Professional Battery Solutions for Delivery Robots
Reliable power for your autonomous delivery robots, ensuring long-distance mobility, stable operation, and efficient performance across commercial and outdoor environments.
The application of Oxygen Concentrators
Delivery robots are widely used in last-mile logistics, commercial campuses, residential communities, industrial parks, shopping malls, hotels, hospitals, and outdoor delivery scenarios.
In urban logistics, delivery robots transport parcels, food, and retail goods autonomously, reducing labor costs and improving efficiency.
In hotels and commercial buildings, service delivery robots handle guest amenities and internal logistics with high reliability and safety.
In campuses and residential areas, delivery robots enable unmanned distribution across long distances, requiring powerful battery systems to handle complex routes and varying terrains.
Delivery robots play a crucial role in modern unmanned delivery, where continuous mobility, long-range endurance, and multi-scenario adaptability are essential. With the rapid expansion of last-mile logistics, the demand for safe, durable, and high-performance delivery robot batteries continues to grow.
LargePower specializes in advanced lithium battery solutions tailored for delivery robots, offering long cycle life, fast charging, stable discharge output, and intelligent BMS protection to support reliable autonomous delivery in dynamic environments.
KRL PowerCore Technology
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Our industry-leading lithium battery solutions are widely used across outdoor autonomous delivery robots, food delivery robots, parcel distribution robots, hotel service robots, campus and community logistics robots, and hospital internal logistics robots. By working closely with global delivery robot manufacturers, we ensure stable mobility, long endurance, and seamless system integration for every application.
18650 14.4V 6700mAh lithium battery pack for oxygen concentrators
Our custom low-temperature batteries are designed to perform in extreme cold conditions, ensuring reliable power output for your specific application needs.
14.8V 4400mAh 18650 medical ventilator ternary lithium battery
14.8V 4400mAh lithium battery pack with UR18650 cells, compact 155×75×22mm design, reliable GB/T 18287-2000 standard, stable power for devices.
11.1V 2200mAh 18650 lithium battery pack for respirators
11.1V 2200mAh lithium battery pack, compact 71×56×19mm, reliable 18650-3S1P design, GB/T 18287-2000 standard, stable power and safe storage.
10.8V 3180mAh breathing machine 18650 lithium battery pack
10.8V 3180mAh lithium battery pack with NCR18650BD cells, 160g compact design, smart BMS protection, reliable power solution for ventilators.
10.8V 6.4Ah 18650 Samsung medical ventilator ternary lithium battery pack
10.8V 6.4Ah medical ventilator lithium battery pack, industrial-grade casing, SMBus communication, high-safety 18650 cells, stable power and long cycle life.
18650 14.4V 6.7Ah Breathing Machine Lithium Battery Pack
14.4V 6.7Ah lithium battery pack with 18650 cells, SMBUS communication, advanced BMS protection, long cycle life, ideal for ventilators and handheld medical devices.
Why Choose LargePower Delivery Robot Batteries
Certified to IEC and UL standards, equipped with advanced BMS protection for safe operation in outdoor and commercial environments.
High-energy-density batteries support 8–20 hours of continuous delivery depending on route complexity and payload.
Stable discharge performance ensures smooth movement, climbing ability, and consistent torque for varying terrains.
Multiple Safety Protections
Protection against overcharge, over-discharge, short circuit, overcurrent, and temperature fluctuations ensures long-term reliability.
Smart Battery Management System
Real-time monitoring, intelligent SOC/SOH calculation, fault alerts, and CAN/RS485 communication for fleet management platforms.
Fast Charging & Swappable Battery Options
Supports 1–2 hour fast charging and hot-swappable battery systems to maximize operational uptime.
