Only break down the model of the car into pieces that will be exposed as separate entities outside the scope of the car. Another way to think about it is do you really understand how your car gets started when you turn the key? As far as the typical driver is concerned, everything under the hood is one big (and noisy) black box. The auto-engineers know the common parts that need maintenance by the car owner and have explicitly designed them for a different level of user interaction, things like the oil dipstick or coolant reservoir refill cap.
Can you model each piece of the car? Sure. Is it helpful to model the individual spark plugs? Probably not.
Do you need cars with different attributes like color or size? Do you need cars with different capabilities like passenger or towing capacity? The one place that is different is if you need cars with different behaviors. This is where you really need to think about modeling a Driver object which has attributes, from simple ones like reaction-time to complex ones like aggressiveness.
Modeling vehicles as examples of object orientation or inheritance is problematic because the examples don't really explain the true distinctions between essential attributes that define a class. It's not new to StackOverflow but this question isn't a duplicate either, see this SO thread. I had this same discussion with a friend of mine and posted a log of it on my blog. Read up on the different aircraft types the FAA recognizes and how the regulations for each type are subdivided. There are lots of different types of aircraft, the biggest separation is between powered and unpowered.
Check out the definitions used by the FAA:
Aircraft means a device that is used
or intended to be used for flight in
Airplane means an engine-driven
fixed-wing aircraft heavier than air,
that is supported in flight by the
dynamic reaction of the air against
Airship means an engine-driven
lighter-than-air aircraft that can be
There is also lighter-than-air and heavier-than-air. A hot-air balloon is unpowered and lighter-than-air. A blimp is powered and lighter-than-air. A glider is unpowered and heavier-than-air. A Boeing 757 is powered and heavier-than air but adds another category of 'fixed-wing' which is unlike a helicopter which is also powered and heavier-than-air but is 'rotary-wing'.
Here is the first four in the form of a table:
| Powered | Unpowered
Lighter-than-air | Blimp | Hot-air balloon
Heavier-than-air | 737 | Glider
You get the picture.
You can't just say you'll model the engine separately from the car because a car without an engine might be a whole different animal. A car without an engine is nothing like a trailer, which also doesn't have an engine but never will either. In these cases neither 'is-a' nor 'has-a' fits in the concrete way we build objects. You don't declare a blimp as being a aircraft that 'is-a' lighter-than-air, so is a hot-air balloon. The fact that they are both lighter-than-air doesn't make them related in any way except the physics they exploit. The distinction is important because the rules and regulations that apply are different. From the other angle, we don't describe a blimp as a hot-air balloon that 'has-a' engine. The aircraft aren't physically related, the relationship is how they should be handled.
If you don't need to define your objects to that level of detail, you may not need to model them to that level of detail either.