I have viewed this youtube entry https://www.youtube.com/watch?v=kRB7Z66brO0
Its self explanatory but it seems we can use an AC breaker on DC (just double the rating)
I guess the thermal side of the breaker will operate first, from magnetic theory Im sure the laminated poles still produce a strong enough field to trip the breaker as well.
I would love to hear others opinions. I have a 60 amp AC breaker on the DC side of my inverter (only wanted to use it as a switch to isolate the DC.
Interesting....
Safe travels
oldtrack123 said
12:34 PM Aug 22, 2014
Hi Phil
Yes, Ac breakers & switchs can be used on DC but not necessarily ALL
Makers will usualy show the DC rating if they consider their's is suitable
It is based on both voltage & amps. but the trip current in both situations will be very similar
It is the arc rupturing abilty [which depends on design] that is the major consideration
There is no hard & fast formula for that
Which operates first will depend on the current
Thermal trip covers normal overloads but always has a time delay
The magnetic trip is fast acting ,more for quick disconnect of sudden excess currents ,such as a short circuits
All Cbs also have a MAX current interupt rating, one they can handle without damage to themselves .
The current that could occur is determined by :
The max short circuit current available fron the source
The actual circuit impedance
PeterQ
-- Edited by oldtrack123 on Friday 22nd of August 2014 12:42:24 PM
Peter_n_Margaret said
04:26 PM Aug 22, 2014
Clipsal rate theirs at 48V DC. Note however they that the time to trip will be Root2 times as long (about 1.4X).
That is an increase in trip TIME, not an increase in RATING as per the OP.
I used 240V DC circuit breakers in the OKA DC wiring, but I avoid using them as switches to break flowing current in order to reduce the frequency of arcing. I have yet to experience a failure in 10 years of use.
Cheers, Peter
-- Edited by Peter_n_Margaret on Friday 22nd of August 2014 04:28:22 PM
oldtrack123 said
06:31 PM Aug 22, 2014
Peter_n_Margaret wrote:
Clipsal rate theirs at 48V DC. Note however they that the time to trip will be Root2 times as long (about 1.4X).
That is an increase in trip TIME, not an increase in RATING as per the OP.
Cheers, Peter
-- Edited by Peter_n_Margaret on Friday 22nd of August 2014 04:28:22 PM
HI Peter
Perhaps you have misunderstood some data as the thermal magnetic trip units fitted to a.c. circuit-breakers are also suitable to be used with direct current.
The thermal protection does not change with reference to its tripping characteristic as the bimetal strips of the trip units are influenced by the heating caused by the current flow, it does not matter whether AC or DC .
I think you may be confusing AC peak Current with RMS values
The peak curent is 1.4times the RMS but when we say XX amps with AC we are referring to the RMS value.
IxIx R= P[Watts] is the same in each case each case
However the MAGNETIC trip function will change under short circuit conditions, due to ferromagnetics involved with AC
Generally the reaction trip time will be faster with DC than AC.
The big reason for derating with DC is ARC suppression.
PeterQ
Peter_n_Margaret said
09:48 PM Aug 22, 2014
The root2 X trip time was Clipsal's figure, not mine, unless I misread it???
Will see if I have a copy.....
Hmmmmm... I'd be a bit cautious with the expectation that all MCBs will
operate in a similar manner on DC as they do on AC.
Certainly in regard to the thermal tripping the DC will equal the RMS and
all should be good but I'm not so sure about the magnetic aspect.
Page 7 of the above PDF shows the MCB design and the magnetic
tripping is performed by a solenoid the coil of which, I assume, is designed
with 240V AC in mind. Additionally the "Specifications" section of:
specifies the "Voltage type" as "AC" and makes no mention of DC.
Given that the only purpose in fitting a MCB is to be as certain as
possible that it will *work* then I would seek e-mail confirmation from
the manufacturers for each model which you intend to use on DC.
