Our intelligent BMS extends battery life by 30% in the same form factor.
Exceed industry standards with our S-Tier Safety Testing Protocol for total compliance.
Fit powerful, custom batteries into award-winning designs with our miniaturization expertise.
STEM robots in schools and homes spend most of their time in short bursts of motor action and sensor reading, then pause while kids debug code or swap parts. Our lithium packs are built around that exact classroom flow—quick power spikes followed by long idle moments.
What actually makes a difference on the desk:
We listen to teachers and after-school coaches, turning their real-world frustrations into packs that let every session run to completion.
→ Share your robot’s motor profile and we’ll size a pack that fits the chassis perfectly.
A robot that powers down halfway through a coding challenge or feels warm to the touch quickly kills excitement. Our packs are shaped by those classroom moments, with enclosures and safeguards that stay invisible yet fully protective.
Core protections that matter in schools:
The packs line up with the standards your procurement teams expect, so the focus stays on learning.
→ Tell us your target markets and we’ll show how the design supports the required safety framework.
Educational robots earn their place when they run steadily through a full 45-minute class or after-school club, not just in a lab test. We validate ours on the same mixed-use patterns teachers actually see—short drives, sensor polling, and long pauses while kids think.
What educators notice right away:
The result is simple: robots stay ready, and the focus stays on discovery.
→ Describe your typical lesson length and we’ll share matching runtime data.
Every STEM kit has its own shape, weight targets, and power logic for young hands. We treat customization as a close conversation with your engineers to make the battery feel like it was born inside the frame.
Typical refinements we deliver:
We iterate until the pack slides in and the robot feels complete.
→ Send your drawings and power needs and we’ll return a proposal that clicks.
Classroom orders often spike before the new term. Our lines keep quality locked so every pack performs the same way.
What keeps supply dependable:
You get supply you can count on.
→ Let’s review the line and current capacity together.
Getting lithium packs to schools and makers means balancing safety rules with tight back-to-school windows. We handle the details so your line never stalls.
Services that keep things moving:
→ Share your shipping points and we’ll map the smoothest route.
Q1: Which chemistry works best for STEM educational robots?
Lithium-polymer strikes the ideal balance—compact, high-density power with the low weight and gentle discharge kids’ robots need.
Q2: Can the pack handle classroom drops and still last?
Yes—drop-resistant construction and coated boards keep everything safe while allowing quick swaps.
Q3: Are the batteries suitable for school and home markets?
They are engineered to comply with CE, UN38.3, UL, and RoHS standards.
Q4: What MOQ should we plan for?
It depends on chemistry and tweaks; we keep entry points flexible for prototypes and full classroom sets.
Q5: Do you support integration with robot controllers and charging docks?
Absolutely—our team tunes BMS communication for seamless power management and safe partial charging.
Customer Background & Application Needs
A European manufacturer supplies programmable robots to schools and parents across the EU and North America.
Market data from popular kits like mBot and similar Arduino-based platforms shows educators need batteries that support 2–4 hour classroom sessions with motors, sensors, and coding without interruptions, while staying lightweight for children to handle.
Key requirements:
• 2–4 hour runtime for full lessons and experiments
• Lightweight under 50 g plus drop resistance for daily classroom use
• -0 °C to 40 °C tolerance and simple USB charging
• High cycle life for year-round school schedules
Himax Battery Solution & Configuration
We supplied a Lithium-Polymer pack based on proven configurations used in mBot-style educational robots.
Battery specification:
• Type: Lithium-Polymer
• Voltage: 3.7 V
• Capacity: 2200 mAh
• Energy: 8.14 Wh
• Setup: High-capacity pouch-cell array with BMS
Key traits:
• Extended reserve for uninterrupted lesson time
• Ultra-light sealed build for easy child handling
• Multi-level protection against over-discharge, surges, and temperature swings
Compliance, Value & Practical Outcomes
Built on a mature platform engineered to comply with UN38.3, CE, and RoHS standards plus real-world drop and discharge validation.
Results after integration:
• Full-lesson operation with no mid-session power loss
• Fewer replacements thanks to high cycle life and durability
• Straightforward scaling with consistent classroom performance data
Himax turns everyday educational demands into safe, long-lasting power that keeps kids engaged and teachers confident.
Shawn
Battery Engineer
– Power System Design
With over 10 years of experience in lithium battery system design, he specializes in Li-ion, LiFePO4, and LiPo battery packs. His expertise includes BMS integration, thermal management, and custom power solutions for medical and consumer devices.
Dawn
Battery Engineer
– Safety & Compliance
A senior battery engineer focused on safety, testing, and certification. She has extensive experience with UN38.3, IEC 62133, IEC 62619, and CE compliance, supporting battery solutions for medical, industrial, and portable electronic applications.
Joan
Battery Engineer
– Custom Pack Development
Specializing in custom battery pack development, he works closely with OEM clients to optimize voltage, capacity, and form factor. His work supports scalable mass production with strict quality control and long-term reliability.
Alden
Battery Engineer
– Manufacturing & Quality Control
With hands-on experience in battery pack manufacturing, he oversees production processes, aging tests, and quality inspections. His work ensures consistent performance, low defect rates, and stable supply for OEM customers.
Caleb
Battery Engineer
– BMS & Protection Systems
Focused on battery management systems and protection design, she develops PCM/BMS solutions with overcharge, over-discharge, thermal, and short-circuit protection to enhance safety and operational stability across applications.
Nath
Battery Engineer
– Cell Selection & Performance
An experienced battery engineer specializing in cell evaluation and performance optimization. He focuses on energy density, discharge stability, and cycle life, ensuring reliable battery packs for medical and consumer electronic applications.
Certification scope depends on target markets and device classification and should be considered during battery design.
View the full list of battery certifications and compliance standards on our Certification page.
We respond within 1 business day.
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