Deciding if a given graph (or type of graph) can be constructed this way would seem the more likely question. When it can, there is sometimes a name for a particular construction of this type. The [circle method][1] is one of several to construct a round robin tournament for $k+1$ players when $k$ is odd: A $k$ day tournament where each player plays one match each day and at the end all pairs have played. Consider the players as vertices of a complete graph $K_{k+1}$ and color the edges according to the day that pair plays their match. This decomposes the $\binom{k+1}2$ edges into $k$ perfect matchings.
Digression: There is much work on deciding if a graph $G$ is $k$-vertex colorable. \
Maximum degree $\lt k$ is certainly a sufficient condition.
Here is a construction of such a graph: Start with $k$ disjoint vertex sets (some perhaps empty) and add some edges, but only between vertices in different sets. The result is certainly $k$-vertex-colorable and every such graph arises that way. But the construction does not have a name as far as I know.
Here are some more interesting properties for a regular graph. Consider a simple graph $G$ which is regular of degree $k.$ Then the vertex coloring number is at most $k+1$ and could be $2.$ The edge coloring number is at least $k.$ We might wonder if it has one or the other of these properties:
**I)** It can be vertex colored with $k+1$ colors so that each vertex has one neighbor of each color other than it's own.
**II)** It can be $k$-edge colored.
The complete graph $K_{k+1}$ somewhat trivially has property I.
It is less obvious that, for $k$ odd, $K_{k+1}$ [ has property II][2]. One way of proving this is the circle method mentioned above.
Another interesting result is that, for $k$ odd, property I implies property II: Given the coloring of $G$, color the vertices of $K_{k+1}$ with the same colors and consider a $k$-edge coloring of that complete graph as just mentioned. Now color each edge of (the vertex colored) $G$ with the same color as the correspondingly colored edge of the complete graph.
To get back to your question, it is immediate that property I precisely says that $G$ can be constructed in this way:
- Consider $k+1$ disjoint vertex classes, each of the same size. Then choose $\binom{k+1}2$ matchings, one between each pair of classes.
While property II ($G$ is $k$-regular and $k$-edge colorable) precisely says that it arises from your construction:
- Take $k$ edge disjoint perfect matchings ($1$-factors) on some $2m$ points. (I'm assuming simple graphs and $k>0$.)
But I don't know that either construction has a name in general.
The construction can easily be used to create a $k$-regular bipartite graph. But it turns out the converse is true as well. A $k$-regular bipartite graph has a perfect matching and hence $k$ disjoint perfect matchings. So every regular bipartite graph has property II.
[1]: https://en.wikipedia.org/wiki/Round-robin_tournament#Circle_method
[2]: https://en.wikipedia.org/wiki/Graph_factorization#Complete_graphs