Your proposal is bizarre. You are Alice. You wish to send a secret message to system "Bob" that only Bob can decrypt. Your proposal is that Alice generates a key pair for Bob, then somehow magically gets Bob's private key from Alice to Bob, and then Alice presumably keeps the public key secret. If you have a mechanism whereby Alice can communicate the private key to Bob then why do you need cryptography in the first place? You already have a secure channel!
Maybe it is too expensive to use the secure channel for the large documents. Even if it is, your scheme is the exact opposite of how public key encryption is supposed to work. What you want is for Bob to generate the key pair and transmit the public key in the clear to Alice.
Now the problem that Bob has to solve is how does Alice know that the public key actually came from Bob? An attacker could be sending their public key to Alice and telling Alice that it came from Bob. This is the important problem that you should be solving. The strength of the entire scheme rests upon Bob being able to get his public key to Alice successfully.
What you really need to make this work is a trusted third party, say, Verisign or some other certifying authority, whose public key is well known. Alice and Bob can both generate their own key pairs, and then Verisign can vouch that Alice's public key and Bob's public key came from Alice and Bob, respectively. That's the foundation that the system's security rests upon.
Furthermore: public key crypto is slow for large messages. Usually what you want to do is use public key crypto as part of a key negotiation. That is generate a secret key in a symmetric cryptosystem for a particular "session", use public key crypto as the secure channel to communicate the session key from Alice to Bob, and then encrypt everything else using the fast symmetric algorithm.