Custom Battery Packs? INTERESTED? - Endless Sphere

I've been thinking of a set standard on battery packs and believe it's finally time to create a simple standard on what kind of battery packs work perfectly well for our DIY Electric Skateboards.

I'm been looking into moving into Lithium NCM cells and/or LiFePO4 cells with built in charging ports.

My Reasons For Choosing Completely Custom Battery Packs
- completely custom build battery packs -- under 1" (Ex 8/9ah) or 1.5" - 1.5" if you want more capacity/longer distance Ex. 11ah
- longer life cycles
- built in charging ports
- option for cheaper battery chargers (use of multiple packs) (ex. work/home)
- safer battery packs
- safer charging - ability to leave charger alone no need to watch or monitor your charger (aka lipo)
- battery led indicator *save additional cost built-in
- built in on/off switch *save additional cost built-in

A low profile metal enclosure is on my to do list as well.

I'll actually create a post on this as it's something I've been looking into lately.

COSTS!!!
Factor in the costs for a nice lipo battery pack other than 6S --> 8S/10S/12S are hefty in cost and lack the other great features. $100-$160.

A HobbyKing 350W Power Supply + iCharger 208B = $160-$180

Easily a $300 battery pack for LIPO!

We could very easily have a $300-$450 battery pack that would have 2-5 times the life cycle as a standard HK Lipo battery.

Replacing our batteries every year or every other year isn't ideal. It ends up making our boards cost way more then they should.

What are your suggestions and your ideas on a custom battery pack that is most ideal?

Enclosure Questions

Do you prefer an aluminum one piece enclosure that goes across the entire bottom deck?

Do you prefer two aluminum enclosures to keep the flex within the center of the deck?

Define your most ideal enclosure for your battery pack + electronics? 100% behind your battery idea! Definitely at least 8ah, especially bc from what I've read on here pneumatics get less range. My HK150a esc only takes up to 6s, so not having to get a new esc would be nice.

As for enclosures, definitely sold on aluminum, again from what I've read on here (help dissipate heat and serve as a safe box for batteries). 1" in height would be perfect. Currently, I've got 2x3ss, so the minimum width of my box has to be 7" to leave room for wires, which will run between the two (not at all an ideal width). I'd imagine your battery will be much narrower than 7" though.

I'm stuck at the same fork in the road, regarding the placement. On one hand, I love Boosted's setup, with the wires concealed under the grip tape. But I'm not sure if there's a significant advantage to a split setup that would merit the work to make it. My board is stiff, and I'm planning on future decks to be too, so that's not a factor for me. I've been looking into a 7S mah pack and a 13S mah pack. Still debating and looking into if I want LiNCM packs or LiFePO4. LiFePO4 has a much larger life cycle rating than LiNCM - Although, heavier and bigger.

I was planning on about 7" width and perhaps 12" or longer and 1" height is what I would prefer.

13S mah will actually get you much further than 7S mah because of the Watt Hours. However, I have yet to figure out the actual run time for both.

We aren't using Lipo batteries so they are much bigger in size or slightly bigger.

I also prefer stiffer decks as I go downhill and uphill more often. I do need them to flex a little as I tend to ride down slight curbs. Too stiff and it might put stress on components. I do like enertion's setup with the wires underneath as trying to put them over the board for a kit is a bit too much unless you know how and have the tools.

I'm thinking of going with an aluminum enclosure that can be easily removed. I'm also trying to think of how it can be easily opened as well even though with these packs it probably doesn't matter a whole lot. What do you guys think? For some reason, I still like the option of easily opening my enclosure regardless if I ever use it or not.

So far from the looks of it. 7S mah will cost about $200-$220 and a 13S perhaps about $300-$350 in LiNCM. Haven't fully checked on LiFePO4.

My pack ratings are about 40A Cont and 80-100A Peak. With a 13S pack we won't nearly hit those amp ratings and they would actually be way less. Perhaps on the 7S it may be around those ratings.

I choose LiNCM for lighter weight and cheaper cost. I'm still debating as the LiFePo4 life cycle seems to be much more. Just need to decide if the trade off is worth it aka bigger packs + heavier weight.

ESC + Receiver shouold be fine. Velcro adhesive from HobbyKing seems to work real well. They can take the vibration. I would wrap my battery around a thin piece of foam although my current lipo's aren't and it's fine.

drmacgyver said: Shadeeba: I've seen a video that showed how to assemble lifepo4 cells that had screw tops and connected to each other with either copper or steel brackets. If I can find that video I'll link it. I'd imagine soldering would be a more reliable method though.

