A conjecture involving a universal set, and a train of thought for formulating a kosher equivalent

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The status quo of mathematics today seems to be reliance upon an underlying set theory that doesn’t permit the existence of a universal set. However, that doesn’t mean that when we think of a conjecture that involves reference to a universal set, that we should simply cross out the conjecture, throw away the paper that it was written on, and drop the paper down a memory hole of Orwell’s novel 1984. There may be a train of thought that will transform the conjecture so that we get some equivalent conjecture that is kosher.

Does anybody know of an example of such a conjecture and of such a train of thought for transforming it into something kosher?
 
V = universe of all sets
L = universe of constructible sets
Conjecture: V = L

See here for Wikipedia article.
 
V = universe of all sets
L = universe of constructible sets
Conjecture: V = L
I’m not familiar with the concept of a universe of sets in set theory.

Is the following equivalent to your suggestion? Alternatively, is it a parody, straw man attack, or other misrepresentation of your idea?

My version of your suggestion:
V = the class of all sets
L = the class of sets that can be constructed
The conjecture: V = L
In my version or your suggestion, the conjecture is kosher, so there’s no need for a train of thought to formulate a kosher equivalent of the conjecture. Thus, if my version is equivalent to your suggestion, then your suggestion helps to demonstrate the difference between hitting the broad side of a barn, and actually hitting the topic on the nose, but isn’t strictly speaking on-topic. If my version is equivalent to your suggestion, then your suggestion is a contribution to the meta-discussion, and a contribution to the pedagogy, but isn’t strictly speaking on topic from the point of view of people who have had enough sleep and don’t require extra tutoring.
 
It is possible to extend the language of set theory to include additional types of objects such as proper classes, in which case V and L are classes, and V = L is a legitimate expression just as it stands.

Alternatively, one can ask what the equivalent of V = L is in standard “sets only” set theory, where V and L are not directly allowable expressions. In this case, the approach is to translate the pseudo-expression V = L into another pseudo-expression that is closer to allowable set theory, and keep on doing that until one obtains an expression that is directly in the allowable language of set theory. For example,

V = L becomes (for all x) ((x in V) if and only iff (x in L))

(x in V) becomes x = x

(x in L) becomes x in (union over ordinals a of L_a) becomes (exists ordinal a) (x in L_a)

and so on.
 
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