By the rational root theorem, you have the following candidates for roots:
[tex]\pm\dfrac16,\pm\dfrac13,\pm\dfrac12[/tex]
Plugging in each of these will tell you which one is actually a zero. You'll find that both [tex]x=\dfrac12[/tex] and [tex]x=\dfrac13[/tex] both work, which means [tex]x-\dfrac12[/tex] and [tex]x-\dfrac13[/tex] are linear factors to the quartic.
To find the remaining factor(s), divide the quartic by the known factors:
[tex]\dfrac{6x^4+x^3+2x^2-4x+1}{x-\dfrac12}=6x^3+4x^2+4x-2[/tex]
[tex]\dfrac{6x^3+4x^2+4x-2}{x-\dfrac13}=6x^2+6x+6[/tex]
Since [tex]6x^2+6x+6=6(x^2+x+1)=0[/tex] has no real roots, you are left with
[tex]6x^4+x^3+2x^2-4x+1=\left(x-\dfrac12\right)\left(x-\dfrac13\right)(6x^2+6x+6)=(2x-1)(3x-1)(x^2+x+1)=0[/tex]
which has two real zeros at [tex]x=\dfrac12[/tex], [tex]x=\dfrac13[/tex]. It also has two complex roots at [tex]x=-\dfrac{1\pm\sqrt3i}2[/tex].