I think 8 of those 3v blue lifepo4 cells would make for a nice size/power pack (2 rows of 4). And I think they're 10ah too, which is awesome.

I can't find the pic. One of the coolest boards I've seen. On wacky boards .com or sounded like that. It was an aluminum deck with 2 or 4 red batteries which looked like they simply bolted at the terminals. Like the visible-board. Probably protected enough and a safer chemisty than lipo and ok exposed to rocks flying. Ill be looking for those connectors and how they do. I've seen pressurized with foam or something non-solder connections but not for sale to build something as small as 8ah. Loose cells that screwed on w some electrolyte jell at the connection if need be.. Still sounds very convenient. And cool looking.



Translucent DIY batteries might be cooler @torque they say great minds think a like

I too have been thinking about higher voltage for some time now, even more lately since vedder came on the scene with his high voltage ESC.

I have also been spending more time reading about electric bikes, the DIY E-bike scene has a lot more minds and several years head start on the DIY eboard scene... I guarantee you won't find many people building e bikes with 6S batteries. In fact even 8s or 10s is too low for most.... & there is a good reason, higher voltage is more efficient.

Obviously you can build higher voltage batteries using LIPO... but it gets problematic... Lipo pouches are more difficult to arrange when you are dealing with the small area under a skateboard deck. I must also mention more volatile chemistry.

So whats the smallest high quality battery available... looks like is the winner! at only 18mm diameter its VERY SLIM... However it needs to be used in a system thats not going to suck it too hard...Or you need to build a very large pack so it can supply the appropriate power output... but we only have the size of a skateboard to work with.

Hummina Shadeeba said: The li-ion will hit 20c and i hear thats good enough.

What cells are you referring to? Are you talking type? I think the Sony VTC5 are 12C which equates to MAX 30A cont discharge.


So i have spent some time thinking really hard about how to design the best electric skateboard components housing possible to hold the large number of cells required to deliver the power we need.

I love aluminium, it is relatively low cost, low weight & also fairly easy to work with & i think it looks great >>>


The only problem with aluminium is it you need to use what is already available, or make your own design by extruding from a mold, so to make the perfect housing to hold cells you have some expensive setup costs before you get your final product.

Also aluminium can interfere with radio signals, so for you guys with Wii receivers that would have to be housed in something else because there is no antenna to mount externally....


I personally think separate box for battery & esc is better for several reasons, for example having them separate is better for people who want to use a slightly flexi board as the flexi bit is in the middle where you don't have stiff aluminium....

However when you start to size up your cells into a format that can offer ample Wh (enough for 1.5 to 2hrs ride time) you realise that the size of the battery is fairly large, especially when your primary objective is SUPER-SLIM... which is what i want.

If you don't care about component housing thickness you have many more options.....

So you get to a point, due to battery size, where there is no point having them separate, because the gap would be about 1 inch! so no benefit.

So for me i am focusing on one single components housing......

My reasoning is, that most people do not want really flexible decks... mostly because they are not great for handling when travelling at high speeds of 45km/h plus

So this is the concept i'm working on at the moment, its a constructed housing made from a composite of carbon fibre, GR10 plate & aluminium.... super lightweight, very strong, no radio interference, only 24mm thick, & looks frocking sexy!


[youtube]HdZmRjFfWuU[/youtube]

I have taken inspiration from multicopter chassis.

I am also developing a special anti-vibration flexible mounting system that will allow the, mostly rigid housing, to be fitted to boards that have a bit of flex... However if you have a really flexiboard you will need a smaller battery and a split housing design. @onloop -- Ebike's are awesome. I've been wanting to build one but no time/space and wouldn't use it as much. Another big rabbit hole to go down. Can't fit the bike as easily on a commuter train and/or at work either.

From what it looks like 33-36" boards would be a bit too small for a thinner and larger pack. 38" - 42" boards similar to boosted/evolve would need to be used to allow for the additional space for the battery packs.

are nice.. Question is supposedly LiNCM are about 800- life cycles and LiFePO4 is about - cycles. I could be wrong haven't done additional research on it just yet.

I'm opting for the LiFePO4. If your spending $300-400 on a pack. I'd rather have the longer cycle pack.

That's also a major issue if we want 8ah to 11ah and underneath 1" in height. We need to use all space available. Having a 2 part enclosure makes it a bit more difficult.

I also agree with the flexible decks. I climb hills and go down steep hills with potholes in the way. I'm not really interested in a flexible deck. Also flex decks are mainly used for people going around 20mph and pot holes aren't as existant. If I didn't have to deal with potholes. I probably would think otherwise but for commuters I would prefer a sturdy deck. I also want the added space.

