. NMC), round-trip efficiency, warranty terms, and compatibility with your existing solar inverter. LFP batteries like BYD offer longer lifespans and enhanced safety, while NMC types like Tesla and LG Chem provide higher energy density and compact designs.
Commercial Uses of 20kWh Lithium-Ion Battery Systems
The 20kWh lithium-ion battery has become a cornerstone of modern commercial energy solutions due to its high energy density, long cycle life, and scalability. As businesses strive for energy independence, cost efficiency, and sustainability, this battery capacity offers a versatile and reliable option across multiple industries. From backup power to renewable integration, the applications are both diverse and impactful.
Key Commercial Applications
Energy Storage
20kWh lithium-ion batteries serve as a robust energy storage solution for commercial facilities, enabling the capture and storage of surplus electricity generated from renewable sources such as solar panels or wind turbines. This stored energy can be deployed during periods of high demand, reducing reliance on the grid and lowering peak-time electricity costs.
Businesses can achieve greater energy self-sufficiency, reduce their carbon footprint, and take advantage of time-of-use pricing by storing energy during off-peak hours when rates are lower. These systems are particularly beneficial for retail centers, warehouses, and manufacturing units with fluctuating power demands.
Emergency Backup Power
In mission-critical environments like hospitals, data centers, and emergency response facilities, uninterrupted power is non-negotiable. A 20kWh lithium-ion battery provides reliable emergency backup power, ensuring essential systems remain operational during grid failures or natural disasters.
Compared to traditional lead-acid batteries, lithium-ion systems offer faster response times, longer lifespan, and require less maintenance. Their compact design also makes them ideal for installations where space is limited but reliability is paramount.
Electric Vehicle (EV) Charging Stations
Commercial EV charging stations increasingly rely on 20kWh lithium-ion batteries to support fast and efficient charging without overloading the local power grid. These batteries store energy during low-demand periods and release it during peak charging times, reducing strain on infrastructure and avoiding costly demand charges.
By integrating battery storage, charging stations can offer multiple simultaneous charging ports, improve service availability, and even participate in demand-response programs. This setup is ideal for fleet depots, shopping malls, and public parking facilities aiming to support sustainable transportation.
Uninterruptible Power Supply (UPS) Systems
Modern UPS systems in commercial offices, financial institutions, and IT environments use 20kWh lithium-ion batteries to safeguard sensitive equipment and data. These batteries provide seamless power transition during outages, preventing data loss, hardware damage, and operational downtime.
Lithium-ion technology offers significant advantages over older battery types, including higher efficiency, reduced footprint, and longer service life—often exceeding 10 years with proper management. This translates to lower total cost of ownership and improved system reliability.
Telecommunication Towers
Remote and off-grid telecommunication towers depend on 20kWh lithium-ion batteries as a stable and durable power source. These batteries ensure continuous operation of critical communication networks, even in areas with unreliable or no grid access.
Solar-powered towers paired with lithium-ion storage can operate autonomously for extended periods. The batteries' ability to withstand deep discharges and extreme temperatures makes them ideal for harsh environments, minimizing maintenance needs and maximizing uptime for mobile and internet services.
Modular Energy Storage Systems
Commercial buildings seeking scalable and future-proof energy solutions often deploy modular energy storage using multiple 20kWh units. This approach allows businesses to start with a base capacity and expand incrementally as energy demands grow or new sustainability goals are set.
Modular systems offer flexibility in installation, maintenance, and energy management. They integrate seamlessly with building energy management systems (BEMS), enabling real-time monitoring, load balancing, and optimization of energy usage across campuses, hotels, or mixed-use developments.
| Application | Key Benefit | Industries Served |
|---|---|---|
| Energy Storage | Reduces peak demand charges and supports renewable integration | Solar farms, warehouses, retail, manufacturing |
| Emergency Backup | Ensures continuity of critical operations during outages | Hospitals, data centers, emergency services |
| EV Charging Stations | Enables fast, grid-friendly charging with energy time-shifting | Fleet operations, public infrastructure, commercial real estate |
| UPS Systems | Protects data and equipment with instant power failover | Banks, offices, IT centers, telecom |
| Telecom Towers | Provides reliable off-grid power for network stability | Mobile network operators, rural connectivity |
| Modular Storage | Scalable, flexible, and future-ready energy management | Commercial buildings, campuses, mixed-use facilities |
Advantages of 20kWh Lithium-Ion Batteries in Commercial Use
Important: When deploying 20kWh lithium-ion battery systems, ensure compliance with local electrical codes, safety standards (e.g., UL, IEC), and proper thermal management. Use certified installers and integrate battery management systems (BMS) to prevent overcharging, overheating, or deep discharge. Proper installation and monitoring maximize safety, performance, and return on investment.
