Let It Be said:
I don't know what the horizonatl and vertical components of velocity are...can you help please!
Vertical acceleration is 9.8m/s^2 (I think)
No horizontal acceleration
A=Vf-Vi/Tf-Ti??
Then where does the 30° come in?
As Jedishrfu has advised, use trig (sin and cos) to resolve the initial velocity into horizontal and vertical components. Surely, you would've covered this in coursework.
The magnitude of vertical acceleration is [itex]g[/itex] as you have stated, but don't forget the direction. The usual convention is to depict "up" as positive and "down" as negative. So if the initial vertical velocity [itex]u_y[/itex] is [itex]+1 ms^{-1}[/itex] (just an example), then the constant vertical acceleration is [itex]-9.8 ms^{-2}[/itex].
The equation for acceleration you quoted is essentially correct, but the usual form it's written in is [itex]v = u + at[/itex], where v is the final velocity (your Vf), u is the initial velocity (your Vi), a is the acceleration (your A) and t is the time interval (your difference of Tf minus Ti).
Correct, there is no horizontal acceleration (because you can neglect wind resistance, etc.) So the horizontal velocity [itex]u_x[/itex] remains constant.
Now find [itex]u_x[/itex] and [itex]u_y[/itex] (the initial horizontal and vertical components of the velocity, respectively) with trig. Then figure out what happens to the vertical velocity after 3 seconds using that equation. Then, once you've got the final vertical velocity [itex]v_y[/itex], figure out how to add that back to the horizontal velocity (which doesn't change) to get the magnitude of the final velocity (which is the final speed). Remember, vector addition is not as simple as just adding two quantities. Hint: Pythagoras.