Okay, let’s back up: a self-propelled vehicle is pretty much any sort of conveyance that, you know, can make itself move. This includes everything from wind-up cars to Japanese Shinkansen trains to rockets to a hovercraft to your friend’s dad’s old Fiat 128 to that moped you always wanted as a kid and never got. Now, let’s think a little more about self-propelled vehicles. Let’s consider old cable cars. The famous San Francisco cable cars worked like this: in between their tracks was a channel with a moving braided cable. Here’s how the Cable Car Museum describes the system: Were you to look at these famous cable cars in operation, they sure would look like self-propelled vehicles, as this 1984 video shows, as it explains it all to you, too. They’ve been around since 1873! Look: Through a slot in the street the car grabs the cable with a big vice-like lever mechanism called a grip. To start the car, the gripman pulls back on the lever which closes the grip around the cable. To stop the car, the gripman releases the grip and applies the brakes.
Did you just lose about 16 minutes on that like I did? If so, sorry. But, you get my point: these behave like self-propelled vehicles, though the motive force, a number of 510 horsepower electric motors turning huge winding wheels that actually pull those cables, is not aboard the cable cars themselves. The cable car itself has a clamp to “harness” the energy of the moving cable. So, does that mean they’re not self-propelled vehicles? Or is the clamp system enough of a mechanism to consider it to be simply using the energy from the motion of the cable for propulsion? Something like an elevator, which I do think is a vehicle, much like a short-distance vertical railroad, works in a similar manner. Now, stay with me here: If we don’t think that a cable car qualifies as a self-propelled vehicle, what about electric buses and trolleys that have motors on-board but get their electricity from overhead wires? You know, trolleybuses like these:
Really, these aren’t any different than other electric-powered vehicles like subways or trolleys with an electrified rail or a slot car track, even. Like the cable car, these machines get their power from conveyers of that power on a network. In the case of trolleybuses, that power is in the form of electricity, through wires. In the case of cable cars, the power is the motion of the cable. Is it that different? Both need outside energy sources to work; one gets that energy and then converts it to rotational, and then forward motion. The other gets the energy in the form of motion from the get-go. Now, if we keep thinking along these lines, we get to sailboats. Are sailboats self-propelled in the same way that a cable car or subway or trolleybus is? In all cases, we have a vehicle that gets its energy from some outside network: the trolleybus from the overhead wires, connected to the power grid and then fed to the on-board electric motors to convert to motion; the cable car from the moving cable under the road, the clamp system transferring the motion from the cable to the whole car; and in the case of a sailboat, the power comes from the wind, air moving in the atmosphere of the Earth, which is harnessed by the boat’s sails and the motion of the wind is transferred into motion of the whole boat.
A sail is a mechanism for capturing energy and turning it into motion, like an electric motor can turn electromagnetic energy into physical motion, just in a very different way. The motive network of a sailboat is the whole atmosphere wherever the boat may be, and as such is quite vast and expansive. So, back to my original question: do any of these count as self-propelled? Is a requirement for being self-propelled that the energy source must be able to be stored aboard the vehicle? The fuel in your car’s tank is really part of an energy network as well, one that started with dinosaurs keeling over, and then lots and lots of time and heat and pressure and microorganisms and probably a bit of magic, then continues with oil companies pumping and refining and trucking and storage and so many steps before it gets to a pump to squirt into the tank of your car. Is that any different than grabbing a moving cable or capturing wind? Or is it essentially the same idea, just instead of drinking continuously from the spring of energy to move, you’re taking mouthfuls away, moving around, and coming back for more? A battery EV, too, is the same: just like a wire-powered trolleybus, but taking some amount of electricity on-board, replenishing as needed. Is this the fundamental differentiator for self-propulsion? On-board energy storage? Or does that actually matter, and it’s just the ability of a vehicle to turn energy into self-motion, via some mechanism that could range in complexity from a cloth sail to the complex electric motor unit in a Tesla. I asked some smart people I trust if they felt a sailboat was self-propelled. They didn’t think so, but the more I think about it, the less sure I am. I think now that a sailboat is self-propelled, and it does have an on-board mechanism for turning energy into motion, or at least one kind of motion (wind) into another (ship moving). If you don’t think a sailboat is self-propelled, you at least have to admit that it is remarkably independently mobile for something that isn’t. Sailboats have criss-crossed the globe for centuries, not being pulled by whales or massive clusters of plankton or anything like that. They’re very steerable, in the right hands, and behave effectively like something that is self-propelled. I think it is? But then I wonder where the line gets drawn; why does a glider not feel like it should count? Or, say, a simple raft, which, really, isn’t any different as it flows down a river than a cable car is as it gets dragged down Mission Street.
