dootdootdoot
Electrical
- Sep 11, 2006
- 12
From what I've gathered, even in the 1NZ-FXE engine, pumping losses reduce engine efficiency by a significant amount. For example, this is supposedly a model based on dyno data
and according to this the approximate power needed to move the Prius on level ground, at ~21.5m/s, with no wind, and ideal surfaces...
Well, anyhow, I figure the Prius needs ~10-15hp to move at that speed, ~1/7-1/5 of the engine's available power. Or, the corresponding amount of the engine's torque at the appropriate rpm... So, this seems to indicate that the engine efficiency at ~21.5mph is only ~20-25%, compared to ~36% peak efficiency. Now, as speed decreases, so does the force needed to overcome fluid friction which is good for vehicle efficiency, but the load drops, which is bad for engine efficiency. To take advantage of the apparent ability of the Prius to coast with the engine off during some low speed range (~15-20m/s, or whatever it is), some drivers are accelerating (loading the engine and I would think increasing efficiency) up to a certain speed, and coasting back down to another speed. With the result being much better efficiency (i.e. mileage) versus cruising at the same average speed.
Now my question is, aside from "is the above supposition correct?", why don't manufacturers just put bigger plug-in battery "buffers" in, coupled with smaller gasoline generators and electric motors? Peak efficiency could very good, acceleration brisk provided the electric motor was suitable, fuel supply diversified, and fuel costs greatly reduced.
My answer to this (my own question is that gas has always been so cheap that the additional cost of the system wouldn't be worthwhile over the lifetime of the vehicle. Now that gasoline prices have risen, the use of more efficient/more costly parallel hybrids is cost effective. And if gas prices rise again, the use of serial hybrids with even greater efficiencies available to the average driver would be practical.
Also, other factors such as patents (supposedly toyota gets all of their batteries from cobasys, and as such must pay a relatively high premium), demand destruction (don't want to cut consumption too much or price drops), manufacturer supply chains (3-7 years turn-around, maybe more?), potential reliability issues, both from unproven technology (more expensive for the manufacturer), and modular vehicle design (possibly cheaper for the consumer in the long run) could significantly influence the makeup of a modern vehicle.
So... yeah, talk about OT. Anyway, does anyone have any opinions about where the current auto is headed?
and according to this the approximate power needed to move the Prius on level ground, at ~21.5m/s, with no wind, and ideal surfaces...
Well, anyhow, I figure the Prius needs ~10-15hp to move at that speed, ~1/7-1/5 of the engine's available power. Or, the corresponding amount of the engine's torque at the appropriate rpm... So, this seems to indicate that the engine efficiency at ~21.5mph is only ~20-25%, compared to ~36% peak efficiency. Now, as speed decreases, so does the force needed to overcome fluid friction which is good for vehicle efficiency, but the load drops, which is bad for engine efficiency. To take advantage of the apparent ability of the Prius to coast with the engine off during some low speed range (~15-20m/s, or whatever it is), some drivers are accelerating (loading the engine and I would think increasing efficiency) up to a certain speed, and coasting back down to another speed. With the result being much better efficiency (i.e. mileage) versus cruising at the same average speed.
Now my question is, aside from "is the above supposition correct?", why don't manufacturers just put bigger plug-in battery "buffers" in, coupled with smaller gasoline generators and electric motors? Peak efficiency could very good, acceleration brisk provided the electric motor was suitable, fuel supply diversified, and fuel costs greatly reduced.
My answer to this (my own question
is that gas has always been so cheap that the additional cost of the system wouldn't be worthwhile over the lifetime of the vehicle. Now that gasoline prices have risen, the use of more efficient/more costly parallel hybrids is cost effective. And if gas prices rise again, the use of serial hybrids with even greater efficiencies available to the average driver would be practical. Also, other factors such as patents (supposedly toyota gets all of their batteries from cobasys, and as such must pay a relatively high premium), demand destruction (don't want to cut consumption too much or price drops), manufacturer supply chains (3-7 years turn-around, maybe more?), potential reliability issues, both from unproven technology (more expensive for the manufacturer), and modular vehicle design (possibly cheaper for the consumer in the long run) could significantly influence the makeup of a modern vehicle.
So... yeah, talk about OT. Anyway, does anyone have any opinions about where the current auto is headed?
