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First passenger service journey for LUL 09 stock
Peter Masson wrote:
Perhaps the Victoria Line needs to be extended into the open air, at least so the piston effect of trains can add ventilation into the tunnels, and ideally so that the next generation (49 stock) can have aircon that takes heat out of the system and dumps it in the open air. Take over Chingford from National Rail? Quadruple Northumberland Park to Cheshunt, with a extended Victoria Line running the local service? A few years ago, a significant proportion of trains went to Northumberland Park anyway - is that still true? I always wondered why - maybe it is to cool the line. |
First passenger service journey for LUL 09 stock
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First passenger service journey for LUL 09 stock
On Jul 24, 10:15*pm, Andy wrote:
"In order to make use of the additional throughput capability of the new signalling, the 2009 Stock has a higher performance than the current stock. The existing 1967 Tube Stock draws about 2,700 amps maximum, while the 2009 Tube Stock will draw 3,500 and is capable of drawing up to 4,500 amps." This looks like well under double the peak current draw. You've missed the whole point. Its not the PEAK current thats the issue. This has been explained in uk.railway several times before - and it seems to be a fundamental issue that headline writers can't get right. With DC motors the PEAK current is very large but drops off very quickly and gets ever smaller as the train accelerates. With AC motors it is a constant current, its not as high as the DC peak, but it never tapers off, it is flat, across the whole train speed. But at all times it is considerably higher than the DC motor train at speed. 3500 A constant is much much more heating effect than 2700 A that drops off rapidly. Thats how AC asynchronous and DC commutator motors work, full stop. It all amounts to much much more I^2*R heat to get rid of when trains are motoring than from a DC motor train. -- Nick |
First passenger service journey for LUL 09 stock
On Fri, 24 Jul 2009 14:57:26 -0700 (PDT), D7666
wrote: With AC motors it is a constant current, its not as high as the DC peak, but it never tapers off, it is flat, across the whole train speed. But at all times it is considerably higher than the DC motor train at speed. Although there is also the issue of DC versus RMS current. When they developed the cross-channel cables that transfer electricity between ..uk and .fr they made a schoolboy error and forgot they were transferring DC, with results that as far as I can tell only electrical engineers find actually amusing. Guy -- http://www.chapmancentral.co.uk |
First passenger service journey for LUL 09 stock
On Jul 24, 11:00*pm, "Just zis Guy, you know?"
wrote: With AC motors it is a constant current, its not as high as the DC peak, but it never tapers off, it is flat, across the whole train speed. But at all times it is considerably higher than the DC motor train at speed. Although there is also the issue of DC versus RMS current. * Yes ... that can be a source of confusion ..... but we are talking here of the current draw on the DC traction third rail in both cases i.e. for both the DC motor [1967] and AC motor [2009] trains. RMS does not come into this debate in the discussion as it is a tthe moment. -- Nick |
First passenger service journey for LUL 09 stock
On Jul 24, 10:57*pm, D7666 wrote:
On Jul 24, 10:15*pm, Andy wrote: "In order to make use of the additional throughput capability of the new signalling, the 2009 Stock has a higher performance than the current stock. The existing 1967 Tube Stock draws about 2,700 amps maximum, while the 2009 Tube Stock will draw 3,500 and is capable of drawing up to 4,500 amps." This looks like well under double the peak current draw. You've missed the whole point. No I've not, you've missed mine. You were the one mentioning 3 times the current draw, when the numbers say less than twice the current draw. Its not the PEAK current thats the issue. This has been explained in uk.railway several times before - and it seems to be a fundamental issue that headline writers can't get right. With DC motors the PEAK current is very large but drops off very quickly and gets ever smaller as the train accelerates. With AC motors it is a constant current, its not as high as the DC peak, but it never tapers off, it is flat, across the whole train speed. But at all times it is considerably higher than the DC motor train at speed. 3500 A constant is much much more heating effect than 2700 A that drops off rapidly. Thats how AC asynchronous and DC commutator motors work, full stop. But only constant current whilst the train is actually motoring, it would be a very strange train which was drawing 3500A when stationary or decelerating. I understand the workings of the different sorts of motors, I was just trying to point out that your estimates seemed to be in error. It all amounts to much much more I^2*R heat to get rid of when trains are motoring than from a DC motor train. Yes and as the current is being drawn much more consistently, a large proportion of the regained energy from the regeneration will be going into powering other trains, rather than heating braking resistors as it does at present. The current 1967 stock braking system will be dumping a lot of heat straight into the stations, with 2009 stock regeneration, a lot of that energy will instead be used. |
First passenger service journey for LUL 09 stock
On Jul 24, 11:44*pm, Andy wrote:
