$$\sqrt{3}\sqrt{2}-\sqrt{3}-\sqrt{2}+1=(\sqrt{3}-1)(\sqrt{2}-1) < 1$$

The last inequality follows from the fact that $(\sqrt{3}-1)$ and $(\sqrt{2}-1)$ are in $(0,1)$.

Second solution

By AM-GM you have

$$2\sqrt[4]{6} \leq \sqrt{2}+\sqrt{3}$$

Combine this with $\sqrt[4]{6} < 2$, which is easy to prove, and you are done.

$$\sqrt{3}\sqrt{2}-\sqrt{3}-\sqrt{2}+1=(\sqrt{3}-1)(\sqrt{2}-1) < 1$$

The last inequality follows from the fact that $(\sqrt{3}-1)$ and $(\sqrt{2}-1)$ are in $(0,1)$.

Second solution

By AM-GM you have

$$2\sqrt[4]{6} \leq \sqrt{2}+\sqrt{3}$$

Combine this with $\sqrt[4]{6} < 2$, which is easy to prove, and you are done.

And a non-algebraic one, which is an overkill :)

Let $\theta$ be the angle so that $\cos(\theta)=-\frac{1}{2\sqrt{6}}$. Plot a point $A$ draw two rays with an angle of $\theta$ between them, and pick points $B$ respectively $C$ on these ray so that $AB=\sqrt{2}$ and $AC=\sqrt{3}$. By the cosine law

$$BC^2=2+3+2\sqrt{2}\sqrt{3}\frac{1}{2\sqrt{6}}=6$$

Thus the triangle $ABC$ has the edges of length $\sqrt{2}, \sqrt{3}$ and $\sqrt{6}$, and your inequality is exactly the triangle inequality.