Shipping and Package Information for 20kWh Lithium-Ion Batteries
Shipping a 20kWh lithium-ion battery requires careful planning due to its size, weight, chemical composition, and regulatory compliance. These batteries are widely used in residential energy storage, commercial backup systems, and electric mobility applications, making safe and efficient transportation essential. While standard dimensions exist, exact specifications vary by manufacturer and model. Most 20kWh units are housed in rugged, compact enclosures designed to protect internal components during transit and facilitate easy installation.
The packaging and shipping process prioritizes safety, structural integrity, and compliance with international hazardous materials regulations. Below is a detailed breakdown of common packaging configurations and critical shipping considerations.
Battery Modules
A 20kWh lithium-ion battery pack typically consists of multiple interconnected modules, each containing individual lithium cells arranged in series or parallel configurations. During shipping, these modules are secured within custom-cut foam or high-impact plastic trays inside durable outer packaging.
- Modular design allows for easier handling and replacement of individual units
- Shock-absorbing materials minimize damage from vibration and impact during transit
- Internal insulation prevents short circuits and thermal runaway risks
- Some models include protective covers over terminals to prevent accidental contact
Best practice: Always inspect module alignment and insulation before unpacking
In-Rack Design
Many 20kWh systems utilize an integrated rack-style housing that supports both mechanical stability and ease of installation. These enclosures often resemble server racks or industrial cabinets and are engineered for direct integration into energy storage systems.
- Rack-mounted units frequently include built-in wheels, handles, or forklift slots for mobility
- Reinforced frames enhance durability during loading and unloading
- Integrated cooling channels or vents may require protective caps during transit
- Typically heavier (150–220 kg) due to added structural components and electronics
Note: Verify floor load capacity at delivery site for heavy rack systems
Managed Packaging
Manufacturers employ managed packaging solutions using custom-sized boxes, wooden crates, or composite containers tailored to the exact dimensions of the battery unit. This precision packaging ensures minimal movement and maximum protection.
- Outer packaging is labeled with UN3480 (Lithium-ion batteries) and Class 9 hazardous material markings
- Water-resistant coatings or liners guard against moisture exposure
- Anti-static liners reduce electrostatic discharge risks
- Fragile, orientation-sensitive, and "This Side Up" labels are standard
Compliance tip: Ensure all labels meet IATA, IMDG, and ADR regulations for air, sea, and road transport
Palletisation
For bulk shipments—especially commercial or fleet deliveries—20kWh batteries are often secured on standard or custom pallets. This method streamlines logistics, warehouse handling, and inventory management.
- Pallets are wrapped with stretch film or shrink-wrapped for stability
- Corners and edges may be reinforced with cardboard or plastic guards
- Load distribution is optimized to prevent tipping or crushing
- Multiple units per pallet require spacing to avoid heat buildup
Efficiency note: Palletised loads integrate seamlessly with forklifts and automated handling systems
Temperature & Humidity Control
Lithium-ion batteries are sensitive to environmental conditions. Exposure to extreme heat, cold, or humidity can degrade performance, reduce lifespan, or pose safety risks.
- Recommended shipping temperature range: 0°C to 40°C (32°F to 104°F)
- Insulated packaging or climate-controlled containers are used in extreme climates
- Desiccant packs absorb moisture inside sealed enclosures
- Some advanced packages include temperature loggers for real-time monitoring
Critical warning: Never ship frozen or overheated batteries—risk of thermal runaway increases significantly
Space & Weight Considerations
Despite their energy density, 20kWh lithium-ion batteries are relatively heavy but space-efficient, making them suitable for various transport modes including trucks, cargo ships, and freight aircraft.
