I believe there are two approaches here: 1) redo the binarization step that led to these images you have right now; 2) consider different possibilities based on image size. Let us focus on the second approach given the question.
In your smallest image, only two digits are connected, and that happens only when considering 8-connectivity. If you handle your image as 4-connected, then there is nothing to do because there are no two components connected that should be separated. This is shown below. The right image can be obtained simply by finding the points that are connected to another one only when considering 8-connectivity. In this case, there are only two such points, and by removing them we disconnect the two digits '1'.
In your other image this is no longer the case. And I don't have a simple method to apply on it that can be applied on the smaller image without making it worse. But, actually, we could consider upscaling both images to some common size, using interpolation by nearest neighbor so we don't move from the binary representation. By resizing both of your images so they width equal to 200, and keeping the aspect ratio, we can apply the following morphological method to both of them. First do a thinning:
Now, as can be seen, the morphological branch points are the ones connecting your digits (there is another one at the left-most digit 'six' too, which will be handled). We can extract these branch points and apply a morphological closing with a vertical line of 2*height+1 (height is from your image), so no matter where the point is, its closing will produce a full vertical line. Since your image is not so small anymore, this line doesn't need to be 1 point-wide, in fact I considered a line that is 6 points-wide. Since some of the branch points are horizontally close, this closing operation will join them in the same vertical line. If a branch point is not close to another, then performing an erosion will remove a vertical line. And, by doing this, we eliminate the branch point related to the digit six at left. After applying these steps, we obtain the following image at left. Subtracting the original image from it, we get the image at right.
If we apply these same steps to the '8011' image, we end with the exactly same image as we started with. But this is still good, because applying the simple method that remove points that are only connected in 8-connectivity, we obtain the separated components as before.