@voodoojar.

Those are some pretty great prices. I think something around 8-10ah would be a bit better for longer rides. What do you expect those 6.8ah packs to achieve in miles? What are the cont amp and peak amp for the pack? @Silenthunter - For the 13S, I plan on using Vedder ESC once it's available.

@Drmacgyver - Some 's are the same voltage as lipos and are 4.2v max and 3.7v nominal. I plan on using similar cells with 3.7v nominal. Voltage should be equal if you are referring to LiFePO4 you might be right. I haven't done as much research with LiFePO4.

I plan on switching to LiFePO4 for the added benefit of increased life cycles as well. It only makes sense hopefully it doesn't affect the size and weight as much but it perhaps might.

I plan on using my new packs with either the 8S 120A Dual ESCs and/or Vedder's ESC once it's available.

The reason for the odd cells 7S/13S is what is readily available with my supplier which would keep costs considerably lower and quicker to produce. 7S should be fine for single or dual boards looking to go under 20mph. I've been using 6S and I think I've outgrown it and enjoy using my 8S packs but they are considerably much more expensive than my 6S packs as well as since the life span is not as long as I would like. I prefer to use a custom built pack if I'm spending the money anyhow. Not sure how many miles most people have traveled with their board just yet. 8S allows me to go up hills much faster. I think the minimum height we'd be able to get with lifepo4 is right under 2". The holders for the lifepo4 headways are 40mm x 80mm and the cells themselves are 138mm x 38mm. The 's are really small though. I guess the way I see it is my enclosure now is 2.5", so getting down to 2" is still an improvement. Add to that a better battery and it's a win-win. It's still not close to ideal, which I know will irk me.

As far as speed is concerned, we should factor in the increased speed from the pneumatics for those of us that will be using those. While having extra voltage would be nice too, I've been happy with 6s (1:3 on 83mms). I think the pneumatics will give me that extra speed without having to up the voltage. The only thing I'd like are more AH's, which the lifepo4's definitely offer.

There's other factors to consider, but basically it seems we're talking about:
A slimmer (prettier?) product for a shorter time -vs- a bulkier (uglier?) product for a longer time.

I'm not sure if we'll ever reach a definitive answer, but I'm interested to hear what more people think about "size vs life span". I think you'll still find that Lipo packs are the best option. I spend some time over on the ebike forum and most of them are still using Lipo packs or want to switch over. You just can't beat their pricing. You can get 12s mah packs for around $75. Compare that to $300 to $400 for other similar Li chemistry packs. The bikers use higher voltage because of a few reasons. Most ebike controllers are rated at 30amps max. You reduce amps by increasing voltage. Also most of them are trying to increase speeds or get over a certain speed. As you know higher volts equals higher rpm and thus higher speeds. Eboards might benefit from 8s, but not much from running 12s. I've never found that I need to go faster. I've gone the other way though. Lowered the gearing to climb hills faster and make it easier on starting.
Ease of use is another thing, but not worth the extra costs. If you want higher voltage use the Lipo in series. You can get two mah 4s hard case packs for $25 each - that's cheaper than one 6s pack. Plus you keep saying a charger is over $150. You don't need a 150w charger if you charge two packs in parallel. The cheapos will do just fine.
You also will be dealing with larger size and heavier weight with other chemistries. Seems like a step backwards. Again bikes can get away with this, but on a small board you don't have the room. C rating is another factor. Most of these other packs aren't able to drain very quickly. As soon as Rc goes to something else it'll be time to change. I do think the Multistar batteries look interesting and might be great for boards. I've seen a few bikes using them. They have some mah packs. Stinks to get a bad cell on something like that.
In regards to bad cells. It does stink to have to replace batteries every once in awhile, but I had a gas powered skateboard before, and I spent much more on gas. I have batteries that are over two years old still.
I do wish that there would be some more communication between the forums. You are right that they have a few years on us with this stuff. As a boarder turned biker I'm frustrated with ebike controllers. They are massive compared to what boards use. It would be awesome to have an RC controller on a bike, but there are issues that haven't been addressed by the manufacturers. The great thing about RC stuff is the companys make so much product it brings the costs down and they are obviously making things as small as possible.

Selecting the right lithium polymer (LiPo) battery for medical devices is crucial for ensuring their reliability, efficiency, and safety. Medical devices span a wide range of applications, from wearable fitness trackers and portable diagnostic tools to implantable devices and life-saving equipment like pacemakers and defibrillators. Each application has unique power requirements, and the choice of battery can significantly impact the device's performance and user experience. This guide aims to provide a comprehensive overview of the key factors to consider when choosing LiPo batteries for various types of medical devices, ensuring optimal functionality and patient safety.

