I've attached the algorithm at the end of my comment.

@AngelicCore, I think the fundamental difference between your solution and the one in the video is that your solution is an "on-line" solution and the one in the video is an "off-line" solution.

Off-line bin packing assumes that the packer has perfect information about each item and has time to arrange them in any order he or she would like. Consider a warehouse with a staging area for shipping. All the cases can be stacked, palletized, and re-ordered as needed until it is ready to be shipped.

On-line bin packing is done "on-the-fly" often on a first-in-first-out basis (FIFO). Imagine you are receiving cases from incoming trucks unto a conveyor belt. The material handling equipment quickly re-directs all cases to a fleet of outgoing trucks.

Additional Notes

The bin capacity is given at 16. (14+13+12+11+10+10+9+8+7+6+6+5+4+3+3+2+2+1)/16 = 126/16 ~ 7.87 => ceiling(7.87) = 8 minimum
bins are the lower bound.

Algorithm

Best-Fit Heuristic
Description: This heuristic attempts to create the fullest bin possible each time an item is assigned. Again, all unfull bins are kept open. It places the next item j in the bin whose current contents are largest, but do not exceed Q − qj (so the item fits). If it does not fit in any bin, a new bin is opened.
Initialization :
Given a list of item weights L = {q1, q2, ..., qn}. Placeitem1inbin1andremovefromL. Letj=2,m=1.
Iterations :
1. Find the bin i whose remaining capacity is minimum but greater than qj (if Si are
the items in bin i, Q − qk is the remaining capacity of bin i), and place j in k∈Si
i. If j does not fit in any bin, open a new bin and number it m + 1, place j in bin m + 1 and let m = m + 1.
2. Remove item j from L. Let j = j + 1.
3. While items remain in L, repeat from Step 1.