Every even integer greater than $2$ can be expressed as the sum of two primes.
Extension of Goldbach's conjecture is:
Every number from $p\mathbb{Z}$ greater than $p$ can be expressed as the sum of $p$ primes
where $p\mathbb{Z}=\lbrace 0, \pm p, \pm 2p, \pm3p,\dots\rbrace$.
You can find a counterexamples?
For example if $p=5$:
Who can make this programming?
First of all we will assume that the Goldbach's conjecture is true, so given an integer $n=kp$ with $k\geq 4$ ($k=3,2$ are easy), we will prove that $n$ is the sum of $p$ primes.
If $p=2,$ it's the Goldbach's conjecture and it's true, so we can assume that $p>2$.
Case 1 If $n$ is even, let's write $$n=\underbrace{2+\cdots+2}_{p-2}+(n-2(p-2)),$$ and because $(n-2(p-2))=(k-2)p+4\geq4$ and it's even, then it can expressed as the sum of two primes. Hence, $n$ is the sum of $p$ primes.
Case 2 If $n$ is odd, let's write $$n=3+\underbrace{2+\cdots+2}_{p-3}+(n-2(p-3)-3),$$ and because $(n-2(p-3)-3)=(k-2)p+3\geq4$ and it's even, then it can expressed as the sum of two primes. Hence, $n$ is the sum of $p$ primes.
So we proved the following statement: $$\text{Goldbach's conjecture} \implies \text{Extension of Goldbach's conjecture}$$
But Goldbach's conjecture is a particular case of the extension of Goldbach's conjecture (when $p=2$), hence: $$\text{Goldbach's conjecture} \iff \text{Extension of Goldbach's conjecture}$$
Conclusion The extension of Goldbach's conjecture as you define it is equivalent to the Goldbach's conjecture itself, and hence no one will ever find a counterexample or prove it unless (s)he solves Goldbach's conjecture.
Suppose Goldbach is true. Let n be your candidate number. Then either n is even or odd. If even, then it is the sum of 2 primes. If odd then n - 3 is even so n is the sum of 3 primes. In no case would you need more than 3 primes.