For more information, please visit our website.

What types of batteries are primarily used in medical devices?

Medical devices primarily use several types of batteries, including:

  ●Lithium Polymer (LiPo) Batteries: Known for their high energy density, lightweight, and flexible form factor.

  ●Lithium-Ion (Li-ion) Batteries: Popular for their high energy density and long cycle life.

  ●Nickel-Metal Hydride (NiMH) Batteries: Used for their stability and safety features.

  ●Alkaline Batteries: Commonly used in single-use, disposable applications.

  ●Silver Oxide Batteries: Often used in small devices like hearing aids and pacemakers due to their small size and stable voltage output.

Why do medical devices use LiPo batteries?

LiPo batteries are favored in medical devices for several reasons:

  ●High Energy Density: They provide a lot of power in a compact size, which is crucial for portable and implantable medical devices.

  ●Lightweight: Minimizes the overall weight of the device, improving portability and user comfort.

  ●Flexible Form Factor: Can be molded into various shapes and sizes to fit the design requirements of different medical devices.

  ●Long Cycle Life: Offers extended operational periods, reducing the need for frequent replacements or recharges.

  ●Low Self-Discharge Rate: Ensures the battery retains its charge over time, essential for reliability in critical medical applications.

Which medical devices use LiPo batteries?

Here are the types of medical devices that use LiPo batteries, classified from different perspectives such as wearable, portable, implantable, and others:

  ● Wearable Medical Devices

1. Smartwatches and Fitness Trackers: Used to monitor heart rate, steps, sleep patterns, and other health metrics.

2. Continuous Glucose Monitors (CGM): For continuous monitoring of blood glucose levels, especially for diabetes patients.

3. Wearable ECG Monitors: To continuously monitor heart activity and detect arrhythmias.

4. Wearable Blood Pressure Monitors: For continuous monitoring of blood pressure levels.

  ● Portable Medical Devices

1. Portable Oxygen Concentrators: Provide oxygen therapy to patients with respiratory conditions.

2. Portable Ultrasound Devices: Used for diagnostic imaging in remote locations or emergency settings.

3. Insulin Pumps: Deliver continuous insulin to manage diabetes.

4. Portable Ventilators: Provide respiratory support to patients with breathing difficulties.

5. Portable Defibrillators: Used to provide emergency treatment for cardiac arrest.

6. Sleep Apnea Screening: Portable devices used to screen for sleep apnea outside of a hospital setting.

7. Asthma Inhaler: Devices like smart inhalers that monitor usage and provide feedback.

  ● Implantable Medical Devices

1. Neurostimulators: Provide electrical stimulation to the nervous system for pain management or movement disorders.

2. Cochlear Implants: Provide a sense of sound to individuals with severe hearing loss.

  ● Diagnostic and Monitoring Devices

1. Hearing Aids: Amplify sound for individuals with hearing impairment.

2. Holter Monitors: Continuously record heart activity over 24-48 hours.

3. Digital Thermometers: Provide accurate body temperature readings.

4. Pulse Oximeters: Measure blood oxygen saturation levels.

5. Medical Light: Devices used for diagnostic purposes, such as examining wounds or during surgical procedures.

  ● Therapeutic Devices

1. Portable Infusion Pumps: Deliver medications, nutrients, or fluids to patients.

2. TENS Units (Transcutaneous Electrical Nerve Stimulation): Provide pain relief through electrical nerve stimulation.

3. Light Therapy Devices: Used for treating skin conditions or mood disorders.

4. Dental Device: Devices used in dental treatments, such as dental drills or dental imaging equipment.

  ● Emerging and Future Medical Devices

1. Smart Wearable Patches: Flexible patches that monitor vital signs or deliver medication.

2. Advanced Prosthetics: Prosthetic limbs with integrated sensors and actuators for enhanced functionality.

3. Bioelectronic Medicines: Devices that interact with the body's nervous system to treat conditions without drugs.

4. Remote Patient Monitoring Systems: Devices that monitor patients' health metrics and transmit data to healthcare providers.

How to choose LiPo Batteries for Fitness trackers？

A wearable device that monitors and tracks fitness-related metrics such as steps taken, distance walked, calories burned, and sometimes heart rate and sleep quality.

  ●Size and Weight: Fitness trackers need compact and lightweight batteries. Prismatic or pouch LiPo cells are common.

  ●Capacity: Typically between 100mAh and 200mAh, providing several days of use.