MH
KFT said
09:24 AM Aug 23, 2014
Think I would be looking to NHP products to be sure to get something eminently suited to the task.
frank
Phil C said
10:22 AM Aug 23, 2014
Thanks folks for a lively discussion, I have had a look at some old text books and agree that the slower thermal aspect of the breaker should open the circuit. The magnetic however may not be as efficient due to not enough flux being generated (Flux = I x N) and at 12V probably not enough to stick to a fridge. Then again under a short circuit who knows? However as I have stated I only wanted to isolate the DC and if its a safety measure as well I get a bonus.
Cheers and safe travels
oldtrack123 said
01:07 PM Aug 23, 2014
Mike Harding wrote:
Hmmmmm... I'd be a bit cautious with the expectation that all MCBs will operate in a similar manner on DC as they do on AC.
Certainly in regard to the thermal tripping the DC will equal the RMS and all should be good but I'm not so sure about the magnetic aspect.
Page 7 of the above PDF shows the MCB design and the magnetic tripping is performed by a solenoid the coil of which, I assume, is designed with 240V AC in mind. Additionally the "Specifications" section of:
specifies the "Voltage type" as "AC" and makes no mention of DC.
Given that the only purpose in fitting a MCB is to be as certain as possible that it will *work* then I would seek e-mail confirmation from the manufacturers for each model which you intend to use on DC.
MH
HI Mike
Your point is valid with regard to the MAGNETIC trip, if used on a different voltage to the designed voltage
One designed for 240V would be pretty well useles on 12V, either AC or DC
It will trip under short circuit conditions but only due to the THERMAL trip
To other readers
DC circuit breakers NEED better ARC quenching than AC breakers.[for the same voltages ]
That is the primary reason why ,when used on DC, the voltage rating is so LOW compared to the A C designed rating
-- Edited by oldtrack123 on Saturday 23rd of August 2014 01:07:49 PM
03_troopy said
11:55 PM Aug 23, 2014
Without wanting to derail the original topic too far, can anyone tell me why many DC thermal circuit breakers have "Batt" and "Aux" labels on their terminals. Given that they operate by heat build up from excessive current, distorting a metal (stainless?) plate which has been punched to give it a dish shape (yes i pulled a few apart ;) ), why does it matter which way the current flows? Or is it maybe that they are marked to facilitate circuit tracing once they are installed?
Mike Harding said
09:33 AM Aug 24, 2014
In the case of there being only a thermal tripping mechanism then I
can see no reason why direction of current flow would matter - heat
is heat.
However many (most?) DC MCBs are combined magnetic and thermal:
and in these cases it is essential that current flow is in the
specified direction in order that the magnetic fields have the
required polarity.
It may simply be that cheap MCBs are produced which don't include the
magnetic aspect but use the same plastic moulding? Or, maybe, the
manufacturers tired of people asking about the polarity so specified
one anyway? :)
MH
oldtrack123 said
11:07 AM Aug 24, 2014
03_troopy wrote:
Without wanting to derail the original topic too far, can anyone tell me why many DC thermal circuit breakers have "Batt" and "Aux" labels on their terminals. Given that they operate by heat build up from excessive current, distorting a metal (stainless?) plate which has been punched to give it a dish shape (yes i pulled a few apart ;) ), why does it matter which way the current flows? Or is it maybe that they are marked to facilitate circuit tracing once they are installed?
HI Troopy
They are polarised so the magnetic arc blowout system pushes the arc in the right direction to break it.
That can be very important if they are to break the arc before it does damage to the breaker itself
Qualty breakers designed for DC operation usualy do have a magnetic arc blow out
PeterQ
-- Edited by oldtrack123 on Sunday 24th of August 2014 11:11:12 AM
03_troopy said
03:18 PM Aug 24, 2014
Sorry Peter, I should have been more specific. I meant the common automotive types like these.
I have not pulled either type apart , so cannot say if either do gave a small permanent magnet to assist arc blow out.
I doubt the small elcheapo has any form just relies on luck Or the larger copper as a a heat sink
The better one could easily have a small permanent magnet or even a basic deionizing chamber [ series of ferrous metal plate which become magnetised by the current & breaks the arc up into small sections.
