There are various approaches to evaluating lambda terms. Depending on whether type information is available or not, you can get more efficient and more secure evaluators (runtime checks are not needed as the programs are known to be well-behaved). I'm going to give a crude presentation of some techniques.
Big steps evaluators
Rather than repeatedly locating lambda-redexes and firing them (which means traversing the term multiple times), you can devise an algorithm trying to minimise the work by evaluating a term in "big steps".
E.g. if the term you want to normalise is
t u then you normalise both
u and if
norm t is a lambda abstraction, you fire the corresponding redex and restart the normalisation on the term you just got.
Abstract / Virtual Machines
Now, you can do basically the same work but a lot faster using abstract machines. These small virtual machines with their own set of instructions and reduction rules which you can implement in your favourite language and compile lambda-terms to.
The historical example is the SECD machine.
Danvy et al. have shown that well-known abstract machines can be derived from the evaluators mentioned before by a combination of continuation passing style and defunctionalisation.
To get a lambda-term back from an abstract machine, you need to implement a reification / read back function building a lambda term based on the state the machine is in. Grégoire and Leroy show how such a thing can be done in a context where the type theory of the language is the one of Coq.
Normalisation by Evaluation
Normalisation by Evaluation is the practice of leveraging the evaluation mechanism of the host language in order to implement the normalisation procedure for another language.
Lambda abstraction are turned into functions in the host language, application becomes the host language's application, etc., etc.
This technique can be used in a typed manner (e.g. normalising the simply-typed lambda-calculus in Haskell or in OCaml) or an untyped one (e.g. the simply-typed lambda-calculus once more or Coq terms compiled to OCaml (!)).