  ●Voltage: Standard 3.7V.

  ●Recharge Cycles: High cycle life (300-500 cycles) is important for daily charging.

  ●Safety: Ensure the battery has protections against overcharge, over-discharge, and short circuits.

How to choose LiPo Batteries for heart rate monitors?

A device that measures and records the electrical activity of the heart to detect irregularities. Often included in wearable fitness trackers or smartwatches to monitor heart rate continuously.

  ●Capacity: Moderate capacity, around 100mAh to 300mAh, to support continuous monitoring.

  ●Size and Weight: Compact and lightweight to ensure comfort.

  ●Voltage: Typically 3.7V.

  ●Recharge Cycles: High cycle life (300-500 cycles) for daily use.

  ●Safety: Suitable for skin contact and certified for wearable use (e.g., ISO ).

How to choose LiPo Batteries for continuous glucose monitors

A device that continuously tracks blood glucose levels throughout the day and night, providing real-time data and alerts for individuals with diabetes.

  ●Size and Weight: Small and lightweight, typically prismatic or pouch cells.

  ●Capacity: Around 50mAh to 200mAh, sufficient for continuous monitoring.

  ●Voltage: Stable output, typically 3.7V.

  ●Safety: Biocompatible and safe materials, with certifications like ISO .

  ●Recharge Cycles: High cycle life to support frequent charging.

How to choose LiPo Batteries for Blood Pressure Monitor

A device that measures blood pressure non-invasively. Wearable versions can provide continuous monitoring, while traditional models use a cuff that inflates to measure blood pressure at intervals.

  ●Capacity: Moderate, around 500mAh to mAh, for regular use.

  ●Size: Compact to fit within the measurement device.

  ●Voltage: Standard 3.7V.

  ●Safety: Certified for medical use, with overcharge and over-discharge protection.

  ●Recharge Cycles: Long cycle life for frequent recharging.

How to choose LiPo Batteries for Portable Oxygen Concentrators?

A device that extracts oxygen from the surrounding air and delivers it to patients with respiratory conditions, providing a continuous supply of oxygen in a portable form.

  ●Capacity: These devices typically need batteries with a capacity of mAh to mAh to provide several hours of use. The exact capacity required depends on the power consumption of the concentrator and the desired runtime.

  ●Voltage: Ensure the battery voltage matches the device’s requirements, often 7.4V (2S configuration) or 11.1V (3S configuration).

  ●Safety: Look for batteries with certifications such as UL, CE, or IEC . Medical-grade batteries often have additional safety features like thermal cut-offs and pressure relief valves.

  ●Size and Weight: Consider the physical dimensions and weight of the battery to ensure it fits within the device's design constraints without adding unnecessary bulk.

  ●Discharge Rate (C-rating): Ensure the battery can handle the high power draw of the concentrator, typically 1C to 2C continuous discharge rate.

How to choose LiPo Batteries for Insulin Pumps? 

A small device that delivers continuous insulin therapy through a catheter placed under the skin, helping manage blood glucose levels in individuals with diabetes.

  ●Capacity: High capacity, often mAh to mAh, to ensure reliable operation.

  ●Size and Weight: Compact to integrate easily into the pump design.

  ●Voltage: Consistent and stable, typically 3.7V.

  ●Safety: Certified for medical use, with overcharge and over-discharge protection.

  ●Recharge Cycles: Long cycle life for daily recharging.

How to choose LiPo Batteries for Ultrasound Device?

A diagnostic tool that uses high-frequency sound waves to create images of structures inside the body. Portable versions allow for use in remote or emergency settings.

  ●Capacity: High capacity, often mAh to mAh, for extended operation.

  ●Voltage: Ensure it matches the device’s requirements, often 7.4V or higher.

  ● Safety: Medical-grade certifications and robust safety features.

  ●Size: Depending on device design, ensure it fits within the housing.

  ●Discharge Rate: Able to handle high power draw, typically 2C to 5C continuous discharge rate.

How to choose LiPo Batteries for Sleep Apnea Screening

Devices used to monitor and diagnose sleep apnea by tracking breathing patterns, oxygen levels, and other metrics during sleep.

  ●Capacity: High enough for overnight use, typically mAh to mAh.

  ●Size: Compact and lightweight for comfortable use.

  ●Voltage: Consistent and stable, typically 3.7V.

  ●afety: Non-toxic and safe materials, with certifications like ISO .

  ●Recharge Cycles: High cycle life for frequent recharging.

How to Choose LiPo Batteries for Portable Ventilators?