An other option used by some is a multi Arc gap, ie two or more sets of contacts in series
But without opening them I realy cannot say for certain.
PeterQ
-- Edited by oldtrack123 on Thursday 28th of August 2014 10:17:05 PM
03_troopy said
03:29 AM Aug 30, 2014
oldtrack123 wrote:
03_troopy wrote:
Still no takers for this query?
HI
I have not pulled either type apart , so cannot say if either do gave a small permanent magnet to assist arc blow out.
I doubt the small elcheapo has any form just relies on luck Or the larger copper as a a heat sink
The better one could easily have a small permanent magnet or even a basic deionizing chamber [ series of ferrous metal plate which become magnetised by the current & breaks the arc up into small sections.
An other option used by some is a multi Arc gap, ie two or more sets of contacts in series
But without opening them I realy cannot say for certain.
PeterQ
Peter, neither of the 2 shown have any magnets and have only the metal plate that acts as the breaker. The query came up when connecting the manually re-settable one in a dual battery setup, where the limited current would be from the auxiliary battery back to the main battery when using the override function of the smart isolator. One bloke wanted to connect the main battery to the BAT terminal and the AUX (load) terminal to the smart isolator. I was thinking that because the current would be in the direction of Auxiliary battery to main battery (flat main battery) maybe it should be connected the opposite way round. But no-one can give a definitive answer on it it so far (with a reason why). To be honest, I really can't see any reason why it wouldn't work both directions.
-- Edited by oldtrack123 on Thursday 28th of August 2014 10:17:05 PM
oldtrack123 said
07:21 AM Aug 30, 2014
HI Troopy
12vDC cannot draw a very long arc, so as long as the break gap is long enough & the break is fast enough,a sustained arc is unlikely
But that can change when the voltage gets above 24VDC or the load is highly inductive[ motors or coils with ferrous cores
PeterQ
03_troopy said
07:18 PM Aug 31, 2014
oldtrack123 wrote:
HI Troopy
12vDC cannot draw a very long arc, so as long as the break gap is long enough & the break is fast enough,a sustained arc is unlikely
But that can change when the voltage gets above 24VDC or the load is highly inductive[ motors or coils with ferrous cores
PeterQ
Yes peter that is also true. thanks. ;)
bobsa said
01:44 PM Dec 16, 2017
here is a link to NHP breaker at all good electrical suppliers
single pole up to 48volt dc and 2 pole 110 dc
I am not an Auto or normal Electrician I can only go by what the description says
I have recently purchased 12 VDC 30 Amp circuit breakers From the description I will assume that there is a type of 30 amp fuse inside
I had normal inline blade fuses, but these circuit breakers will give me the ability to isolate, the following circuits, easier
Roof solar panel, positive wire before the DC/DC charger 12 volt upright fridge, positive wire, at the batteries 12 volt merit (ciggy type) socket, positive wire, (for my chest fridge/freezer if I need to use it), at the batteries end
The inline blade fuses would have done the same isolation, at a much cheaper price The circuit breakers give me ease of isolation/re-powering
oldtrack123 said
05:44 PM Dec 16, 2017
Tony Bev wrote:
I am not an Auto or normal Electrician I can only go by what the description says
I have recently purchased 12 VDC 30 Amp circuit breakers From the description I will assume that there is a type of 30 amp fuse inside
I had normal inline blade fuses, but these circuit breakers will give me the ability to isolate, the following circuits, easier
Roof solar panel, positive wire before the DC/DC charger 12 volt upright fridge, positive wire, at the batteries 12 volt merit (ciggy type) socket, positive wire, (for my chest fridge/freezer if I need to use it), at the batteries end
The inline blade fuses would have done the same isolation, at a much cheaper price The circuit breakers give me ease of isolation/re-powering
Elcheopo 12V thermal circuit are just a thermal switch .often using just the moving contact arm itself as the bimetal thermal trip
Auto rest types simply close the contacts with arm cools down & something that should not be normally used except in situations as vehicle headlights
Manual reset require manual resetting to latch in . Such should be used for most applications as you will be aware they have tripped & investigate why
Polarity again could depend on design , but with most the Pos [usually the fixed] contact, in breaker will be larger or have a heat sink to absorb the greater heat generated by arc @ the Pos contact face
Better quality Dc breakers especial for voltage above 24V will usually have some form of magnetic blow out[permanent magnet or coil]
Such will usually require mounting vertically in the direction indicated to assist the arc blowing into the extinguisher area
]
Tony Bev said
06:08 PM Dec 16, 2017
Thanks for that explanation, oldtrack123, it is appreciated
T1 Terry said
05:58 PM Dec 21, 2017
If you want a reliable DC circuit breaker for solar you can't go past the No Ark range. Those lever type DC circuit breakers have a nasty habit of getting hot and tripping well before they have reached their rated capacity due to poor contacts creating high resistance. There other specialty is welding the contacts together and never tripping.
