Battery compartment ventilation

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CT846

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I'm in the process of updating the wiring in my '80s Scotland based yacht (lots of corroded copper cable being replaced with correctly gauged tinned copper). I'm also upgrading the charging circuits using Victron equipment (Orion XS, Blue Smart, SmartSolar MPPT, Smart shunt etc). The plan is to use my existing Lead Acid batteries (2 x 140Ah) but with the future option of changing to LifePo4 (say 300Ah). There is no intention for running 'high power' inverters, so I will be dealing with modest 12v usage & charging currents (say max 60A combined alternator / solar charging).

I am also taking advantage of moving the location of the house batteries from their current position under a seat / bunk in the saloon to in a unit next to the Nav station.

My question is about ventilation. The current battery location is unventilated. I'm understand the need to vent potential hydrogen build-up from charging lead acid batteries & also the advice to provide 'suitable ventilation' for gases that could be produced by LifePo4 batteries if they overheat. From the new battery location there is the potential to run some ventilation ducting up and out to the cockpit, although space is reasonably tight.

What is considered 'suitable ventilation'? I'm unable to find any guidance to ventilation pipe diameter or cross-sectional area. I understand that two ventilation ducts are better (one high & one low) and also that there's the potential to use (computer) fans to help force ventilation if required. Does anyone have any experience of adding ventilation ducting?
 
CT846 said:
I'm in the process of updating the wiring in my '80s Scotland based yacht (lots of corroded copper cable being replaced with correctly gauged tinned copper). I'm also upgrading the charging circuits using Victron equipment (Orion XS, Blue Smart, SmartSolar MPPT, Smart shunt etc). The plan is to use my existing Lead Acid batteries (2 x 140Ah) but with the future option of changing to LifePo4 (say 300Ah). There is no intention for running 'high power' inverters, so I will be dealing with modest 12v usage & charging currents (say max 60A combined alternator / solar charging).

I am also taking advantage of moving the location of the house batteries from their current position under a seat / bunk in the saloon to in a unit next to the Nav station.

My question is about ventilation. The current battery location is unventilated. I'm understand the need to vent potential hydrogen build-up from charging lead acid batteries & also the advice to provide 'suitable ventilation' for gases that could be produced by LifePo4 batteries if they overheat. From the new battery location there is the potential to run some ventilation ducting up and out to the cockpit, although space is reasonably tight.

What is considered 'suitable ventilation'? I'm unable to find any guidance to ventilation pipe diameter or cross-sectional area. I understand that two ventilation ducts are better (one high & one low) and also that there's the potential to use (computer) fans to help force ventilation if required. Does anyone have any experience of adding ventilation ducting?
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Little note of caution. If using a computer fan it should be on the input side of the vent. system, you don't want to be dragging hydrogen over something that could cause a spark :eek: As for for vent pipe anything 50 mm or above and yes an inlet and outlet would be ideal.
 
CT846 said:
I'm in the process of updating the wiring in my '80s Scotland based yacht (lots of corroded copper cable being replaced with correctly gauged tinned copper). I'm also upgrading the charging circuits using Victron equipment (Orion XS, Blue Smart, SmartSolar MPPT, Smart shunt etc). The plan is to use my existing Lead Acid batteries (2 x 140Ah) but with the future option of changing to LifePo4 (say 300Ah). There is no intention for running 'high power' inverters, so I will be dealing with modest 12v usage & charging currents (say max 60A combined alternator / solar charging).

I am also taking advantage of moving the location of the house batteries from their current position under a seat / bunk in the saloon to in a unit next to the Nav station.

My question is about ventilation. The current battery location is unventilated. I'm understand the need to vent potential hydrogen build-up from charging lead acid batteries
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If your LA batteries are venting more than a tiny amount when on bulk charge you have a problem. Hydrogen is lighter than air anyway, so will quickly disperse. It is possible that a faulty battery or charger can cause excessive venting, but even so, it's unusual for battery compartments on boats to have vent pipes. No reason why you can't fit something simple, such as a pipe from the top of the battery compartment to the outside. Only needs to be a small pipe and certainly no need for fans.
CT846 said:
& also the advice to provide 'suitable ventilation' for gases that could be produced by LifePo4 batteries if they overheat.
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If your LFP battery is overheating and venting gas you have a very serious issue, the BMS should not allow the battery to overheat in use. LFP cells are sealed, so no need/point in providing ventilation for venting. If the batteries are in a location where the ambient temperature can adversely affect the battery then venting might be needed and a fan would likely be needed too. Such venting would need to be automatically controlled, you would not want fans running continuously. But, better to install in a more suitable location.
 
Great, thank you for the advice. I totally agree that, with a correctly designed system, there shouldn't be any serious amount of gases produced, however I'm very conscious of the potential issues around insurance & some of the recent advice / guidelines / standards about lithium installs. It makes sense to address that now while everything's in bits!
 
CT846 said:
Great, thank you for the advice. I totally agree that, with a correctly designed system, there shouldn't be any serious amount of gases produced, however I'm very conscious of the potential issues around insurance & some of the recent advice / guidelines / standards about lithium installs. It makes sense to address that now while everything's in bits!
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Link to LFP standards that require ventilation for gassing please ?

If your system is so designed that it allows the LFP battery to overheat and vent gas, you are doomed.
 
CT846 said:
MCA guidance (para6 ) MGN 550 (M+F) Amendment 1: Electrical installations - guidance for safe design, installation and operation of lithium-ion batteries
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That's for commercial vessels, not relevant to leisure boats.