Portable ventilators are critical devices for patients who require respiratory support. These devices must be reliable and capable of operating for extended periods without interruption. Choosing the right LiPo batteries for portable ventilators involves considering several key factors:

  ●Capacity : Ventilators need high-capacity batteries to support continuous operation. Look for batteries with capacities ranging from mAh to mAh or more, depending on the ventilator's power consumption and the desired operational duration.

  ●Voltage: Ensure the battery voltage matches the ventilator’s specifications, often around 12V (3S configuration) or 14.8V (4S configuration).

  ●Discharge Rate (C-rating): Ventilators require a moderate discharge rate to ensure stable power delivery. A discharge rate of 5C to 10C is typically sufficient.

  ●Safety: Safety is paramount in medical devices. Look for batteries with certifications such as UL, CE, or IEC . Ensure they have built-in protections against overcharge, over-discharge, short circuits, and thermal runaway.

  ●Size and Weight: The battery should be compact and lightweight to maintain the ventilator's portability.

How to Choose LiPo Batteries for Portable Defibrillators?

Portable defibrillators, such as Automated External Defibrillators (AEDs), require reliable and powerful batteries to ensure they function effectively in emergency situations. Here’s what to consider:

  ●Capacity (mAh): Typically, AEDs require batteries with capacities ranging from mAh to mAh to deliver multiple shocks and operate for extended periods.

Voltage: Ensure the battery voltage matches the device’s specifications, usually around 14.8V (4S configuration).

  ●Discharge Rate (C-rating): AEDs require a high discharge rate to deliver the necessary energy for defibrillation, typically around 20C.

  ●Safety: Look for batteries with certifications such as UL, CE, or IEC . These batteries should also have built-in protections against overcharge, over-discharge, and short circuits.

  ●Size and Weight: Ensure the battery fits within the device's design constraints and doesn’t add excessive weight.

  ●Longevity: Choose batteries with a high cycle life, capable of maintaining performance over several years.

How to choose LiPo Batteries for Asthma Inhaler?

A handheld device that delivers medication directly to the lungs to relieve asthma symptoms. Some smart inhalers track usage and provide feedback.

  ●Capacity: Sufficient for multiple uses, typically 100mAh to 500mAh.

  ●Size: Compact and lightweight to fit within the inhaler.

  ●Voltage: Standard 3.7V.

  ●Safety: Non-toxic and safe materials, with protections against overcharge and short circuits.

  ●Recharge Cycles: High cycle life for frequent recharges.

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How to choose LiPo Batteries for Neurostimulators?

An implanted device that sends electrical signals to specific areas of the nervous system to treat chronic pain, movement disorders, or other neurological conditions.

  ●Precision: Batteries must deliver consistent power for precise neurostimulation. Low self-discharge and stable voltage are crucial.

  ●Safety: High safety standards and biocompatibility are a must. Look for batteries with medical-grade certifications.

  ●Capacity: Adequate capacity to support long-term use, typically 500mAh to mAh.

  ●Voltage: Stable output, usually around 3.7V.

  ●Size: Small form factor to fit within the device.

How to Choose LiPo Batteries for Cochlear Implants?

Cochlear implants require small, reliable batteries to power the device that helps improve hearing:

  ●Size: Very small and compact, often using coin cell or button cell LiPo batteries.

  ●Capacity: Typically between 10mAh to 50mAh, sufficient for daily use.

  ●Voltage: Standard 3.7V.

  ●Longevity: High cycle life, as these batteries need to be recharged frequently, commonly rated for 300-500 cycles.

  ●Safety: Non-toxic, biocompatible, and safe materials, with certifications such as ISO .

  ●Recharge Speed: Fast charging capabilities to minimize downtime for users.

How to choose LiPo Batteries for OTC Hearing Aids

Over-the-counter devices that amplify sound to help individuals with hearing loss. These are typically less expensive and more accessible than prescription hearing aids.

  ●Size: Hearing aids require very small, compact batteries. Coin cell or button cell LiPo batteries are commonly used.

  ●Capacity: Usually ranges from 10mAh to 50mAh, sufficient for a full day of use.

  ●Voltage: Typically 3.7V.

  ●Longevity: High cycle life is essential, as these batteries need to endure daily recharges. Look for batteries rated for 300-500 cycles.

  ●Safety: Non-toxic and safe materials are crucial, along with certifications like ISO for biocompatibility.

How to choose LiPo Batteries for Oxygen Monitor

A device that measures the oxygen saturation level in the blood and pulse rate. Commonly used in both clinical and home settings.

  ●Capacity: Adequate for extended use, generally 500mAh to mAh.