Hi all
This will spark some discussion Im sure.
I have viewed this youtube entry https://www.youtube.com/watch?v=kRB7Z66brO0
Its self explanatory but it seems we can use an AC breaker on DC (just double the rating)
I guess the thermal side of the breaker will operate first, from magnetic theory Im sure the laminated poles still produce a strong enough field to trip the breaker as well.
I would love to hear others opinions. I have a 60 amp AC breaker on the DC side of my inverter (only wanted to use it as a switch to isolate the DC.
Interesting....
Safe travels
Hi Phil
Yes, Ac breakers & switchs can be used on DC but not necessarily ALL
Makers will usualy show the DC rating if they consider their's is suitable
It is based on both voltage & amps. but the trip current in both situations will be very similar
It is the arc rupturing abilty [which depends on design] that is the major consideration
There is no hard & fast formula for that
Which operates first will depend on the current
Thermal trip covers normal overloads but always has a time delay
The magnetic trip is fast acting ,more for quick disconnect of sudden excess currents ,such as a short circuits
All Cbs also have a MAX current interupt rating, one they can handle without damage to themselves .
The current that could occur is determined by :
The max short circuit current available fron the source
The actual circuit impedance
PeterQ
-- Edited by oldtrack123 on Friday 22nd of August 2014 12:42:24 PM
Clipsal rate theirs at 48V DC.
Note however they that the time to trip will be Root2 times as long (about 1.4X).
That is an increase in trip TIME, not an increase in RATING as per the OP.
I used 240V DC circuit breakers in the OKA DC wiring, but I avoid using them as switches to break flowing current in order to reduce the frequency of arcing.
I have yet to experience a failure in 10 years of use.
Cheers,
Peter
-- Edited by Peter_n_Margaret on Friday 22nd of August 2014 04:28:22 PM
HI Peter
Perhaps you have misunderstood some data as the thermal magnetic trip units fitted to a.c. circuit-breakers are also suitable to be used with direct current.
The thermal protection does not change with reference to its tripping characteristic as the bimetal strips of the trip units are influenced by the heating caused by the current flow, it does not matter whether AC or DC .
I think you may be confusing AC peak Current with RMS values
The peak curent is 1.4times the RMS but when we say XX amps with AC we are referring to the RMS value.
IxIx R= P[Watts] is the same in each case each case
However the MAGNETIC trip function will change under short circuit conditions, due to ferromagnetics involved with AC
Generally the reaction trip time will be faster with DC than AC.
The big reason for derating with DC is ARC suppression.
PeterQ
Will see if I have a copy.....
Cheers,
Peter
Quotes the 48VDC, but does not describe any other DC operating characteristics.
Cheers,
Peter
operate in a similar manner on DC as they do on AC.
Certainly in regard to the thermal tripping the DC will equal the RMS and
all should be good but I'm not so sure about the magnetic aspect.
Page 7 of the above PDF shows the MCB design and the magnetic
tripping is performed by a solenoid the coil of which, I assume, is designed
with 240V AC in mind. Additionally the "Specifications" section of:
www.clipsal.com/Trade/Products/ProductDetail
specifies the "Voltage type" as "AC" and makes no mention of DC.
