Ammonium is highly toxic for aquatic animals, but its conventional detection methods are labor-intensive, time-consuming and involved using toxic or expensive reagents. In this approach, the rapid and unstable reaction with the cheap and eco-friendly reagents, o-phthalaldehyde (OPA) and N-acetylcysteine (NAC), was conducted with a software-controlled lab-on-valve (LOV) system to achieve a highly sensitive and selective analytical performance by a stopped-flow strategy. A LOV system with a 5 mL syringe was used for sampling (pond water, the aqueous ammonium or glycine standard solutions for calibration) and mixing with the reagents (0.0160 M OPA and 0.0079 M NAC in 0.1 M phosphate buffer, pH 6.8); the mixture was then introduced through a stainless reaction coil (63°C, 0.8 mm i.d. × 400 cm) and then a flow-through fluorometer with the excitation/emission wavelengths at 410/470 or 380/470 nm. For the stopped-flow process, the flow was stopped and the reaction mixture was heated in the reaction coil for 1 minute, and the reacted mixture was propelled through the detector. The whole liquid-handling and fluorescence monitoring process were performed by user interfaces developed under LabVIEW platform. For ammonium determination, a calibration curve (410/470 nm) with the linear range from 0.1 to 2.0 ppm was obtained with the correlation coefficient of 0.9987; the relative standard deviation (n=3) for 1.0 ppm was less than 5%, and with limt of detection of 0.04 ppm. The sample throughput was higher than 15/hr. Since the fluorescence spectra of the OPA-adducts of ammonium and primary amines are distinctly different, two-wavelength (410/470 and 380/470) measurement was adopted when the sample solution contains residual primary amines such as amino acids. With glycine as the amine standard, both ammonium and primary amines can be calculated with the errors less than 10%. Compared with the prior arts, this quick, sensitive and selective approach used only a general-purpose mini-LOV system to execute a safe, green and economic reaction, which is promising for the water quality inspection of aquaculture, sewage and livestock wastewater.