Or a hot air balloon, even? Does the burner to make heated air that rises count as a propulsion system? It carries fuel with it for that, but it’s only active on the vertical axis, and relies on outside wind energy for horizontal motion; so does that make a hot air balloon self-propelled on the vertical axis but not on the horizontal axis? Or is it just self-propelled? I’ve taken a simple idea and confused myself really, really effectively. Help me figure this out! I would argue that there is the implication that a vehicle and its propulsive force are mechanical in nature, not living. A horse does not qualify as a vehicle, nor does a bicycle, push-scooter, rollerblades, wheelies, etc, etc. I would also argue that there is an implication that a self-propelled vehicle has some amount of freedom of movement. Does self-propulsion imply that if MUST have a sentient being that is AWARE of movement? Ah? Thus, meaning that a horse can be self-propelled. Any human controlled device can be self-propelled, but a rock that simply falls down the hill is not. A Tesla is not sentient (thank God) but the sentient being inside makes it so. How bout them apples? It’s NOT the propulsion mechanism form that matters but rather the embodiment of SELF that is the key determinant. Whoa! I need to lie down now. If you separate vehicles into motorized and non-motorized you get a more manageable taxonomy. Cable cars are not motorized because the motor is remote. Electric trollies and busses are motorized, sail boats are not unless perhaps a wind turbine powers a motor. Hmm… I will leave this one for you https://en.m.wikipedia.org/wiki/Blackbird_(wind-powered_vehicle)#:~:text=On%20July%202%2C%202010%2C%20Blackbird,on%20El%20Mirage%20Dry%20Lake. For land vehicles, I’d say if it can move uphill via onboard power, then is self propelled. If the sailboat and wind share a vector the sailboat’s speed is limited to that of the wind’s. The wind is a pushing force, and the sailboat is a hot air balloon, a raft in a current, a car on a cable. And when that sailboat’s speed matches the speed of the wind (again, shared vectors) the sailboat is you and the wind is the elevator – but the cable has snapped, you and the elevator are in freefall and for a few protracted seconds you marvel at the feeling of weightlessness as you experience no other force save, perhaps, for the expulsion from your rectum. But if the sailboat and wind vectors aren’t perfectly aligned the wind is a lifting force, too. A pushing force, and a lifting force, simultaneously. Because there’s one wind pushing and a new wind created my moving through the air. Stick your hand through the door of your elevator in free fall and you’ll feel it. To the elevator, it’s drag. To the sailboat, a new source of energy. Because the sailboat has wings. “Wings” in that those sails experience a drag force (slowing things down) and a lifting force (speeding things up), and – properly built and set – the lifting force of those sails will exceed the drag. As boat speed increases so, too, does that of the created (or, apparent) wind, which increases the lifting force on the sails, which increases the boat speed, which increases the speed of the apparent wind, which increases the lifting force on the sails, which increases the boat speed, which increases… The forecast calls for 15mph winds. You’ve got a fast boat. The wind is blowing due south, and you’re headed due west. You have a date with an old friend to scavenge the shores of a small island for old gravestones slowly exposed by the eroding waves of a rising sea 45 miles away. You’ll be there in an hour. Plenty of time to think about whether your boat is self-propelled. Hot air balloons are a hybrid as they use both self-contained energy (propane heat) and earth wind energy.