Given that the only purpose in fitting a MCB is to be as certain as
possible that it will *work* then I would seek e-mail confirmation from
the manufacturers for each model which you intend to use on DC.
MH
frank
Cheers and safe travels
HI Mike
Your point is valid with regard to the MAGNETIC trip, if used on a different voltage to the designed voltage
One designed for 240V would be pretty well useles on 12V, either AC or DC
It will trip under short circuit conditions but only due to the THERMAL trip
To other readers
DC circuit breakers NEED better ARC quenching than AC breakers.[for the same voltages ]
That is the primary reason why ,when used on DC, the voltage rating is so LOW compared to the A C designed rating
-- Edited by oldtrack123 on Saturday 23rd of August 2014 01:07:49 PM
can see no reason why direction of current flow would matter - heat
is heat.
However many (most?) DC MCBs are combined magnetic and thermal:
bit.ly/1AIJXIe
and in these cases it is essential that current flow is in the
specified direction in order that the magnetic fields have the
required polarity.
It may simply be that cheap MCBs are produced which don't include the
magnetic aspect but use the same plastic moulding? Or, maybe, the
manufacturers tired of people asking about the polarity so specified
one anyway? :)
MH
HI Troopy
They are polarised so the magnetic arc blowout system pushes the arc in the right direction to break it.
That can be very important if they are to break the arc before it does damage to the breaker itself
Qualty breakers designed for DC operation usualy do have a magnetic arc blow out
PeterQ
-- Edited by oldtrack123 on Sunday 24th of August 2014 11:11:12 AM
Sorry Peter, I should have been more specific. I meant the common automotive types like these.
HI
I have not pulled either type apart , so cannot say if either do gave a small permanent magnet to assist arc blow out.
I doubt the small elcheapo has any form just relies on luck Or the larger copper as a a heat sink
The better one could easily have a small permanent magnet or even a basic deionizing chamber [ series of ferrous metal plate which become magnetised by the current & breaks the arc up into small sections.
An other option used by some is a multi Arc gap, ie two or more sets of contacts in series
But without opening them I realy cannot say for certain.
PeterQ
-- Edited by oldtrack123 on Thursday 28th of August 2014 10:17:05 PM
HI Troopy
12vDC cannot draw a very long arc, so as long as the break gap is long enough & the break is fast enough,a sustained arc is unlikely
But that can change when the voltage gets above 24VDC or the load is highly inductive[ motors or coils with ferrous cores
PeterQ
Yes peter that is also true. thanks. ;)
single pole up to 48volt dc and 2 pole 110 dc
www.nhp.com.au/files/editor_upload/File/Brochures/Business-Specific/easy-selection-guides/NHPNTUMCBAUSESG.pdf
I am not an Auto or normal Electrician
I can only go by what the description says
I have recently purchased 12 VDC 30 Amp circuit breakers
From the description I will assume that there is a type of 30 amp fuse inside
I had normal inline blade fuses, but these circuit breakers will give me the ability to isolate, the following circuits, easier
Roof solar panel, positive wire before the DC/DC charger
12 volt upright fridge, positive wire, at the batteries
12 volt merit (ciggy type) socket, positive wire, (for my chest fridge/freezer if I need to use it), at the batteries end
The inline blade fuses would have done the same isolation, at a much cheaper price
The circuit breakers give me ease of isolation/re-powering
Elcheopo 12V thermal circuit are just a thermal switch .often using just the moving contact arm itself as the bimetal thermal trip
Auto rest types simply close the contacts with arm cools down & something that should not be normally used except in situations as vehicle headlights
Manual reset require manual resetting to latch in . Such should be used for most applications as you will be aware they have tripped & investigate why
Polarity again could depend on design , but with most the Pos [usually the fixed] contact, in breaker will be larger or have a heat sink to absorb the greater heat generated by arc @ the Pos contact face
Better quality Dc breakers especial for voltage above 24V will usually have some form of magnetic blow out[permanent magnet or coil]
Such will usually require mounting vertically in the direction indicated to assist the arc blowing into the extinguisher area
]
T1 Terry