Commercial zebrafish culture systems are commonly used for culturing experimental zebrafish. Although they have many advantages, commercial culture systema lacking the automatic feeding capabilities are usually laborious to operate and could lead to poor and unstable qualities of the cultured fish. This research is aimed to develop an automatic feeding mechine, capable of feeding dry pallets or powders and liquids containing live brine shrimp larvae, accurately enough to replace human feeding, and can be adopted to the smart zebrafish culture systems. In this research, a dry and a wet feeding mechanisms are developed using air pressure to deliver the feed. The dry feeding mechanism has an Arduino chip that controls a stepping motor. The motor drives a rotating rod at the bottom of the feeder, a groove on the rotating rod transfers a fixed amount of a channel below it, allowing the feed to be blown out by the air pump. The wet feeding mechanism uses air bubbles to aerate the water in the feed bottle to keep brine shrimp nauplii, it uses the Arduino chip and a solenoid valve to control the air in to the fodder bottle, which then help to force the water comtaining the nauplii to spray out through a tube. Further, a light sensor is used to position a carrier for the dry and wet feeding mechanisms to test movement and positioning results. The results show that the dry feeding mechanism can accurately throw out fodder according to the sizes of the rotating rods. The feeding amount and error of the three different diameter rotating rods (5, 7, 9mm) are 0.04 ± 0.004g, 0.11 ± 0.014g and 0.21 ± 0.022g, this resprctively result is more accurate than manual feeding (manual:0.1±0.14g), proving that this mechanism can meet the daily feeding needs of zebrafish. Each complete feeding action takes only 15 seconds from start to finish, much more efficient than manual feeding. The test results of the wet feeding mechanism show that the wet feeding can completely throw out the liquid in the feed bottle at a very stable rate, with the errors of 100 feedings less than 1% (average ± error: 10.1 ± 0.1ml). The movement mechanism test results show that only one of the 10 tests deviated more than expected (3.5mm), and the remaining errors are between 0 and 1.5mm, meaning the feeding mechanism can deliver feed to fish tanks accurately for commercial zebrafish culture systems. The feeding mechanism does not conflict with the existing patents of other feeding machines, and can apply for new patents, this is extremely beneficial to the build up of a localized intelligent zebrafish culture system in the future.