No I've not, you've missed mine. You were the one mentioning 3 times the current draw, when the numbers say less than twice the current draw. If the cont power rating of 2009 stock is 1800 kW and the cont power rating of 1967 sock is 848 kW and they are both drawing that power at 630 V DC then that alone, comparing one 8-car train with another draws 2.12 times as much current from traction DC. Or are you going to tell me now that the Laws of Ohm, Kirchoff, Newton, and anyone else with an established theorem of electricity or mechanics is wrong ? If not then read on. Making no changes to the service, across the whole line, its must then follow as 2.12 times as much current. But there are 37 trains (I think) in the present timetable. That [I think] goes to 41 with full 2009 stock service post VUl. That actually up ~10%. So its 2.33 times the current. Thats the base load, on cont ratings, before we even look at one hour or short term overloads. Those new trains in the full timetable will work harder - instead of [?] 28 TPH they work 33[??] TPH - so they will be pushed harder with the new ATO than the old ATO does with 1967 stock. (You only have to go on the Central Line to see how a more modern ATO system pushes trains - and that is a system that is very like the one going in on VUL, just a refined version of it.) But only constant current whilst the train is actually motoring, In the same way the 1967 stock don't draw current all the time only when motoring. The *relative* load proportion of 1967 and 2009 stock at continuous rating thus remains at around 2.33 times. So far I've only looked at traction motor load. Add air con etc - anyone want to esitimate or state what the aircon load of 2009 stock is ? It is around 1 MW on a Eurostar. I'm not seriously suggesting 2009 stock is the same load, but write it as its the only one I know off the top of my head to show how siginificant these loads are. That traction load goes on top the 2.33 ... in round figures with auxiliary load we approach 3x. -- Nick |
First passenger service journey for LUL 09 stock
D7666 wrote:
If the cont power rating of 2009 stock is 1800 kW and the cont power rating of 1967 sock is 848 kW and they are both drawing that power at 630 V DC then that alone, comparing one 8-car train with another draws 2.12 times as much current from traction DC. Or are you going to tell me now that the Laws of Ohm, Kirchoff, Newton, and anyone else with an established theorem of electricity or mechanics is wrong ? If not then read on. Making no changes to the service, across the whole line, its must then follow as 2.12 times as much current. But there are 37 trains (I think) in the present timetable. That [I think] goes to 41 with full 2009 stock service post VUl. That actually up ~10%. So its 2.33 times the current. Thats the base load, on cont ratings, before we even look at one hour or short term overloads. Those new trains in the full timetable will work harder - instead of [?] 28 TPH they work 33[??] TPH - so they will be pushed harder with the new ATO than the old ATO does with 1967 stock. (You only have to go on the Central Line to see how a more modern ATO system pushes trains - and that is a system that is very like the one going in on VUL, just a refined version of it.) But only constant current whilst the train is actually motoring, In the same way the 1967 stock don't draw current all the time only when motoring. The *relative* load proportion of 1967 and 2009 stock at continuous rating thus remains at around 2.33 times. So far I've only looked at traction motor load. Add air con etc - anyone want to esitimate or state what the aircon load of 2009 stock is ? It is around 1 MW on a Eurostar. I'm not seriously suggesting 2009 stock is the same load, but write it as its the only one I know off the top of my head to show how siginificant these loads are. That traction load goes on top the 2.33 ... in round figures with auxiliary load we approach 3x. I suspect the aircon would only be on when the trains were regeneratively braking, or when a significant chunk of the fleet was stationary in the tunnel and drawing no motor power - possibly also when the trains were coasting, but I see no need to have the aircon working when the trains are accelerating. |
First passenger service journey for LUL 09 stock
On Jul 25, 12:14*am, D7666 wrote:
On Jul 24, 11:44*pm, Andy wrote: No I've not, you've missed mine. You were the one mentioning 3 times the current draw, when the numbers say less than twice the current draw. If the cont power rating of 2009 stock is 1800 kW and the cont power rating of 1967 sock is 848 kW and they are both drawing that power at 630 V DC then that alone, comparing one 8-car train with another draws 2.12 times as much current from traction DC. Or are you going to tell me now that the Laws of Ohm, Kirchoff, Newton, and anyone else with an established theorem of electricity or mechanics is wrong ? Stop being so condescending. If not then read on. Making no changes to the service, across the whole line, its must then follow as *2.12 times as much current. But there are 37 trains (I think) in the present timetable. That [I think] goes to 41 with full 2009 stock service post VUl. That actually up ~10%. So its 2.33 times the current. Thats the base load, on cont ratings, before we even look at one hour or short term overloads. Those new trains in the full timetable will work harder - instead of [?] 28 TPH they work 33[??] TPH - so they will be pushed harder with the new ATO than the old ATO does with 1967 stock. (You only have to go on the Central Line to see how a more modern ATO system pushes trains - and that is *a system that is very like the one going in on VUL, just a refined version of it.) But only constant current whilst the train is actually motoring, In the same way the 1967 stock don't draw current all the time only when motoring. The *relative* load proportion of 1967 and 2009 stock at continuous rating thus remains at around 2.33 times. So far I've only looked at traction motor load. Add air con etc - anyone want to esitimate or state what the aircon load of 2009 stock is ? What Aircon? 2009 stock isn't fitted although the S Stock will be. The original point of the discussion was why it hasn't got the aircon. It is around 1 MW on a Eurostar. I'm not seriously suggesting 2009 stock is the same load, but write it as its the only one I know off the top of my head to show how siginificant these loads are. That traction load goes on top the 2.33 ... in round figures with auxiliary load we approach 3x. Ok, another question, since you seem to be disregarding my attempts to point you towards the energy saving of the regeneration. Why are you assuming that R is constant when the modern AC motors and their control systems are considerably more efficient than the DC systems being replaced. A more powerful modern traction system doesn't necessarily generate twice as much heat just because it has twice as much power at its disposal. |
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