A defibrillator battery is a specialized power source designed to provide energy to defibrillators, which are medical devices used to deliver electric shocks to the heart in order to restore a normal heart rhythm in cases of cardiac arrest or other life-threatening heart conditions.
When every second counts, trust the Worldpower Defibrillator Battery to deliver unmatched reliability and power for your defibrillator. Designed with advanced lithium technology, our batteries ensure that your life-saving device is always ready when it matters most.
| Specification of 12V Medical Defibrillator Battery battery pack | |
| Voltage | 11.1V |
| Capacity | 4200mAh |
| Discharge current | 12.5A continuous |
| Charging Current | <1A |
| Working Voltage | 8.25V-12.6V |
| Charging Cut-off Voltage | 12.6V |
| Discharge Cut-off Voltage | 8.25V |
| Load power | 5W/15W/20W/30W |
| Cycle Life | 800+cycles |
| Charge Temperature | 0℃ to 45℃ |
| Discharge Temperature | -20℃ to 60℃ |
| Humidity | 60±25%R.H |
| Model | Voltage | Capacity | Discharge Current | Charging port | Protocol |
| WP-DX14 | 11.1V | 2000mAh | 12.5A Continuous | Same Port | / |
Automatic Battery Protection Module/System
Low Voltage Disconnect
Over Voltage Disconnect
Short Circuit Protection
Reverse Polarity Protection
Cell Balancing
Instant Power on Demand – Get the high-voltage energy needed to deliver a life-saving shock, instantly and reliably.
Long Standby Life – With up to 7 years of shelf life, our defibrillator batteries stay charged and prepared for emergencies, so you're always ready.
High Capacity & Fast Recharge – Whether you choose our rechargeable or non-rechargeable models, experience long-lasting performance and quick recharge times, ideal for hospitals, ambulances, and home-use AEDs.
Built-In Safety & Reliability – Worldpower’s batteries meet the highest medical-grade standards, providing you with peace of mind knowing your defibrillator will work precisely when you need it.
Trusted by Professionals – From hospitals to emergency responders, Worldpower Defibrillator Batteries are trusted to deliver power in critical moments.
When lives are on the line, choose Worldpower Defibrillator Battery for safety, reliability, and performance you can trust.
Customizing your defibrillator battery involves tailoring the battery’s specifications to meet the unique requirements of the defibrillator model and its usage. Here's a step-by-step guide to help you through the process:
1. Determine the Power Requirements:
· Voltage: Check the defibrillator’s voltage requirements. Most defibrillators operate on voltages between 12V and 24V, but this can vary depending on the model.
· Capacity (mAh or Ah): Determine how long you want the battery to last. A higher capacity (measured in milliamp-hours (mAh) or amp-hours (Ah)) will allow for longer use between charges or replacements.
· Discharge Rate: Defibrillators need a high discharge rate to deliver powerful, short bursts of energy. Ensure the battery can safely deliver the necessary energy for high-voltage shocks.
2. Choose the Battery Type:
· Lithium-Ion (Li-ion): Offers high energy density, lightweight, and fast recharge capabilities. Ideal for manual defibrillators used in hospitals or ambulances.
· Lithium Manganese Dioxide (LiMnO2): Common in Automated External Defibrillators (AEDs), these non-rechargeable batteries have a long shelf life (up to 7 years).
· Nickel Cadmium (NiCd): These are less common but may be used in certain defibrillators due to their durability and ability to handle frequent use and recharging.
3. Configure Battery Pack Design:
· Series/Parallel Configuration: Depending on the voltage and capacity required, design the battery pack by connecting cells in series (to increase voltage) or in parallel (to increase capacity).
· Size and Shape: Customize the physical size and shape of the battery pack to fit the specific defibrillator model. The form factor may need to be compact for portability, especially in AEDs.
4. Integrate a Battery Management System (BMS):
A Battery Management System (BMS) is crucial for ensuring safety and optimal performance. The BMS will:
· Prevent overcharging/overdischarging to avoid damage to the battery.
· Balance the cells in the battery pack, ensuring even charging/discharging for a longer battery life.
· Monitor temperature to prevent overheating, which can lead to failure or safety hazards.
· Provide protection against short circuits or overloads.
5. Select Rechargeable or Non-Rechargeable:
· Rechargeable: Suitable for manual defibrillators used in hospitals or frequently used devices, rechargeable batteries offer convenience and cost savings in the long run.
· Non-Rechargeable: Common in AEDs, these batteries have long standby life (up to 7 years) and are designed to be replaced after a certain number of uses or when the battery is depleted.
6. Include Thermal Management:
Defibrillators can generate heat during use, especially when delivering high-energy shocks. Implement thermal management solutions to dissipate heat, such as:
· Heat sinks or vented battery casing for improved cooling.
· Thermal sensors integrated into the BMS to monitor and manage temperature.
7. Battery Case and Durability:
· Protective Casing: The battery should be housed in a durable, shock-resistant case to protect it from impacts or rough handling during emergencies.
· Waterproof/Sealed Design: For AEDs used in outdoor or harsh environments, consider a waterproof or sealed design to protect the battery from moisture and dust.
8. Safety Features and Standards:
Defibrillator batteries must comply with medical-grade safety standards. Ensure that the battery pack is:
· ISO 13485 compliant (medical devices quality management system).
· UL 1642 or IEC 62133 certified (safety standards for lithium-ion batteries).
· FDA Approved (if applicable in your region).
9. Choose the Right Charging System:
If you're customizing a rechargeable battery, you’ll need a compatible charging solution:
· Smart Charger: Select or customize a charger that matches the battery’s voltage and current specifications.
· Fast Charging Capability: If the defibrillator is used frequently (e.g., in hospitals or ambulances), a fast-charging system may be important to minimize downtime.
10. Work with a Custom Battery Manufacturer:
Partner with a battery manufacturer experienced in creating custom battery packs for medical devices. Provide them with:
· Voltage and capacity requirements.
· Defibrillator model details.
· Form factor and size constraints.
· Any specific regulatory or certification needs.
11. Testing and Validation:
After designing the battery, it’s crucial to test and validate its performance:
· Cycle Testing: Ensure the battery can go through multiple charge and discharge cycles without degradation.
· Temperature and Stress Testing: Simulate real-world conditions, including temperature extremes and high discharge rates, to confirm safe and reliable performance.
· Emergency Simulations: Test the battery under typical usage scenarios to ensure it can deliver the necessary shock power when required.
1. Define power needs (voltage, capacity, discharge rate).
2. Select battery type (Li-ion, LiMnO2, etc.).
3. Design the pack configuration (series/parallel connections).
4. Add a Battery Management System (BMS) for safety and efficiency.
5. Choose between rechargeable or non-rechargeable options.
6. Implement thermal management to prevent overheating.
7. Ensure protective casing for durability and environmental protection.
8. Adhere to medical safety standards for compliance and reliability.
9. Customize the charging system for fast and reliable recharging.
10. Work with a trusted battery manufacturer for design and production.
11. Test and validate the battery to ensure safety and performance.
By following these steps, you can create a custom defibrillator battery that meets the specific needs of your defibrillator, ensuring that it is reliable, safe, and effective in delivering life-saving shocks.
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