The result of convolving two $BW=2$ triangles is the same as convolving four $BW=1$ rectangles, and has $BW=4$. It is a piece-wise cubic, whose shape approximates a bell shaped curve. If you convolve a $BW=a$ curve with a $BW=b$ curve, the convolution will have $BW=a+b$.
Here I understand "bandwidth" $BW$ to mean half the length of the shortest interval on which the signal is non-zero. If $f$ is supported on interval $[-A,A]$ and $g$ is supported on $[-B,B]$, then $h=f*g$ is supported on $[-(A+B),(A+B)]$. For if $h(x)=\int_{\mathbb{R}} f(y) g(x-y) dy$, the only non-zero contributions to the integral for $h(x)$ come from $y$ values for which $|y|\le A$ **and** for which $|x-y|\le B.$ By the triangle inequality, for such $y$ we have $|x|\le |y|+|x-y|\le A + B.$ If $|x|>A+B,$ there is no $y$ for which **both** $f(y)\
e0$ and $g(x-y)\
e0$, so $h(x)=0$ for such $x$.