If you're planning to make it, I would reduce the chip clearance by adding a larger "shoulder" behind the cutting edge. A gear of that DP doesn't need anywhere near that much chip clearance. Other than that, it looks good!
Don't forget that the cutter needs back and side relief so that it will actually cut. You can get away without relief in brass, but most other materials will require relief and it will improve the surface finish on aluminum.
Regarding the involute form, have a look at how it is generated as opposed to directly machined in modern practice. A hob, having a straight tooth form like a rack gear is used to generate the involute profile on the gear by rotating the two in time. As the hob profile intersects the gear tooth, it generates a perfect involute tooth form.
Lighting Engineer said:
The difference between an involute gear and a "straight" cut gear is that an involute always makes contact as it moves in a "steady line of force"
A "straight cut gear" is also known as a spur gear. That is, the involute profile is cut straight across the face of the gear blank. Straight cut gears are used primarily because they are easy to make and are adequate for a very large percentage of commercial products.
Helical gears use the same involute tooth profile as a straight cut gear, except that the teeth form a segment of a helix across the face of the gear. Helical gears don't suffer as much from the radius of action differential shown in the animation you posted. Note that as the gear on the left drives the gear on the right, the radius of action or "leverage ratio" between the two gears changes. Because a helical gear is operating at multiple leverage ratios across the width of it's face, it transfers power smoothly and with less noise.
All I can say is that it's pretty curvy 