- Average weight: 140–180 kg (300–400 lbs), depending on chemistry and casing
- Typical dimensions: ~600–800 mm (W) × 600–700 mm (D) × 1500–1800 mm (H)
- Stackable designs maximize container and truck space utilization
- Proper load securing prevents shifting during transit
Logistics insight: Standardized footprints allow compatibility with common racking and storage systems
Expert Recommendation: When shipping 20kWh lithium-ion batteries, always use certified hazardous materials carriers and ensure full compliance with UN Manual of Tests and Criteria. Pre-shipment inspections, proper documentation (including MSDS/SDS), and employee training in lithium battery handling are crucial for safety and regulatory adherence. For international shipments, confirm country-specific import restrictions and labeling requirements.
| Packaging Type | Best For | Weight Range | Key Safety Features |
|---|---|---|---|
| Module Packaging | Replacement parts, modular systems | 20–50 kg per module | Foam inserts, terminal protection, ESD-safe materials |
| In-Rack Enclosure | Residential/commercial ESS installations | 150–220 kg | Reinforced frame, handles/wheels, orientation labels |
| Managed Crating | Long-distance, international shipping | 160–190 kg | Custom fit, moisture barrier, hazard labels |
| Palletised Load | Bulk orders, fleet deployments | 300–1000+ kg | Stretch-wrapped, corner protectors, non-slip base |
Additional Shipping Best Practices
- State of Charge (SoC): Batteries are typically shipped at 30–50% charge to minimize risk while preserving cell health
- DG Documentation: Air and sea shipments require a completed Dangerous Goods Declaration and UN38.3 test summary
- Terminal Protection: All electrical terminals should be insulated or capped to prevent short circuits
- Stacking Limits: Observe manufacturer guidelines to avoid crushing lower units in multi-tier storage
- Reverse Logistics: Use original packaging or equivalent protection when returning defective units
Factors to Consider When Choosing a 20kWh Lithium-Ion Battery
Selecting a 20kWh lithium-ion battery involves evaluating a wide range of technical, financial, environmental, and human factors. As energy storage becomes increasingly vital for homes, businesses, and renewable energy systems, understanding what makes a battery suitable for your needs is essential. This comprehensive guide breaks down the critical considerations—from performance metrics to market dynamics—so you can make an informed and sustainable investment in energy storage technology.
Important Note: A 20kWh lithium-ion battery is typically used for residential energy storage, backup power, or integration with solar PV systems. Always ensure compatibility with your inverter, charge controller, and local electrical codes before purchase and installation.
Technical Factors
The technical performance of a 20kWh lithium-ion battery directly impacts its efficiency, longevity, and suitability for your energy needs. Key technical aspects include:
- Energy Density: Lithium-ion batteries offer high energy density, meaning they store more energy per unit of volume or weight. A higher energy density allows for a compact design, making these batteries ideal for installations with limited space, such as urban homes or commercial rooftops.
- Cycle Life: This refers to the number of complete charge and discharge cycles a battery can undergo before its capacity drops below 80% of its original rating. High-quality 20kWh lithium-ion batteries typically offer 4,000–7,000 cycles, significantly enhancing long-term cost-effectiveness and reducing the need for early replacements.
- Charge/Discharge Rate (C-Rate): Lithium-ion batteries support fast charging and discharging without degradation. A high C-rate (e.g., 1C or higher) enables rapid energy delivery, which is crucial for applications like peak shaving, emergency backup, or supporting high-power appliances.
- Depth of Discharge (DoD): Most lithium-ion batteries allow up to 90–100% DoD, meaning nearly all stored energy can be used without damaging the battery. This contrasts sharply with lead-acid batteries, which are typically limited to 50% DoD.
- Efficiency: Modern lithium-ion batteries achieve round-trip efficiency of 90–95%, meaning minimal energy is lost during charging and discharging, maximizing the return on your solar or grid input.
- Thermal Management: Built-in cooling or heating systems help maintain optimal operating temperatures, preventing overheating and extending battery lifespan, especially in extreme climates.
Expert Tip: Look for batteries with Battery Management Systems (BMS) that monitor voltage, temperature, and cell balance in real time. A robust BMS enhances safety, performance, and longevity.
Cost-Related Factors
While lithium-ion batteries have a higher upfront cost than traditional options, their long-term value often justifies the investment. Consider the following cost elements:
- Initial Purchase Price: Prices for 20kWh systems typically range from $8,000 to $15,000, depending on brand, chemistry (e.g., NMC vs. LFP), and included components like inverters or monitoring systems.