  ●Size: Compact to ensure the monitor remains portable.

  ●Voltage: Standard 3.7V.

  ●Recharge Cycles: High cycle life for frequent recharging.

  ●Safety: Certified for medical use with protections against overcharge and short circuits.

How to choose LiPo Batteries for Medical Light?

Devices used to provide illumination for diagnostic examinations, surgical procedures, or therapeutic purposes.

  ●Capacity: High to support extended use, often mAh to mAh.

  ●Voltage: Ensure it matches the light’s requirements, often 7.4V or higher.

  ●afety: Medical-grade certifications and robust safety features.

  ●Size: Depending on device design, ensure it fits within the housing.

  ●Discharge Rate: Able to handle high power draw, typically 2C to 5C continuous discharge rate.

How to Choose LiPo Batteries for Holter Monitors?

Holter monitors are used for continuous heart rate monitoring over 24-48 hours or longer, requiring reliable and long-lasting batteries:

  ●Capacity: Typically between 500mAh to mAh to support continuous monitoring.

  ●Voltage: Standard 3.7V.

  ●Size: Compact to ensure the monitor remains portable and comfortable for the patient.

  ●Longevity: High cycle life to support frequent recharges.

  ●Safety: Certified for medical use with protections against overcharge, over-discharge, and short circuits.

How to Choose LiPo Batteries for Digital Thermometers?

Digital thermometers require small, reliable batteries for accurate temperature measurement:

  ●Capacity: Typically very small, around 100mAh to 200mAh.

  ●Voltage: Standard 3.7V.

  ●Size: Compact to fit within the thermometer housing.

  ●Safety: Safe and non-toxic materials, with certifications like UL and CE.

  ●Longevity: Moderate cycle life, as these devices are not used continuously.

How to choose LiPo Batteries for Bioelectronic Medicines

Devices that use electrical stimulation to modulate the body's nervous system to treat diseases and conditions without drugs.

  ●Precision: Consistent and stable power delivery is crucial. Low self-discharge and stable voltage are necessary.

  ●Safety: High safety standards and biocompatibility, with certifications like ISO .

  ●Capacity: Moderate to high, around 500mAh to mAh, depending on usage.

  ●Voltage: Stable output, typically 3.7V.

  ●Size: Small form factor to fit within the device.

How to choose LiPo Batteries for Smart Wearable Patches

Flexible patches that adhere to the skin and monitor various health metrics, such as heart rate, glucose levels, or temperature, often with integrated sensors and wireless communication.

  ●Size and Weight: Ultra-compact and lightweight, typically prismatic or pouch cells.

  ●Capacity: Sufficient for continuous monitoring, around 50mAh to 200mAh.

  ● Voltage: Typically 3.7V.

  ●Safety: Certified for skin contact with biocompatible materials (e.g., ISO ).

  ●Recharge Cycles: High cycle life to support frequent recharging.

How to choose LiPo Batteries for Advanced Prosthetics

Prosthetic limbs with advanced functionality, including integrated sensors, actuators, and sometimes neural interfaces, providing improved movement and control for amputees.

1. Capacity: High to support advanced functions, often mAh to mAh.

2. Size and Weight: Compact and lightweight to integrate seamlessly.

3. Voltage: Stable and consistent, typically 3.7V.

4. Safety: Biocompatible and safe materials, with certifications like ISO .

5. Recharge Cycles: Long cycle life for daily recharging.

How to choose LiPo Batteries for Remote Patient monitors

Systems that use various devices to monitor patients' health metrics remotely, transmitting data to healthcare providers for continuous care and management.

  ●Capacity: High for continuous monitoring, typically mAh to mAh.

  ●Size: Compact and lightweight for portability.

  ●Voltage: Stable output, typically 3.7V.

  ●Safety: Certified for medical use, with robust safety features.

  ●Recharge Cycles: Long cycle life for frequent recharging.

How to choose LiPo Batteries for Dental Device

Various tools and equipment used in dental care and treatments, including drills, imaging devices, and orthodontic appliances.

  ●Capacity: Moderate to high, around 500mAh to mAh, for consistent use.

  ●Size: Compact to fit within the device.

  ● Voltage: Standard 3.7V.

  ●Safety: Certified for medical use, with overcharge and over-discharge protection.

  ●Recharge Cycles: High cycle life for frequent recharging.

How to Choose LiPo Batteries for Portable Infusion Pumps

Infusion pumps require reliable and long-lasting batteries to ensure continuous medication delivery:

  ●Capacity: Typically between mAh to mAh to ensure extended operation.

