In system design, it is crucial to ensure that the Fire-Resistant Bus Duct works in coordination with other equipment, and this needs to be considered from multiple aspects.
First, in terms of electrical parameters, ensure that the rated current, voltage and other parameters of the Fire-Resistant Bus Duct match those of other connected equipment. For example, it should be coordinated with the output capacity of the transformer and the rated current of the switchgear to avoid overload or underload. In the design stage, accurately calculate the load requirements of the entire system and select the appropriate specifications of the Fire-Resistant Bus Duct according to the load size to ensure stable power supply in both normal operation and fault conditions. At the same time, consider the short-circuit capacity of the system to ensure that the bus duct can withstand the instantaneous high current shock when a short-circuit fault occurs without affecting the normal operation of other equipment.
Secondly, in terms of installation layout, the positional relationship between the Fire-Resistant Bus Duct and other equipment should be reasonably planned. Ensure that the installation path of the bus duct will not interfere with other equipment to facilitate maintenance and repair. For example, maintain a certain safe distance from pipelines, bridges, etc. to avoid damage to equipment or heat dissipation due to physical contact. For complex systems such as high-rise buildings, the vertical installation and horizontal laying of the bus duct should be coordinated with equipment such as elevators and ventilation ducts to ensure that the installation is firm and does not affect the functions of other equipment.
Furthermore, in terms of control and protection systems, the Fire-Resistant Bus Duct should be controlled in conjunction with other equipment. Through intelligent control systems, such as programmable logic controllers (PLCs) or distributed control systems (DCSs), the operating status of the bus duct and other equipment can be monitored and controlled in real time. For example, when a bus duct fails, the power supply can be cut off in time and the backup equipment can be started to ensure the continuous operation of the system. At the same time, protection devices such as overcurrent protection and grounding protection should be reasonably set to ensure that the fault point can be quickly isolated when a fault occurs and protect other equipment from being affected.
In addition, in terms of heat dissipation, the heat dissipation requirements of the Fire-Resistant Bus Duct and other equipment should be considered. The bus duct generates heat during operation. If the heat dissipation is poor, it may affect its performance and life, and even cause a fire. Therefore, it is necessary to ensure that there is enough ventilation space around the bus duct, or adopt heat dissipation measures such as forced ventilation. At the same time, it is necessary to consider the heat dissipation coordination with other heat-generating equipment to avoid local overheating.
Finally, during the system debugging and maintenance phase, comprehensive testing and verification should be carried out to ensure that the Fire-Resistant Bus Duct can work with other equipment. This includes electrical performance testing, voltage resistance testing, ground resistance testing, etc., as well as linkage debugging of the control system to ensure stable operation under various working conditions. At the same time, a comprehensive maintenance plan should be formulated to regularly inspect and maintain the bus duct and other equipment to promptly discover and solve potential problems.
