Does the elliptic curve $y^2 = 4 x^3 -6075$ have any integer points?

No, $y^2=4x^3-6075$ has no integer solution.

An elementary observation: $3\nmid x$: because $$3\mid x \implies 27\mid y^2 \implies 9\mid y \implies 9\mid x$$ but $y^2+6075$ has no solution in $\mathbb{Z}/3^6\mathbb{Z}$.

The ring of integer of $\mathbb{Q}(\sqrt{-3})$ is a UFD. The equation can be written as $$\left( {\frac{{y + 45\sqrt { - 3} }}{2}} \right)\left( {\frac{{y - 45\sqrt { - 3} }}{2}} \right) = {x^3}$$ elements inside brackets, denoted by $\alpha$ and $\beta$, are integral over $\mathbb{Z}$ since $y$ is odd.

I claim that $\alpha,\beta$ are relatively prime. If a prime $\pi$ divides both, then $\pi\mid 45\sqrt{-3}$, so $\pi = \sqrt{-3}$ or $5$. If $\pi = \sqrt{-3}$, then $3\mid x$, contradiction. If $\pi = 5$, let $v_5$ denote valuation at $5$, normalized so that $v_5(5)=1$, note that $v_5(\alpha) \in \mathbb{Z}$ as $v_5$ is unramified. $$0< v_5(\alpha)+v_5(\beta) = 2v_5(\alpha)= 3v_5(x) $$ this says $v_5(x)$ is even, hence $5^6 \mid (y^2+6075)$, but $y^2+6075=0$ has no solution in $\mathbb{Z}/5^6\mathbb{Z}$, ruling out $\pi = 5$. Valuation can be saved by noting that $5^3 \mid (y^2+6075)$ is already impossible, but it seems difficult to deduce the stronger $5^6 \mid (y^2+6075)$ from consideration in $\mathbb{Z}$ alone.

Since $\alpha,\beta$ are relatively prime, they are both cube, say $$\frac{{y + 45\sqrt { - 3} }}{2} = {(\frac{{a + b\sqrt { - 3} }}{2})^3} \qquad \text{ or } \qquad \left( {\frac{{1 + \sqrt { - 3} }}{2}} \right){\left( {\frac{{a + b\sqrt { - 3} }}{2}} \right)^3}$$ with $a,b$ both even or odd. The first case gives $60= {a^2}b - {b^3}$, so $b$ has only a few possible values, checking them gives no integer solutions to original equation. The second case gives $$\frac{{45}}{2} = \frac{{{a^3} + 3{a^2}b - 9a{b^2} - 3{b^3}}}{{16}}$$ this says $v_3(a) \geq 1$, thus $v_3(a^3+3a^2b-9ab^2)\geq 3$ but $v_3(45/2) = 2$, so $v_3(3b^3) = 2$, absurd.


Sagemath

Multiplying by $2^4$, you get $$ (2^2y)^2=(2^2x)^3 - 97200 $$ This is a Mordell curve with $n=-97200$, but it looks like there are only records for $-10000 \leq n \leq 10000$. The curve $$ Y^2 = X^3-97200 $$ according to Sagemath has only one integral point $$ (X,Y) = (49,143) $$ so if it's correct then $(x,y) = (X/4,Y/4) = (49/4,143/4)$ is not integral and hence no integer points.


LMFDB

The curve has conductor $6075$ so you can try to find it via the LMFDB (The L-functions and Modular Forms Database), as shown in this page. It finds up to $400000$ but lists only the minimal model of the curve so you have to match those coefficients.

Taking modulo $2$, we know that $y$ is odd. Now let $(x,y)=(X,2Y+1)$, then $$ \begin{align} (2Y+1)^2 &= 4X^3- 6075\\ Y^2 + Y &= X^3 - 1519 \end{align} $$ so the coefficients are $$ [a_1,a_2,a_3,a_4,a_6] = [0, 0, 1, 0, -1519] $$ corresponding to this curve in LMFDB. According to it, similarly there are no integral points.


Magma

Another way that I know of is using an online Magma calculator

E := EllipticCurve([0, -97200]);
IntegralPoints(E);

which returns the same result as Sagemath [ <(49 : 143 : 1), 1> ]


Since the curve has rank $1$, there are infinitely many rational points. Hence I think modulo $p$ methods might not work.

Algebraic Number Theory

Perhaps another way is to solve the problem over the number field $K =\mathbb Q(\sqrt{-3})$. Rewriting, the equation becomes $$ X^3 = (Y+180\sqrt{-3})(Y-180\sqrt{-3}) $$ Then using the fact that $K$ has class number $1$, hence unique factorization in its ring of integers, we can try to deduce the possible $X,Y$'s.

Edit 1 Looks like this has been done by @pisco.


Using elementary number theory, take both sides modulo 4 so that $y^2=1\pmod{4}$, then $y=2m+1$. We also have $x=1\pmod3$ so $x=3n+1$. Expand to get: $$4m^2+4m+1 = 4(27n^3+27n^2+9n+1)-6075$$ So $$4m^2+4m=81n^3+81n^2+36n-6072.$$ Now take modulo $9$ on both sides to have $$4m(m+1) = 3 \pmod9.$$ This implies that $m(m+1)=3\pmod9$. So write $m(m+1)=9a+3$ and we need to solve $$ m^2+m-3-9a=0. $$ It follows that $13+36a$ needs to be the square of an odd number. Maybe this helps with your numerical search?