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On Thu, 21 Apr 2005 09:22:27 -0700, Keith Hughes
wrote: 2. If the 12V device (VHF IIRC) is a significant load, you can always build a simple voltage divider (the VHF should be input voltage tolerant enough to handle the voltage sag during transmission) and run from both batteries. The overall battery draw will, of course, be somewhat larger since you'll dissipate heat in the dropping resistor. If multiple devices are used, however, this approach quickly becomes problematic. Keith A series voltage dropping resistor may work for some devices where the current draw is constant, but it _will not_ work for a VHF radio. The radio will only draw a few hundred mA on receive when squelched, somewhat more when actually receiving, and a few amps when transmitting - there is no way a simple resistor can keep the supply voltage to the radio within acceptable bounds with that current variation. -- Peter Bennett VE7CEI email: peterbb4 (at) interchange.ubc.ca GPS and NMEA info and programs: http://vancouver-webpages.com/peter/index.html Newsgroup new user info: http://vancouver-webpages.com/nnq |
Peter Bennett wrote:
On Thu, 21 Apr 2005 09:22:27 -0700, Keith Hughes wrote: 2. If the 12V device (VHF IIRC) is a significant load, you can always build a simple voltage divider (the VHF should be input voltage tolerant enough to handle the voltage sag during transmission) and run from both batteries. The overall battery draw will, of course, be somewhat larger since you'll dissipate heat in the dropping resistor. If multiple devices are used, however, this approach quickly becomes problematic. A series voltage dropping resistor may work for some devices where the current draw is constant, but it _will not_ work for a VHF radio. The radio will only draw a few hundred mA on receive when squelched, somewhat more when actually receiving, and a few amps when transmitting - there is no way a simple resistor can keep the supply voltage to the radio within acceptable bounds with that current variation. Keith mentioned a voltage divider. That's not a simple resistor. Even a voltage divider is unlikely to be very satisfactory either, since in order to keep the voltage within acceptable range for the VHF, the resistance values will probably need to be so low, you'd be dissipating as much power in the divider all the time as the VHF on full-power transmit. One possibility might be to use a zener diode in place of a simple series resistor. At the end of the day, having different-voltage devices aboard is always going to be a pig's breakfast unless you have proper fully independent systems, with two alternators, one for charging the 24V batteries, and one for the 12V ones, or a charge controller capable of charging a 12V battery from the 24V alternator. |
On Thu, 21 Apr 2005 21:46:09 GMT, Ronald Raygun wrote: Peter Bennett wrote: On Thu, 21 Apr 2005 09:22:27 -0700, Keith Hughes wrote: 2. If the 12V device (VHF IIRC) is a significant load, you can always build a simple voltage divider (the VHF should be input voltage tolerant enough to handle the voltage sag during transmission) and run from both batteries. The overall battery draw will, of course, be somewhat larger since you'll dissipate heat in the dropping resistor. If multiple devices are used, however, this approach quickly becomes problematic. A series voltage dropping resistor may work for some devices where the current draw is constant, but it _will not_ work for a VHF radio. The radio will only draw a few hundred mA on receive when squelched, somewhat more when actually receiving, and a few amps when transmitting - there is no way a simple resistor can keep the supply voltage to the radio within acceptable bounds with that current variation. Keith mentioned a voltage divider. That's not a simple resistor. Even a voltage divider is unlikely to be very satisfactory either, since in order to keep the voltage within acceptable range for the VHF, the resistance values will probably need to be so low, you'd be dissipating as much power in the divider all the time as the VHF on full-power transmit. One possibility might be to use a zener diode in place of a simple series resistor. At the end of the day, having different-voltage devices aboard is always going to be a pig's breakfast unless you have proper fully independent systems, with two alternators, one for charging the 24V batteries, and one for the 12V ones, or a charge controller capable of charging a 12V battery from the 24V alternator. Come on guys, get back to the proper way to do the job and the simplest. The 24 to 12 volt converter. Resistor dividers will draw more power than the radio. A zener has to be very large for the job at hand. Again it will consume as much power as the radio. regards Gary |
On Thu, 21 Apr 2005 02:23:40 GMT, "James Hahn"
