Working with a byte array is practically (ignoring computers that cannot work with 8-bit chunks of data natively; I don't even know if such exist in actual use these days) guaranteed to always represent the data bytes in the same order, regardless of platform, programming language or framework. Given knowledge of the storage or transmission format, you can translate it to whatever internal format your current platform etc. uses.
For example, I wouldn't trust that an application written in C++ running on an Alpha CPU will write out an
unsigned long in the same way that a .NET application running on Intel writes out a
UInt32 (let alone how perhaps Java running on an IBM z10 might handle the lower 32 bits of a 64-bit
long or PIC assembly might handle tossing a 32-bit value at an I/O port). If you work with pure bytes, this becomes a non-issue: you will have to translate the byte sequence wherever you read or write it, but you will know exactly how to do that. It is well defined.
If you send data over a socket, persist it to a file, or otherwise transmit it in space or time, by using a byte array you guarantee that the recipient will see exactly what was sent or persisted. It is then up to the recipient (note that the "recipient" may be your own application's file "load" code, whereas the "sender" may be the code to "save" to a file) to do something useful with the byte sequence that the sender generated from whatever happens to be its native format.
If you are using non-byte types, you need to guarantee the byte order by other means, because depending on platform etc. the bytes may be interpreted in a different order. For example, you would need to specify (either yourself or by reference to the framework's specification) whether the persisted form of a multi-byte integer uses big endian or little endian.