Heavy equipment, heavy machinery, earthmovers, construction vehicles, or construction equipment, refers to heavy-duty vehicles specially designed to execute construction tasks, most frequently involving earthwork operations or other large construction tasks. Heavy equipment usually comprises five equipment systems: the implement, traction, structure, power train, and control/information.

Heavy equipment has been used since at least the 1st century BC, when the ancient Roman engineer Vitruvius described a crane powered by human or animal labor in De architectura.

Heavy equipment functions through the mechanical advantage of a simple machine that multiplies the ratio between input force applied and force exerted, easing and speeding tasks which often could otherwise take hundreds of people and many weeks' labor. Some such equipment uses hydraulic drives as a primary source of motion.

The word plant, in this context, has come to mean any type of industrial equipment, including mobile equipment (e.g. in the same sense as powerplant). However, plant originally meant "structure" or "establishment" – usually in the sense of factory or warehouse premises; as such, it was used in contradistinction to movable machinery, often in the phrase "plant and equipment".

The design of heavy equipment has increasingly incorporated modern electronics and software, a process known as Fleet digitalization. This integration of technology facilitates greater automation, safety monitoring, and operational efficiency on construction and mining sites, creating what is often referred to as an intelligent job site.

Fleet telematics systems are utilized for the Fleet management of heavy equipment. A ruggedized Telematic control unit, installed on each asset, uses a GPS tracking unit to provide real-time Vehicle location data. In addition to location, the system transmits a wide range of telemetry data, including engine hours, fuel consumption, idle time, and diagnostic fault codes. This data is used for operational oversight, such as to track asset utilization, schedule predictive maintenance, and manage fuel with Fuel-management systems. Studies in the construction industry have correlated the use of such systems with improvements in overall project efficiency. A primary function of these platforms is to address the challenge of aggregating data from a mixed fleet of equipment from various manufacturers into a single, unified interface.

Research and development in heavy equipment has increasingly focused on robotics and autonomous operation. Several manufacturers have commercialized autonomous systems that allow machines like haul trucks and dozers to operate without a human driver by following pre-programmed routes from a digital site plan. Such applications are most prevalent in mining and large-scale earthwork operations where tasks are repetitive and occur in controlled environments. Semi-autonomous features, such as grade control and automated digging cycles on excavators, are also becoming common, assisting operators in performing tasks with greater speed and precision.

Technology is applied to improve operator safety and situational awareness. Video telematics systems, which utilize multiple ruggedized cameras, offer operators a comprehensive view of their surroundings to mitigate blind spots. These systems also record operational data for incident analysis. Operator scoring applications analyze telemetry data to identify potentially hazardous operating practices, such as excessive speed or abrupt movements, providing a basis for targeted safety training. Advanced driver-assistance systems (ADAS) are also being adapted for heavy equipment, with features like object detection and collision avoidance alerts to protect both the operator and ground personnel.