  ●Voltage: Standard 3.7V.

  ●Size and Weight: Compact and lightweight to integrate easily into the pump design.

  ●Safety: Certified for medical use, with robust safety features like overcharge and short circuit protection.

  ●Longevity: High cycle life to support frequent recharges.

How to Choose LiPo Batteries for TENS Units

Transcutaneous Electrical Nerve Stimulation (TENS) units require reliable batteries to deliver pain relief therapy:

  ●Capacity: Typically between 500mAh to mAh to support multiple therapy sessions.

  ●Voltage: Standard 3.7V.

  ●Size and Weight: Compact and lightweight for portability.

  ●Safety: Certified for medical use with protections against overcharge and short circuits.

  ●Longevity: High cycle life to support frequent recharges.

How to Choose LiPo Batteries for Light Therapy Devices

Light therapy devices require powerful batteries to support prolonged use:

  ●Capacity: Typically between mAh to mAh to ensure extended operation.

  ●Voltage: Ensure it matches the device’s requirements, often 7.4V or higher.

  ●Discharge Rate (C-rating): Able to handle high power draw, typically around 2C to 5C continuous discharge rate.

  ●Safety: Medical-grade certifications and robust safety features.

  ●Size and Weight: Depending on device design, ensure it fits within the housing and doesn’t add unnecessary weight.

Conclusion

In conclusion, the selection of flexible LiPo batteries for medical devices requires careful consideration of multiple factors, including capacity, voltage, size, weight, safety, and longevity. Each type of medical device has specific requirements that must be met to ensure reliable operation, patient safety, and user comfort. By understanding these requirements and choosing the appropriate LiPo battery specifications, manufacturers can enhance the performance and reliability of their medical devices, ultimately improving patient care and outcomes. Whether for wearable fitness trackers, portable diagnostic tools, or critical implantable devices, the right LiPo battery choice is essential for advancing medical technology and providing better healthcare solutions. If you have any questions or needs about our button cell batteries, please feel free to contact us at .

FAQ

Are lipo batteries safe for medical device applications?

LiPo batteries can be safe for medical device applications if they are specifically designed and certified for such use.

How long do medical device batteries typically last?

Battery lifespan varies depending on usage and type but generally lasts months to years. Lipo batteries typically last 2 to 5 years or around 300 to 500 charge cycles.

Can medical device batteries be recharged?

Some medical device batteries are rechargeable, while others are disposable and cannot be recharged. Lipo and NiMH batteries can be rechargeable. alkaline or lithium primary cells cannot be recharged.

What certifications are needed for medical device lipo batteries?

When selecting LiPo batteries for medical devices, it is essential to ensure they meet specific certification requirements to guarantee safety, reliability, and compliance with industry standards. Here are the key certifications required:

  ●ISO : This certification indicates that the batteries are manufactured in accordance with the international standards for quality management systems specific to the medical device industry.

  ●IEC : This standard pertains to the safety requirements for portable sealed secondary cells, and it is crucial for batteries used in medical devices to meet these criteria.

  ●UL : This certification ensures the batteries have passed rigorous testing for safety and performance, including assessments for potential hazards like overheating, short-circuiting, and overcharging.

  ●CE Mark: For batteries used in the European market, the CE mark is essential as it signifies compliance with EU safety, health, and environmental protection standards.

  ●UN 38.3: This certification is crucial for batteries that will be transported by air, sea, or land, ensuring they have passed tests for altitude simulation, thermal tests, vibration, shock, external short circuit, impact, overcharge, and forced discharge.

What safety certifications are needed for the transportation of medical device batteries?

When transporting LiPo batteries for medical devices, ensuring they have the appropriate safety certifications is vital to prevent hazards during transit. Here are the necessary safety certifications for transportation:

  ●UN 38.3: This certification is mandatory for lithium batteries transported by air, sea, or land. It includes tests for altitude simulation, thermal tests, vibration, shock, external short circuit, impact, overcharge, and forced discharge.

  ●IATA DGR (Dangerous Goods Regulations): Batteries must comply with the International Air Transport Association’s regulations for the safe transportation of dangerous goods by air.

  ●IMDG Code (International Maritime Dangerous Goods): For batteries transported by sea, compliance with the International Maritime Organization's regulations for dangerous goods is required.

  ●49 CFR (Code of Federal Regulations): In the United States, batteries must meet the Department of Transportation's hazardous materials regulations for safe transportation.

  ●ADR (European Agreement Concerning the International Carriage of Dangerous Goods by Road): For road transport in Europe, batteries must comply with the ADR regulations to ensure safe and secure transportation.

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