wrote: "Meindert Sprang" wrote in message ... snip The charge of a battery is the product of current x time. True, but irrelevant Both batteries are in series and one load is connected to the set, operating at 24V. Another load is connected across only one battery, operating at 12V. So it is evident that one battery is discharged more than the other. Yes, but you don't need the load - batteries will always have different charge levels in individual cells, whether in the same case or not. It's easy to measure the differences. I start to charge the set in series, so the current through both batteries is exactly the same. No. You are failing to understand that the charging process is a chemical reaction that converts energy into a differnt form.. The current flowing at the positive and negative terminal of the whole string of cells is the same, obviously, but the current that flows 'through' any cell is a complex result of the conversion processes occurring inside the cells of which it is a string. Each cell can be considered an energy sink. The amount of energy imparted to each cell will differ, either within a single battery or within a series of batteries. This is not a problem for the charging process. The current flowing across any cell, or any group of cells, is most definately not equal, and there is no reason it should be. Since one battery is discharged more than the other and the current throug both is the same, one battery must be charged longer that the other. No. All cells are charged for as long as the charge is applied. It makes no sense to say that one is charged longer than the other. Perhaps you meant to say that some will continue to have the full potential applied when they are not accepting additional energy - this is normal in any charging process and causes no problem for the battery. It is, in fact, exactly what happens when any battery is fully charged and a maintaining charge is being applied. It is no different for the battery as a whole as it is for the individual cells. Exactly how am I going to achive that with the same current through both batteries? You do not achieve that, and you don't need to. One battery will reach the full state before the other but is still being charged with full current because the other battery hasn't reached the voltage that corresponds with full charge. One battery wil reach the full state before the other, like one cell will reach the full state before some others. It's not a problem. It is not being charged with full current because the 'load' that the system presents to the charging process is reduced by the reduced charging requirements of the cell (or cells) that have reached or are approaching full charge. The current that can be absorbed by a bank of cells depends on the charge state of the cells in the string, not the charge state of the most discharged cell. That's why I said before that the system 'monitors' the state of the string of cells, not individual cells. If the charge rate was controlled by the most discharged cell then modern lead acid batteries, with typical manufacturing differences, wouldn't last any time at all. Current is always equal at any point in a series circuit. All cells are in series therefore current is the same through each cell. What does change is the resistance of each cell as it charges. The more charge a cell accumulates the higher it's resistance becomes. That makes the current through it decrease. But as the current decreases through that cell so does it decrease by an equal amount through all the other cells. As resistance increases in a particular cell so does the voltage across it increase. Total current decreases as cells charge if charge voltage is held constant because cell resistance increases. Resistance can increase more in one cell than in another but total current will be still be equal in all cells. It comes down to good old ohms law. Applied voltage divided by the sum of the resistance of each cell equals total current. Regards Gary |
Gary Schafer wrote:
On Thu, 21 Apr 2005 21:46:09 GMT, Ronald Raygun wrote: Peter Bennett wrote: On Thu, 21 Apr 2005 09:22:27 -0700, Keith Hughes wrote: 2. If the 12V device (VHF IIRC) is a significant load, you can always build a simple voltage divider (the VHF should be input voltage tolerant enough to handle the voltage sag during transmission) and run from both batteries. The overall battery draw will, of course, be somewhat larger since you'll dissipate heat in the dropping resistor. If multiple devices are used, however, this approach quickly becomes problematic. A series voltage dropping resistor may work for some devices where the current draw is constant, but it _will not_ work for a VHF radio. The radio will only draw a few hundred mA on receive when squelched, somewhat more when actually receiving, and a few amps when transmitting - there is no way a simple resistor can keep the supply voltage to the radio within acceptable bounds with that current variation. I did not recall, for sure, what the device was. That's why I hedged. Whatever the device, you'd have to look at the full load/idle ratio and see if a voltage divider makes sense. In the OP's case, I'm not sure. Keith