CT846 said:
Haven Knox Johnston insurance guidelines (#3) https://www.havenkj.com/guides-and-tips/lithium-ion-battery-guidance/
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That is not a standard, that is just ridiculous nonsense from an insurer who does not have a clue about LFP. If you wish to follow this advice you will not be able to comply with a LFP installation.

https://www.havenkj.com/guides-and-tips/lithium-ion-battery-guidance/
CT846 said:
ISO 23625:2025 (para 7), although I haven't been able to find a full online excerpt of this paragraph.
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Still not a standard.

Any talk of gassing LFP in a correctly spec'd system is nonsense, as i said earlier, the cells are sealed, they do not vent.
 
PaulRainbow said:
That's for commercial vessels, not relevant to leisure boats.



That is not a standard, that is just ridiculous nonsense from an insurer who does not have a clue about LFP. If you wish to follow this advice you will not be able to comply with a LFP installation.

https://www.havenkj.com/guides-and-tips/lithium-ion-battery-guidance/


Still not a standard.

Any talk of gassing LFP in a correctly spec'd system is nonsense, as i said earlier, the cells are sealed, they do not vent.
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Yes, I appreciate that, however if it's the case of making minor adjustments at the design stage in order to avoid problems of insurance it's certainly worth considering, regardless of whether we think their reasons are nonsense. Two 50mm vent pipes should be achievable in my scenario.
 
CT846 said:
Yes, I appreciate that, however if it's the case of making minor adjustments at the design stage in order to avoid problems of insurance it's certainly worth considering, regardless of whether we think their reasons are nonsense. Two 50mm vent pipes should be achievable in my scenario.
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Which insurance company are you with that accepts DIY LFP installs ?
 
CT846 said:
I'm not at the moment, hence the "for but not with" approach & hope that things become more sensible in due course.
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OK, i was interested because at the moment insurance companies seem to fall into two camps, not interested in LFP or if they are, no DIY installs.

As for fitting a vent, i said in post #3 "No reason why you can't fit something simple, such as a pipe from the top of the battery compartment to the outside. Only needs to be a small pipe and certainly no need for fans."

2x 50mm vents for gassing is excessive, even for LA. LA batteries have vent holes in them, about 3mm. LFP are totally sealed, if they are creating gas you have a very badly designed system and something is seriously wrong. Such a system will certainly not comply with the requirements of an insurance company that's interested in an LFP installation.

However, feel free to fit whatever vents you want, it's your boat.
 
thinwater said:
ABYC E13 for LiFePO4.
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Which states "Because of the wide variations in terms of battery chemistries, construction, volatility, and responses to a thermal
runaway event, it is not possible to issue a generic prescription for battery compartment design and ventilation. It is
incumbent on the boat builder and battery installer to consult with the battery manufacturer and supplier to determine
an appropriate compartment design and venting mechanism, and appropriate fire containment and firefighting
mechanisms if these are considered necessary."
 
PaulRainbow said:
Which states "Because of the wide variations in terms of battery chemistries, construction, volatility, and responses to a thermal
runaway event, it is not possible to issue a generic prescription for battery compartment design and ventilation. It is
incumbent on the boat builder and battery installer to consult with the battery manufacturer and supplier to determine
an appropriate compartment design and venting mechanism, and appropriate fire containment and firefighting
mechanisms if these are considered necessary."
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Yeah, I kind of knew that.😈

It would be funny, but it's not, really.
 
I increased the ventilation of the fridge and freezer on a catamaran. I added ducting from the bow locker to the fridge and freezer compressors and then through the bilges to the engine bay, which is vented at the transom. I added large computer fans at the compressors. wired to run when the compressor's ran.

I was using the predominately natural flow of air from bow to stern (when you are at anchor the bow is always to windward) - and simply augmenting that flow with ducting and fans. Your yacht spends more time at anchor/on a swing mooring than sailing.

Space on a multihull is not an issue (unless you fill it with something heavy).

Your ducting and how you achieve a sensible airflow is based on the spaces you have available and how they interconnect (or can be made to interconnect - there is no one right answer. But 'use' the natural airflow.

My computers fans were quite big, 120mm square. I vented into the engine bay and then left natural flow in the engine bay to vent through the engine bay's vents (at the deck/hull interface). Cat engines tend to be in dedicated engine bays in each transom.

You need to plan carefully and have the appropriate hole saws.

As the fridge and freezer were in the same hull my ducting was starboard side only I could have split the ducting to each hull and added separate ducting for the batteries, in the other hull - but our batteries were in a well ventilated open space.

Jonathan
 
Neeves said:
I increased the ventilation of the fridge and freezer on a catamaran. I added ducting from the bow locker to the fridge and freezer compressors and then through the bilges to the engine bay, which is vented at the transom. I added large computer fans at the compressors. wired to run when the compressor's ran.

I was using the predominately natural flow of air from bow to stern (when you are at anchor the bow is always to windward) - and simply augmenting that flow with ducting and fans. Your yacht spends more time at anchor/on a swing mooring than sailing.

Space on a multihull is not an issue (unless you fill it with something heavy).

Your ducting and how you achieve a sensible airflow is based on the spaces you have available and how they interconnect (or can be made to interconnect - there is no one right answer. But 'use' the natural airflow.

My computers fans were quite big, 120mm square. I vented into the engine bay and then left natural flow in the engine bay to vent through the engine bay's vents (at the deck/hull interface). Cat engines tend to be in dedicated engine bays in each transom.

You need to plan carefully and have the appropriate hole saws.

As the fridge and freezer were in the same hull my ducting was starboard side only I could have split the ducting to each hull and added separate ducting for the batteries, in the other hull - but our batteries were in a well ventilated open space.

Jonathan
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Sure you're reading the right thread ?
 
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