This table has 60 fields but 16 of those are indexed + 1 primary field.
This looks a bit excessive, but if you really need all these indexes then it's OK.
Indexes are not free: each additional index will take space, and require maintenance1 when modifying data, in return to speed-up when searching for data (assuming it's used correctly). It's up to you to identify the right trade-off for you particular case.
If this a good idea to have such a large table with all these indexes?
Having indexes on FKs is almost always a good idea, so the DBMS can maintain the FKs with good performance. Specifically, whenever a parent row is deleted or the referenced key updated, the DBMS has to search for the child rows. Theoretically, if you never delete/update parent, you won't really need indexes on FKs either, although some DBMSes will force you to have them in any case.
These indexes can be (and usually are) useful for JOINins, but that really depends on how you JOIN and how capable is the query planner of you DBMS.2
What is the best way to use indexes in such a large project?
For each performance-sensitive query, carefully examine the query execution plan and measure the actual timing on representative amounts of data. Just because a query is executed one way on a small table, doesn't mean it will be executed the same way when the table grows.
And last but not least, I warmly recommend reading Use The Index, Luke!
1 Every time a row is inserted into table, the DBMS has to insert the corresponding key in the index B-tree. When the row is removed, the key is removed from the index. When an indexed field is updated, the old key needs to be removed and the new one inserted. The more indexes you have on your table, the more time the DBMS will have to spend doing this "index maintenance" whenever you INSERT / UPDATE / DELETE a row in that table.
2 There are many ways a JOIN can be executed: nested loops in various orders, merge joins, hash joins... Different strategies may require different indexes or even different kinds of indexes (e.g. a B-tree won't do much good for hash joins). Not all DBMSes are capable of using all these strategies nor using existing indexes in all cases when they could theoretically be used. So an indexing strategy that works well for one DBMS may not necessarily work as well for another. And sometimes, you can keep the indexes, but you have to "nudge" the DBMS in the right direction, either by using "query hints" or by using a syntax that is "friendly" towards the query optimizer of the particular DBMS, even though the equivalent but more human-readable syntax may exist. For example, older versions of MySQL would always execute an IN sub-query as the inner one of the nested loops, even in cases where a reverse order of loops or a merge join would be faster. That's why people often recommend rewriting IN as JOIN under MySQL (though I hear they fixed that in MySQL 5.6). OTOH, rewriting an IN as JOIN under Oracle is not very useful, since Oracle is much better at executing equivalent queries equivalently, even when there are syntactic differences.