hasTopping some CheeseTopping
hasTopping some VegetableTopping
The intersection of these expressions is not inconsistent. An individual can have more than one topping. E.g., a pizza can have one cheese topping and also have one vegetable topping. Then it would be an instance of both types, and thus an instance of their intersection.
(property some Class1) and (property some Class2)
is not equivalent to
(property some (Class1 and Class2))
This may be seen with another example (if the above isn't sufficient).
Human ⊑ ∃ hasBodyPart.Ear
Human ⊑ ∃ hasBodyPart.Hand
Every human (modulo injuries, birth defects, etc.) has at least one ear, and at least one hand. It doesn't mean that the hand is an ear, or that the ear is a hand.
So, to recap, you're right that
∀p.C ⊓ ∀p.D ≡ ∀p.(C ⊓D)
but it is not generally the case that
∃p.C ⊓ ∃p.D ≡ ∃p.(C ⊓D)
However, if something has a value which is both a C and a D, then it has a value which is a C, and a value which is D, so we do have this subclass relationship:
∃p.(C ⊓D) ⊑ ∃p.C ⊓ ∃p.D
As another example, consider the disjoint classes Mother and Father. The class expression
(hasParent some Mother)
is the class of things which have a mother. The class expression
(hasParent some Father)
is the class of things which have a father. There's clearly an non-empty intersection, since there are things which have both a father and a mother. The intersection expression is what you get by connecting these expressions with and:
(hasParent some Mother) and (hasParent some Father)
This is different, and not equivalent to, the class expression:
(hasParent some (Mother and Father))
All of the description logic operations are really just a convenient syntax for logic and set theory. The class expression (p only C), or in DL notation, ∀ p.C, denotes the set of individuals that are only related by the property p to elements of C. I.e.,
(p only C) ≡ {x : ∀y [p(x,y) → y ∈ C]}
Similarly, (p some C) is the set of individuals that are related to some element of C by property p. I.e.,
(p some C) ≡ {x : ∃y [p(x,y) ∧ y &in C]}
Now you can consider intersections.
(p only C) and (p only D)
≡ {x : ∀y [p(x,y) → y ∈ C]} ∩ {x : ∀y [p(x,y) → y ∈ D]}
≡ {x : ∀y [p(x,y) → y ∈ C] ∧ ∀y [p(x,y) → y ∈ D]}
≡ {x : ∀y [p(x,y) → (y ∈ C ∧ y ∈ D)]}
≡ {x : ∀y [p(x,y) → y ∈ (C ∩ D)]}
≡ (p only (C ⊓ D))
You don't get quite the same reduction for existential restrictions, though:
(p some C) and (p some D)
≡ {x : ∃y [p(x,y) &wegde; y ∈ C]} ∩ {x : ∃y [p(x,y) &wegde; y ∈ C]}
You can't reduce this any farther, because the y in the first existential isn't necessarily equal to the y in the second.