We continue from where you left off. Given the predicate $P(k)$:
$$ P(k) = 49 \mid (7k + 1) 6^k + (-1)^{k + 1} $$
You deduced $P(k + 1)$ to be:
$$ P(k + 1) = 49 \mid 7(−1)^k + 42 \cdot 6^k \wedge P(k) $$
Now, since we assume $P(k)$ holds it remains to show that $49 \mid 7(−1)^k + 42 \cdot 6^k$. We do so inductively. First we divide by $7$, getting:
$$ Q(k) = 7 \mid (-1)^k + 6^{k + 1} $$
We now show $Q(k)$ holds for all naturals. We consider two cases, these being that $k$ is even or odd. If $k$ is even $Q(k)$ is:
$$ Q(k) = 7 \mid 1 + 6^{k + 1} = 7 \mid 1 + 6 \cdot 6^k $$
This means $Q(k + 2)$ is:
$$ Q(k + 2) = 7 \mid 1 + 36 \cdot 6 \cdot 6^k = 7 \mid 1 + 6 \cdot 6^k + 6 \cdot 35 \cdot 6^k = 7 \mid 6 \cdot 35 \cdot 6^k \wedge Q(k) $$
Now, the base case $Q(0)$ holds therefore $Q(k)$ holds for all even $k$. If $k$ is odd $Q(k)$ becomes:
$$ Q(k) = 7 \mid -1 + 6 \cdot 6^k $$
In this case $Q(k + 2)$ is:
$$ Q(k + 2) = 7 \mid -1 + 6 \cdot 36 \cdot 6^k = 7 \mid -1 + 6 \cdot 6^k + 6 \cdot 35 \cdot 6^k = 7 \mid 6 \cdot 35 \cdot 6^k \wedge Q(k) $$
The base case for odd $k$ $Q(1)$ holds and so $Q(k)$ holds for all odd $k$. This implies $P(k)$ holds for all naturals.