i went on this site to find out the answer not to answer it
Load bearing structures are structures where the loads are transferred to the foundation via load bearing walls(external and internal). These type of structures have a smaller window to walls ratio. Since the loads are borne by the walls the height of walls are limited. Framed structures are structures where the loads are transferred to the foundation via beams and columns. So beams and columns play a major role here. The loads in floor is transferred to the beams and then columns. These type structures can have large open areas in the walls. These type of structures can be adapted in high-rise buildings.
Shear strength measures the ability of a fastener to withstand a load at right angles to the axis of the fixing connection . Tensile strength measures the ability of a fastener to withstand a force along its axis
LOAD BEARING WALLS Walls that must support the dead load of their own weight and the weight of subsequent bearing structural members placed upon them. In addition, load bearing walls must be capable to carry the load of "live" loads that are anticpated to be placed upon the the system without deflection that can degrade or negatively impact structural intergrity. NON LOAD BEARING Walls that are only intended to support themselves and the weight of the cladding or sheathings attached. Non load bearing walls provide no structural support and may be interior or exterior walls. Non load bearing walls must be braced to resist minimum 5 psf lateral loads.
"Load bearing" is a term used to describe any structure or support system designed to bear a load of some sort. "High load bearing," by definition, implies that the item will hold heavier weights and higher levels of stress.
The average lifespan of a load-bearing structure typically ranges from 50 to 100 years, depending on various factors such as materials used, environmental conditions, maintenance practices, and design quality. Concrete structures often last longer, while wood and steel structures may have shorter lifespans due to susceptibility to rot, corrosion, or other damage. Regular inspections and maintenance can significantly extend the life of these structures.
to support its load
Load-bearing capacity describes a structure's ability to support a load. It is the maximum load or force that a structure can withstand without collapsing or failing.
The ability of a structure to support a load is determined by factors such as the materials used, the design of the structure, the shape and size of the components, the connection between components, and the distribution of the load. Factors like the type of loading (e.g. static or dynamic), environmental conditions, and maintenance also play a role in the structure's ability to support a load.
The formula used by the floor weight capacity calculator to determine the maximum load a floor can support is typically based on the material strength of the floor, its dimensions, and the type of load it will bear. This formula takes into account factors such as the floor's weight-bearing capacity, the distribution of the load, and any additional support structures in place.
Two characteristics of mass structures are that they are designed to support large amounts of weight or load, and they typically utilize materials like concrete, steel, or masonry for stability and durability. These structures are commonly used in buildings, bridges, and other infrastructure projects for their ability to withstand heavy forces and maintain their shape over time.
Stiffness of a structure refers to its ability to resist deformation when subjected to an external load. For example, a steel beam is known for its high stiffness due to its ability to deflect minimally when a load is applied. Stiffer structures typically experience less deformation and are considered more stable and reliable.
Static load refers to a stationary force acting on a structure or a component. It is a constant force that does not change over time. Static load is important to consider in engineering and construction to ensure that structures can safely support the weight placed on them without failure.
The denser the styrofoam, the greater it's load bearing ability.
Compression load refers to the force applied to an object that tends to make it shorter or more compact by pushing its particles closer together. This type of load is common in structures such as columns, beams, and supporting members where the weight or external force causes compression stress. It is important to consider compression loads when designing and analyzing structures to ensure they can support the expected weight or forces.
Structural loads or actions are forces, deformations, or accelerations applied to a structure components. Loads cause stresses, deformations, and displacements in structures. Assessment of their effects is carried out by the methods of structural analysis.
Elastic support refers to the ability of a system or structure to deform under load and then return to its original shape once the load is removed. This property is important for preventing damage from excessive stress or strain on flexible materials. Elastic support is commonly utilized in applications such as shock absorption, vibration damping, and structural reinforcement.
First, remove all encroaching vegetation. Then, replace rotted wood and broken support structures. Windows and entrances should also be replaced to guard from moisture and the inevitable mold that comes with it. You should check the wiring, load bearing structures, and Plumbing.