This equipment represents a floor saw model designed and manufactured by Husqvarna. It is engineered for concrete and asphalt cutting applications, typically employed in construction and road maintenance projects. Its designation indicates a specific set of features and performance characteristics tailored for demanding professional use.
Its significance lies in its ability to provide precise and efficient cutting, crucial for tasks such as expansion joint creation, demolition work, and utility installation. Historically, this type of machinery has evolved to offer improved power, durability, and operator comfort, contributing to increased productivity and reduced labor costs on job sites.
The following sections will delve into the technical specifications, operational considerations, and maintenance requirements associated with this type of floor saw, providing a detailed understanding of its capabilities and optimal usage.
1. Engine Power
Engine power is a critical determinant of the operational effectiveness. Within this specific Husqvarna floor saw model, engine power directly influences its cutting capability and the types of materials it can efficiently process. Insufficient power restricts the saw’s ability to handle dense concrete or asphalt, resulting in slower cutting speeds and increased blade wear. Conversely, adequate power ensures smooth and consistent cutting, minimizing strain on the engine and maximizing productivity. For instance, cutting through heavily reinforced concrete requires a robust engine capable of delivering high torque to maintain blade speed and prevent stalling.
The engine’s specifications, typically measured in horsepower (HP) or kilowatts (kW), correlate directly with the diameter of the blade the saw can accommodate and the maximum cutting depth achievable. A higher-powered engine enables the use of larger diameter blades, thus increasing the maximum cutting depth. Furthermore, the engine’s efficiency impacts fuel consumption and overall operating costs. Regularly maintaining the engine, including air filter replacement, spark plug inspection, and oil changes, is paramount to preserving its power output and preventing performance degradation over time. Choosing the right engine that balances power with fuel efficiency is crucial for optimizing project economics.
In summary, engine power represents a fundamental performance parameter. Understanding its impact on cutting performance, blade compatibility, and operational costs is essential for effectively utilizing the saw in diverse construction and maintenance applications. Properly maintaining the engine and selecting an appropriate engine size relative to the anticipated workload are key to maximizing the return on investment and ensuring reliable operation over the equipment’s lifespan.
2. Cutting Depth
Cutting depth represents a primary performance characteristic, directly influencing its applicability across various concrete and asphalt cutting tasks. This parameter dictates the maximum thickness of material that can be processed in a single pass, defining the scope of projects for which the equipment is suitable.
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Blade Diameter and Maximum Cutting Depth
The maximum achievable cutting depth is inherently linked to the diameter of the blade that can be mounted on the equipment. Larger diameter blades allow for deeper cuts, enabling the processing of thicker concrete slabs or asphalt layers. The machine’s design incorporates specific blade guard dimensions and spindle configurations to accommodate a defined range of blade sizes, ultimately determining the maximum cutting depth specification. Exceeding the recommended blade size can compromise safety and damage the equipment.
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Adjustability Mechanisms
The equipment features a depth adjustment mechanism that allows the operator to precisely control the cutting depth based on project requirements. This mechanism typically involves a handwheel or lever system that raises or lowers the blade housing relative to the cutting surface. Accurate depth adjustment is crucial for achieving clean, consistent cuts and preventing overcutting or undercutting, which can compromise structural integrity or aesthetics. Regular inspection and maintenance of the adjustment mechanism are essential to ensure accurate and reliable operation.
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Material Properties and Cutting Efficiency
The achievable cutting depth is also influenced by the properties of the material being processed. Harder, more abrasive materials, such as heavily reinforced concrete, may require multiple passes to achieve the desired depth, effectively reducing the rate of material removal. In such cases, selecting the appropriate blade type and adjusting cutting parameters, such as blade speed and coolant flow, can optimize cutting efficiency and minimize blade wear. Understanding the material properties and adjusting operational techniques accordingly is vital for maximizing productivity.
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Impact on Project Applications
Cutting depth significantly impacts the range of applications for which the equipment is suitable. Shallower cutting depths are appropriate for tasks such as expansion joint creation or shallow trenching, while deeper cutting depths are necessary for demolition work, utility installation, and full-depth pavement repairs. Selecting the appropriate cutting depth for a given application ensures efficient material removal, minimizes unnecessary damage to surrounding structures, and contributes to overall project success.
In summary, cutting depth, determined by blade diameter, adjustability, material properties, and application requirements, is a key factor. Proper understanding and management of cutting depth are crucial for maximizing efficiency, ensuring accuracy, and expanding the range of applications the equipment can effectively address.
fs400lv Husqvarna
This exploration has detailed key facets of the equipment, encompassing engine power and cutting depth capabilities. Understanding these parameters is vital for informed operation and maintenance, directly influencing performance and longevity. Emphasis on matching specifications to application requirements enables optimal productivity and minimizes operational risks.
Continued adherence to manufacturer guidelines and proactive maintenance practices remain paramount. Consistent monitoring of performance indicators and timely intervention will safeguard the operational integrity and maximize return on investment. Such diligence is essential for sustained, reliable functionality within demanding work environments.