- Installation Costs: Professional installation is recommended and can add $1,000–$3,000 depending on complexity, electrical upgrades, and permitting requirements. Systems requiring integration with solar panels or smart home energy managers may incur higher labor costs.
- Maintenance Costs: Lithium-ion batteries require minimal maintenance—no watering, cleaning terminals, or equalization charges—reducing long-term ownership costs compared to lead-acid alternatives.
- Replacement and Lifespan: With a typical lifespan of 10–15 years and warranties covering 10 years or 10,000 cycles, a durable 20kWh battery reduces the frequency and cost of replacements.
- Return on Investment (ROI): When paired with solar, these batteries can reduce electricity bills by storing excess daytime generation for nighttime use, potentially paying for themselves over time through energy savings and incentives.
| Cost Factor | Average Range | Factors Influencing Cost | Money-Saving Tips |
|---|---|---|---|
| Purchase Price | $8,000 – $15,000 | Brand, chemistry, warranty, included hardware | Compare quotes; consider LFP for longer life |
| Installation | $1,000 – $3,000 | System complexity, location, electrical upgrades | Bundle with solar installation for discounts |
| Maintenance | $0 – $200/year | Monitoring, occasional inspections | Choose systems with remote diagnostics |
| Replacement | Every 10–15 years | Usage patterns, climate, battery type | Optimize charging habits to extend life |
Non-Technical Factors
Beyond performance and price, several non-technical considerations influence purchasing decisions:
- Brand Reputation: Established brands like Tesla, LG Energy Solution, BYD, and Enphase are trusted for reliability, customer support, and proven track records. Consumers often favor these brands despite higher prices due to confidence in product quality and service.
- Regulatory Compliance: Ensure the battery meets local safety standards (e.g., UL 9540 in the U.S., IEC 62619 internationally) and building codes. Non-compliant systems may not qualify for permits or insurance coverage.
- Environmental Policies: Many buyers prioritize manufacturers with sustainable practices—such as recycling programs, reduced carbon footprint in production, and ethical sourcing of raw materials like lithium and cobalt.
- Warranty and Support: Look for comprehensive warranties (e.g., 10 years, 70% capacity retention) and responsive customer service. Some brands offer mobile apps for monitoring and troubleshooting.
Market-Related Factors
The broader market landscape can significantly affect availability, pricing, and technology trends:
- Demand Spikes: Increased adoption of solar energy and electric vehicles has led to surges in lithium-ion battery demand. This can cause supply chain delays, especially during peak installation seasons or global disruptions.
- Competition: A growing number of manufacturers entering the market has driven innovation and price reductions. However, consolidation or supply shortages can temporarily reduce competition and increase prices.
- Market Trends: The global shift toward renewable energy, carbon neutrality, and energy independence is accelerating demand for home battery storage. Government incentives (e.g., tax credits, rebates) further boost adoption, making now an opportune time to invest.
- Raw Material Availability: Fluctuations in lithium, nickel, and cobalt prices can impact battery costs. Long-term trends suggest increased recycling and alternative chemistries (e.g., sodium-ion) may stabilize prices.
Insight: Monitor market trends and incentive programs in your region. Purchasing during promotional periods or when new models are released can yield significant savings.
Human-Related Factors
People play a crucial role in the successful deployment and operation of battery systems:
- Technician Expertise: Proper installation and configuration require trained professionals familiar with lithium-ion systems. Inexperienced technicians may cause safety hazards, void warranties, or reduce system efficiency.
- User Efficiency: How well the system is managed—through energy monitoring apps, load scheduling, and usage habits—impacts overall energy savings. Educated users can optimize battery use to maximize ROI.
- Disposal and Recycling Practices: Lithium-ion batteries contain valuable and hazardous materials. Choosing manufacturers with take-back programs or partnering with certified recyclers ensures environmentally responsible end-of-life management.
- Safety Awareness: Homeowners should understand basic safety protocols, such as avoiding physical damage, monitoring for overheating, and knowing emergency shutdown procedures.
Safety Reminder: Never attempt to disassemble or repair a lithium-ion battery yourself. Thermal runaway, though rare, can lead to fire. Always rely on certified professionals for maintenance and disposal.
