An Internet of Things-based X-ray generator employing a direct current inverter technique, comprising a base (5), a conveyor apparatus (4) arranged on the base (5), and, arranged at a side of the base (5), an X-ray detecting mechanism and a central control room (6). The X-ray detecting mechanism comprises a lifting/lowering apparatus (1) arranged vertically, a control console (2) arranged horizontally on the lifting/lowering apparatus (1), and two X-ray transmitters (3) arranged below the control console (2). Several control buttons (9) are arranged on the control console (2). The Internet of Things-based X-ray generator employing the direct current inverter technique communicates in real-time with a backstage via a wireless communication module (17) to ensure that staff monitors in real-time a state of onsite inspection, performs stable control of a working power supply of the X-ray transmitters (3) via an X-ray power supply control circuit in a power supply control module (18) and by means of a PWM technique, thus ensuring the stability of the output of the X-ray transmitters (3) and increasing the detection precision of the X-ray generator, and, at the same time, increases the operability and practicability of the X-ray generator via a button control module (14), a human-machine interaction module (15), and an instruction control module (16).Linvention concerne un générateur de rayons X basé sur un internet des objets employant une technique donduleur de courant continu, comprenant une base (5), un appareil de transport (4) placé sur la base (5), et, placé sur un côté de la base (5), un mécanisme de détection de rayons X et une salle de commande centrale (6). Le mécanisme de détection aux rayons X comprend un appareil de levée/abaissement (1) agencé verticalement, une console de commande (2) agencée horizontalement sur lappareil de levée/abaissement (1) et deux émetteurs de rayons X (3) agencés en dessous de la console de commande (2). Plusieurs boutons de comman
