The installation of bus ducts demands precision and adherence to stringent standards, encompassing the quality of embedded building components, structural support robustness, and installation accuracy. To optimize installation quality, employing a theodolite to ascertain uniform heights across embedded parts at the construction site and creating clear markings can effectively minimize horizontal installation errors.

The bus duct connections feature high-insulation, arc-resistant, and flame-retardant high-strength insulation boards, secured using bolts with insulating sleeves. Compliant with specifications, the narrow gap between bolt holes and bolts accommodates the requisite overlap area for busbar connections. The inclusion of insulating sleeves on bus duct bolts reduces gaps, ensuring snug fits. During horizontal installation of modular aluminum alloy enclosed bus ducts, combining the plug-in box with the duct raises its installation height, potentially complicating future maintenance and operation. Notably, integrating a switch within the plug-in box proves challenging, necessitating the introduction of power supply through connecting conductors and cables to a nearby wall-mounted power box.

During bus duct installation, meticulous alignment of the main busbars of adjoining sections, maintaining a strict centerline axis alignment, and precise alignment with insulation plate bolt holes are imperative. Bolts should be uniformly tightened to prevent insulating sleeve damage from shear forces. Intensive bus ducts utilize copper with an optimal width-to-thickness ratio, minimizing inductive reactance and voltage losses, making them suitable for high current and long-distance applications, with the capacity to elevate voltage levels at line ends.

Effective construction management must address potential insulation reduction caused by stress-induced insulating sleeve damage on bolts. Grounding connections can utilize the busbar shell for grounding requirements, necessitating wire connections between all busbar shells post-spraying. While bus ducts are primarily designed for indoor use, water ingress within the ducts can compromise insulation over time, leading to short circuits and potential bus duct burnouts. Therefore, preemptive protective measures should be implemented to avert water ingress risks during installation.

Given the escalating demand for electricity in diverse structures like buildings and factories, transitioning from conventional circuit wiring methods to bus duct installations offers expediency and aesthetic enhancements, streamlining construction processes and enhancing architectural appeal.