mentioned a voltage divider. That's not a simple resistor. Even a voltage divider is unlikely to be very satisfactory either, since in order to keep the voltage within acceptable range for the VHF, the resistance values will probably need to be so low, you'd be dissipating as much power in the divider all the time as the VHF on full-power transmit. One possibility might be to use a zener diode in place of a simple series resistor. At the end of the day, having different-voltage devices aboard is always going to be a pig's breakfast unless you have proper fully independent systems, with two alternators, one for charging the 24V batteries, and one for the 12V ones, or a charge controller capable of charging a 12V battery from the 24V alternator. True, but do-able. And relatively cheaply compared to off-the-shelf solutionsa. Come on guys, get back to the proper way to do the job and the simplest. The 24 to 12 volt converter. I would certainly agree. Shouldn't be too hard to find a 12VDC output, 12-12VDC regulated power supply. Resistor dividers will draw more power than the radio. A zener has to be very large for the job at hand. Again it will consume as much power as the radio. Hmmm...where have I hear that before??? :-) Keith |
On Thu, 21 Apr 2005 11:07:23 UTC, Ronald Raygun
wrote: : What exactly happens at the microscopic level may well be complex and : diverse, but the current passing through any surface you'd care to cut : through any cell will be the same. Is that strictly true? When a cell is charging, with electrochemical processes taking place at the plates, does the charging current still exist between them? It wouldn't in a capacitor, though I suppose the displacemet current would even up the score a bit there. Ian -- |
On Thu, 21 Apr 2005 22:33:12 UTC, Gary Schafer
wrote: : It comes down to good old ohms law. Applied voltage divided by the sum : of the resistance of each cell equals total current. Only if you define resistance that way. For non-linear circuit elements it's a pretty meaningless thing to say. Ian |
"Ian Johnston" wrote in message news:cCUlhtvFIYkV-pn2-1yXN8Ihw3NKL@localhost... On Thu, 21 Apr 2005 22:33:12 UTC, Gary Schafer wrote: : It comes down to good old ohms law. Applied voltage divided by the sum : of the resistance of each cell equals total current. Only if you define resistance that way. For non-linear circuit elements it's a pretty meaningless thing to say. Ian Absolutely. And if we dare mention in this thread that internal resistance of a battery is dI/dV (rather than I/V), then god knows what chaotic argument that will create amongst the cognoscenti who think that a battery is a big bucket full of electrons! |
"Pete Styles" wrote in message ... "Ian Johnston" wrote in message news:cCUlhtvFIYkV-pn2-1yXN8Ihw3NKL@localhost... On Thu, 21 Apr 2005 22:33:12 UTC, Gary Schafer wrote: : It comes down to good old ohms law. Applied voltage divided by the sum : of the resistance of each cell equals total current. Only if you define resistance that way. For non-linear circuit elements it's a pretty meaningless thing to say. Ian Absolutely. And if we dare mention in this thread that internal resistance of a battery is dI/dV (rather than I/V), then god knows what chaotic argument that will create amongst the cognoscenti who think that a battery is a big bucket full of electrons! WHOOPS - meant dV/dI and V/I, sorry! |
Ian Johnston wrote:
On Thu, 21 Apr 2005 11:07:23 UTC, Ronald Raygun wrote: : What exactly happens at the microscopic level may well be complex and : diverse, but the current passing through any surface you'd care to cut : through any cell will be the same. Is that strictly true? Yes, I very much believe so, and know of no reason why it should not be. When a cell is charging, with electrochemical processes taking place at the plates, does the charging current still exist between them? It wouldn't in a capacitor, though I suppose the displacemet current would even up the score a bit there. That's because in a capacitor the dielectric replaces the electrolyte, and the energy is stored in the form of an electric field created by the physical separation of "real" (electric) charge. In a battery no electric charge is stored at all (to speak of) and energy is stored by chemical changes to plates and electrolyte. Out of every two SO4-- ions in any drop of electrolyte, on average one travels to each plate, but all four corresponding H+ ions travel only to the PbO2 plate. As I tried to explain yesterday by considering the drops laid end to end in series, this means that for each two electrons travelling left to right on the outside, the charge balance in each drop of electrolyte is neutral (-2 out to the left, -2 out to the right, +4 out to the right) and at each inter-drop interface this means charge travels either -2 left or +2 right, plus self-balancing through traffic. Hence charge travels on the inside as well as on the outside. Where charge travels, that's current. |
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