String literals are arrays - objects of inherently non-fixed (and possibly large) size. In general case there's simply no other way to represent such literals except as objects in memory, i.e. as lvalues. In C99 this also applies to compound literals, which are also lvalues. Hiding the fact that string literal is an lvalue at the language level would create a considerable number of completely unnecessary difficulties, since the ability to point to a string literal with a pointer as well as the ability to access it as an array relies critically on its lvalue-ness.
Meanwhile, literals of scalar types have fixed compile time size. At the same time such literals are very likely to be embedded directly into the machine commands on the given hardware architecture. For example, when you write something like
i = i * 5 + 2, the literal values
2 become explicit (or even implicit) parts of the generated machine code. They don't exist and don't need to exist as standalone locations in data storage with values
2. There's imply no point in that.
It is also worth nothing that on many (if not most, or all) hardware architectures floating-point literals actually end up being "hidden" lvalues (even though the language does not expose them as such). On platforms like x86 machine commands from floating-point group do not support embedded immediate operands. This means that virtually every floating-point literal has to be stored in (and read from) data memory by the compiler. E.g. when you write something like
i = i * 5.5 + 2.1 it is translated into
double unnamed_double_5_5 = 5.5;
double unnamed_double_2_1 = 2.1;
i = i * unnamed_double_5_5 + unnamed_double_2_1;
In other words, floating-point literals often end up becoming "unofficial" lvalues internally. However, it makes perfect sense that language specification did not make any attempts to expose this implementation detail. At language level arithmetic literals make more sense as rvalues.