The COVID-19 virus and its variants have caused skyrocketing illness rates worldwide and have been proven as an airborne disease. Based on the perspective of occupational health, source control is the most effective way of hazard prevention. Therefore, whether the exhaled particles of the carriers can be effectively prevented from contaminating the environment is the key to whether the transmission chain can be interrupted immediately. This study aims to develop an open face shield with filter and suction devices, called Personal Exhaled Breath Aerosol Receiver (PEBAR), which causes no breathing burden to wearers and captures the exhaled particles effectively to achieve the purpose of source control. PEBAR comprises a face shield, pleated filter, suction fan, connecting components, and lithium battery, worn on the user by ear loops and straps or waist straps. Using an independent experimental system to measure the capture efficiency of different structural parameters, referring to the measured values of human faces in the literature, and using LCD 3D printing to optimize and materialize the design of the face shield; The characteristics of the pleated filter and connecting pipe are evaluated, the appropriate type is selected, and the fan that can overcome the pressure drop caused by the aforementioned components is selected. Results show that the optimal height (TCGH)/width (TCGW)/thickness (TCGT) of the triangular curved groove (TCG) of the face shield is 3 / 10 / 2 cm. The baffle uses a polyurethane sponge (Mixing reducer), which can effectively prevent the exhaled particles at the upper edge of the baffle from being disturbed by the external airflow and escaping. However, it has many disadvantages and may generate negative pressure inside the face shield. Therefore, the homemade 3D baffle is used, which can reduce the distance between the baffle and the face, so that the exhaled airflow is not easily disturbed by outside airflow. The homemade 3D baffle is divided into three sizes according to the distance from the bottom edge of the lower lip to the tip of the nose, which can be worn by different users. It wouldn’t cause negative pressure inside the face shield, and can also achieve 99.5% capture efficiency at a lower suction airflow. The prototype of the PEBAR developed in this study can be worn indoors under normal breathing conditions, with high collection efficiency and wearing comfort. In the future, it can be applied to aerosol-transmitted patients, potential patients, and clean room workers in technology factories.