Well, it's necessary to project a 3D world onto a 2D surface since your screen is a 2D surface.
3D graphics works in different "coordinate spaces", and these are converted between to get a final scene.
Imagine for example modelling a city. You might define the bottom left corner of the map as (0, 0), and the top right as (1000000, 1000000). You might also say that as a rule, one point will represent a foot of real space. This representation we will call World Space.
To draw your city, you'll want to import some models of buildings, and place them in the world. So you get your model of a building, but when you're making this model, you don't want to have to worry about the size of the world or where it will be - you maybe will say that the building's bottom left corner is at (0, 0) and its top right is at (1, 1). This representation we will call Model Space. In the world though, the building might be placed at (104, 136) and you might want it to be 1000x1000 pixels, so you will need to translate it to (104, 136) and scale it up 1000x. This is converting it from Model Space to World Space.
Finally, Camera Space is how you move around in the world. If you think about it, moving around in the world could be thought of in two ways (at least): You move around the world, or the world moves around you. So to make movement easy, we'll say that the camera is always at the point (0, 0) facing down some axis. Now if you want to move forward 10 pixels, instead you just move everything back 10 pixels. If you want to rotate, rotate the world instead. So to render the building, first we want to transform it from Model Space to World Space. Now, to actually draw it, we want to know where it is relative to the viewer, so we move it from World Space to Camera Space.
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As an aside, if you want to understand this very well, a good exercise is to write a 3D wireframe renderer, separate from OpenGL. Your only drawing function available is DrawLine(x1, y1, x2, y2) which draws a line on the screen from (x1, y1) to (x2, y2).