Final Recommendations
- Evaluate your energy usage patterns to determine if a 20kWh battery is appropriately sized for your needs.
- Compare multiple brands and request detailed specifications, including cycle life, warranty terms, and efficiency ratings.
- Choose systems with smart monitoring features for real-time insights and remote management.
- Verify installer credentials and ensure they are certified by the battery manufacturer.
- Plan for end-of-life recycling from the outset to support a circular economy.
Investing in a 20kWh lithium-ion battery is a strategic decision that combines energy independence, cost savings, and environmental responsibility. By carefully weighing technical capabilities, financial implications, market conditions, and human factors, you can select a system that delivers reliable performance for years to come. As battery technology continues to evolve, staying informed will help you make the most of future advancements and opportunities.
Frequently Asked Questions About 20 kWh Lithium-Ion Batteries
A1: A Battery Management System (BMS) is critical for the safe, efficient, and long-term operation of a 20 kWh lithium-ion battery. It acts as the brain of the battery pack, continuously monitoring and managing key parameters such as:
- Cell Voltage Monitoring: Ensures no individual cell is overcharged (which can lead to thermal runaway, fires, or explosions) or undercharged (which reduces capacity and lifespan).
- Temperature Regulation: Tracks heat levels across the battery; excessive heat can degrade performance or cause safety hazards. The BMS may trigger cooling systems or reduce charging rates when needed.
- State of Charge (SoC) Estimation: Provides accurate readings of how much energy remains, similar to a fuel gauge, helping users plan usage and charging.
- Cell Balancing: Equalizes charge levels across all cells to prevent imbalances that lead to premature aging of certain cells, thereby extending overall battery life.
- Health Monitoring (SoH): Assesses long-term degradation and predicts remaining useful life based on usage patterns and internal resistance.
Without a BMS, even a high-capacity 20 kWh battery would be unsafe and inefficient. The system not only enhances safety but also optimizes performance, improves energy efficiency, and can extend the battery’s usable life by up to 30–50% with proper management.
A2: The charging time for a 20 kWh lithium-ion battery varies significantly depending on the type of charger used, the battery’s current state of charge (SoC), and the charging profile (e.g., constant current/constant voltage). Here's a breakdown:
| Charger Type | Power Output | Estimated Charging Time (0–100%) | Common Use Cases |
|---|---|---|---|
| Level 1 (Standard Home Outlet) | 1.4–2.0 kW | 10–14 hours | Overnight residential charging, backup systems |
| Level 2 (EV Charger / Wallbox) | 3.3–7.2 kW | 3–6 hours | Home, workplace, or public charging stations |
| DC Fast Charger (DCFC) | 20–50 kW | 1–2 hours | Commercial EV charging, fleet operations |
Most users opt for Level 1 or Level 2 charging at home, especially for applications like electric scooters, small EVs, or home energy storage, where overnight charging aligns perfectly with off-peak electricity rates. Fast charging is ideal for time-sensitive applications but should be used sparingly to minimize long-term battery wear.
A3: Yes, a 20 kWh lithium-ion battery is highly versatile and well-suited for both energy storage systems (ESS) and electric vehicles (EVs), thanks to its balanced capacity, compact size, and advanced chemistry. Here’s how it serves both applications:
- Energy Storage (Home/Grid): Ideal for residential solar energy storage, allowing homeowners to store excess solar power during the day and use it at night. It supports off-grid setups, backup power during outages, and peak shaving to reduce electricity bills. Its modular design allows stacking for higher-capacity needs.
- Electric Vehicles: Powers light to medium-duty EVs such as e-scooters, neighborhood electric vehicles (NEVs), small electric cars, and delivery vans. A 20 kWh battery typically provides a range of 80–150 km (50–90 miles), depending on vehicle efficiency, driving conditions, and load.
- Renewable Integration: Enables smooth integration of renewable sources like solar and wind by storing intermittent energy and releasing it when needed, improving grid stability and energy independence.
- Portability & Scalability: Due to its manageable size and weight, it's easier to install and maintain than larger systems, making it perfect for urban environments, remote areas, or mobile applications.
Manufacturers increasingly design 20 kWh batteries with dual-use capabilities—allowing them to be repurposed from EVs to stationary storage after their automotive life (a concept known as "second-life batteries"), enhancing sustainability and cost-effectiveness.
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