Product Comparison
LargePower delivery robot batteries vs. standard lithium batteries
| Feature | LargePower Delivery Robot Battery | Standard Lithium Battery | Advantage |
|---|---|---|---|
| Safety Certification | IEC/UL + Smart BMS | Basic protection | Industrial-grade safety |
| Runtime | 8–20 hours | 4–10 hours | Up to 2× longer operation |
| Cycle Life | 2000+ cycles | 500–800 cycles | +150% extended lifespan |
| Charge Time | 1–2 hours fast charging | 3–5 hours | Rapid recovery |
| Communication | CAN/RS485 + real-time monitoring | No intelligent communication | Supports robot fleet systems |
| Durability | IP-rated, outdoor-ready | Low environmental resistance | Better for real-world delivery |
WHAT OUR PARTNERS SAY
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We conduct comprehensive electrical, mechanical, and environmental testing to ensure stable power performance for delivery robots across urban, commercial, and outdoor environments.
With robust supply chain capabilities and customizable battery engineering, we deliver high-performance solutions where endurance meets intelligent logistics.
Relevant Guidelines
Lightweight and Compact Battery Designs for Portable Oxygen Concentrators
Why Choose Custom Lithium Battery Packs for Oxygen Concentrator
A Side-by-Side Look at Leading Portable Oxygen Concentrator Battery Packs
How Battery Pack Design Influences Portable Oxygen Concentrator Performance
Choosing the Safest and Most Reliable Lithium Battery for Oxygen Generators
Oxygen Concentrator Battery FAQ
What are the best battery types for delivery robots?
What battery requirements should be checked before selecting a battery for a delivery robot?
- Voltage and capacity requirements
- Peak/continuous discharge current
- Battery weight limits
- Operating temperature range
- Charging time expectations
- Cell chemistry preference
- Built-in BMS compatibility
- Required certifications (UN38.3, UL, CE) This helps ensure the battery matches both performance needs and regulatory requirements.
How do lithium-ion and lithium-polymer batteries compare for delivery robots?
| Attribute | Lithium-Ion | Lithium-Polymer |
|---|---|---|
| Energy Density | High | Higher |
| Shape Flexibility | Limited | Very flexible |
| Weight | Low | Lower |
| Cycle Life | Long | Medium–long |
| Cost | Medium | Slightly higher |
| Safety | Good | Good with proper BMS |
Who are the major manufacturers of batteries for robotic applications?
How do I choose the right battery for a custom delivery robot project?
2.Estimating runtime requirements
3.Selecting a suitable battery chemistry
4.Determining pack size and allowable weight
5.Adding BMS requirements
6.Evaluating environmental conditions
7.Validating with prototype tests This helps builders select the best battery for performance and safety.
Why is a battery management system (BMS) important for delivery robot fleets?
What makes a battery “smart” in robotics applications?
- Built-in BMS
- Real-time monitoring
- CAN / RS485 communication
- Cycle tracking
- Fault detection and protection These capabilities help the robot manage energy more efficiently and safely.
What does a cost analysis for delivery robot batteries include?
- Battery chemistry used
- Capacity and discharge rate
- BMS complexity
- Expected cycle lifespan
- Charging infrastructure Pricing guides often compare long-term cost per cycle, not just upfront price.
What battery specifications are used in robots like Starship or Amazon Scout?
- Lithium-based packs (Li-ion / LiPo / LiFePO4)
- High energy density cells
- Modular pack designs
- Thermal management systems Compiled product specification sheets help illustrate how commercial delivery robots meet range and safety needs.
Should delivery robots use swappable batteries or fast charging stations?
- Swappable batteries maximize uptime and suit high-frequency delivery fleets
- Fast charging works well for small fleets or predictable operation cycles Companies choose based on operation scale, infrastructure cost, and routing behavior.
What safety standards apply to high-capacity lithium batteries in robots?
- UN38.3 transport testing
- UL 2580 / UL 2271 for light electric vehicles
- IEC 62133 for lithium rechargeable cells
- CE and RoHS compliance Safety-related FAQs often address thermal management, certification limits, and risk prevention.
How should a delivery robot fleet maintain its batteries?
- Regular cycle-life checks
- Temperature monitoring
- Proper storage protocols
- Balancing charge levels during low use Video tutorials and maintenance transcripts help operators extend battery lifespan in commercial fleets.
