Suppose $n\ge4$. For any natural $j$, let $I_j$ be the indicator of heads in the $j$th flip. Then the number of times 4 consecutive heads appear in $n$ flips is 
$$N_H=\sum_{j=1}^{n-3}\prod_{k=0}^3 I_{j+k}.$$
So,
$$EN_H=\sum_{j=1}^{n-3}\prod_{k=0}^3 EI_{j+k}
=\sum_{j=1}^{n-3}\prod_{k=0}^3\frac1{2j-1+2k}=\frac{4 n^3-18 n^2+23 n-15}{45 (2 n-5) (2 n-3) (2 n-1)}. 
$$
Similarly, the expected number of times 4 consecutive tails appear in $n$ flips is 
$$EN_T=\sum_{j=1}^{n-3}E\prod_{k=0}^3 (1-I_{j+k}) \\
=\sum_{j=1}^{n-3}\prod_{k=0}^3 (1-EI_{j+k})
=\sum_{j=1}^{n-3}\prod_{k=0}^3\Big(1-\frac1{2j-1+2k}\Big)
=\frac{4 (n-3) \left(n \left(6 n^2+4 n-39\right)+23\right)}{3 (2 n-5) (2n-3) (2 n-1)}+2 H_{n-4}-4 H_{2 n-7}, 
$$
where $H_p$ is the $p$th harmonic number. 
The expected number of points you would get is $EN_H+EN_T$ for $n=100$, which is 
$$2346708582182272408275807403879906977180754393543457162802747798939487\
45206696917816972687/\
2635106162757236442495826303084698495565581115509040892412867358728390\
766099042109898375\approx89.0556\approx100,$$
which makes sense.