I'm stuck on kind of a silly functional analysis problem. Suppose that $T:D(T) \subset X \to Y$ is a closable linear operator, where $X$ and $Y$ are Banach spaces and $R(T)$ is finite dimensional. I need to show that $T$ is continuous, but for some reason we are not allowed to use the fact that a linear operator with finite dimensional range is compact.
My approach so far has been to pick an arbitrary sequence $\{x_n\} \subset D(T)$, with $x_n \to 0$. Then I want to show that $\{Tx_n\} \subset R(T)$ is Cauchy, so that the limit will exist (since $R(T)$ is a finite dimensional linear subspace of the Banach space Y, and thus complete). Then since $T$ is closable, I will have $\lim_{n \to \infty}Tx_n=0$. Since the sequence $\{x_n\}$ was arbitrary, then $T$ will be continuous at $0$ and hence continuous. However, I can't seem to show that $\{Tx_n\}$ converges.
Am I taking the wrong approach, or just missing something?
EDIT: For the person asking what closable means: http://www.math.pku.edu.cn/teachers/fanhj/courses/fl3.pdf on page 3 there is a useful criteria.